Examples of biotechnological achievements in Gentiana, Rhodiola and Leucojum species.
\\n\\n
Released this past November, the list is based on data collected from the Web of Science and highlights some of the world’s most influential scientific minds by naming the researchers whose publications over the previous decade have included a high number of Highly Cited Papers placing them among the top 1% most-cited.
\\n\\nWe wish to congratulate all of the researchers named and especially our authors on this amazing accomplishment! We are happy and proud to share in their success!
\\n"}]',published:!0,mainMedia:null},components:[{type:"htmlEditorComponent",content:'IntechOpen is proud to announce that 179 of our authors have made the Clarivate™ Highly Cited Researchers List for 2020, ranking them among the top 1% most-cited.
\n\nThroughout the years, the list has named a total of 252 IntechOpen authors as Highly Cited. Of those researchers, 69 have been featured on the list multiple times.
\n\n\n\nReleased this past November, the list is based on data collected from the Web of Science and highlights some of the world’s most influential scientific minds by naming the researchers whose publications over the previous decade have included a high number of Highly Cited Papers placing them among the top 1% most-cited.
\n\nWe wish to congratulate all of the researchers named and especially our authors on this amazing accomplishment! We are happy and proud to share in their success!
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\r\n\r\n\tThe areas that this book will integrate are: pollution by metals in water, pollution by hydrocarbons in water, pollution by pesticides in water, pollution by emerging micro-pollutants in water, pollution by microorganisms in water, advances in analytical chemistry in assessing water quality, advances in microbiology in water quality, sediment-water interaction, particulate material and water interaction, effluent water, water biomonitoring, statistical treatment of water quality data, human water supply, wastewater treatment plants, bioremediation, physical-chemical treatments, groundwater pollution, urban river pollution, water and circular economy.
\r\n\r\n\tWith the themes presented, this book aims to provide the reader with a comprehensive overview of the current state of the art in water quality, presenting an adequate and viable path to follow.
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Kevin Summers",publishedDate:null,coverURL:"https://cdn.intechopen.com/books/images_new/10446.jpg",keywords:"Metals, Hydrocarbons, Microorganisms, Aquatic Flora and Fauna, Analytical Chemistry, Innovative Methods, Wastewater Treatment Plants, Bioremediation, Mangrove, Saline Water, Groundwater Pollution, Urban River Pollution",numberOfDownloads:null,numberOfWosCitations:0,numberOfCrossrefCitations:null,numberOfDimensionsCitations:null,numberOfTotalCitations:null,isAvailableForWebshopOrdering:!0,dateEndFirstStepPublish:"October 12th 2020",dateEndSecondStepPublish:"November 9th 2020",dateEndThirdStepPublish:"January 8th 2021",dateEndFourthStepPublish:"March 29th 2021",dateEndFifthStepPublish:"May 28th 2021",remainingDaysToSecondStep:"4 months",secondStepPassed:!0,currentStepOfPublishingProcess:4,editedByType:null,kuFlag:!1,biosketch:"Dr. Kevin Summers is a Senior Research Ecologist at the Environmental Protection Agency’s (EPA) Gulf Ecosystem Measurement and Modeling Division. He has authored approximately 150 peer-reviewed journal articles, book chapters, and reports and has received many awards for technical accomplishments from the EPA and outside the agency.",coeditorOneBiosketch:"Doctor in analytical chemistry with practical experience in laboratory work, currently on a position of a coordinator.",coeditorTwoBiosketch:null,coeditorThreeBiosketch:null,coeditorFourBiosketch:null,coeditorFiveBiosketch:null,editors:[{id:"197485",title:"Dr.",name:"J. Kevin",middleName:null,surname:"Summers",slug:"j.-kevin-summers",fullName:"J. Kevin Summers",profilePictureURL:"https://mts.intechopen.com/storage/users/197485/images/system/197485.jpg",biography:"Dr. Kevin Summers is a Senior Research Ecologist at the Environmental Protection Agency’s (EPA) Gulf Ecosystem Measurement and Modeling Division. At present, he is working with colleagues in the Sustainable and Healthy Communities Program to develop an index of community resilience to natural hazards, an index of human well-being that can be related to changes in ecosystem, social and economic services, and a community sustainability tool for communities with populations less than 40,000. He leads research efforts for indicator and indices development. Dr. Summers is a systems ecologist and began his career at the EPA in 1989 and has worked in various programs and capacities. This includes leading the National Coastal Assessment in collaboration with the Office of Water culminating in the award-winning National Coastal Condition Report series (four volumes between 2001 and 2012), which integrates water quality, sediment quality, habitat and biological data to assess the ecosystem condition of the estuaries of the United States. He was the acting National Program Director for Ecology for the EPA between 2004 and 2006. 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Venkateswarlu",coverURL:"https://cdn.intechopen.com/books/images_new/371.jpg",editedByType:"Edited by",editors:[{id:"58592",title:"Dr.",name:"Arun",surname:"Shanker",slug:"arun-shanker",fullName:"Arun Shanker"}],productType:{id:"1",chapterContentType:"chapter",authoredCaption:"Edited by"}},{type:"book",id:"878",title:"Phytochemicals",subtitle:"A Global Perspective of Their Role in Nutrition and Health",isOpenForSubmission:!1,hash:"ec77671f63975ef2d16192897deb6835",slug:"phytochemicals-a-global-perspective-of-their-role-in-nutrition-and-health",bookSignature:"Venketeshwer Rao",coverURL:"https://cdn.intechopen.com/books/images_new/878.jpg",editedByType:"Edited by",editors:[{id:"82663",title:"Dr.",name:"Venketeshwer",surname:"Rao",slug:"venketeshwer-rao",fullName:"Venketeshwer Rao"}],productType:{id:"1",chapterContentType:"chapter",authoredCaption:"Edited by"}},{type:"book",id:"4816",title:"Face Recognition",subtitle:null,isOpenForSubmission:!1,hash:"146063b5359146b7718ea86bad47c8eb",slug:"face_recognition",bookSignature:"Kresimir Delac and Mislav Grgic",coverURL:"https://cdn.intechopen.com/books/images_new/4816.jpg",editedByType:"Edited by",editors:[{id:"528",title:"Dr.",name:"Kresimir",surname:"Delac",slug:"kresimir-delac",fullName:"Kresimir Delac"}],productType:{id:"1",chapterContentType:"chapter",authoredCaption:"Edited by"}}]},chapter:{item:{type:"chapter",id:"42585",title:"Role of Biotechnology for Protection of Endangered Medicinal Plants",doi:"10.5772/55024",slug:"role-of-biotechnology-for-protection-of-endangered-medicinal-plants",body:'The last two centuries of industrialization, urbanization and changes in land use converting agricultural and natural areas to artificial surface have led to European plants being considered amongst the most threatened in the world. In some countries, more than two-thirds of the existing habitat types are considered endangered. Human activity is the primary cause of risk for 83% of endangered plant species. Habitat destruction and loss are also a problem because they lead to the fragmentation of the remaining habitat resulting in futher isolation of plant population [1]. From another side during the last 10 years an intense interest has emerged in "nutraceuticals" (or "functional foods") in which phytochemical constituents can have long-term health promoting or medicinal qualities. Although the distinction between medicinal plants and nutraceuticals can sometimes be vague, a primary characteristic of the latter is that nutraceuticals have a nutritional role in the diet and the benefits to health may arise from long-term use as foods (i.e. chemoprevention) [2]. In contrast, many medicinal plants possess specific medicinal benefits without serving a nutritional role in the human diet and may be used in response to specific health problems over short- or long-term intervals [3].
There is indisputable interest towards traditional and alternative medicine world-wide [4] and at the same time an increasing application of herbs in medical practices, reported by World Health Organization (WHO) [5]. Nowadays the centuries-old tradition of medicinal plants application has turned into a highly profitable business on the world market. Numerous herbal products have been released like patented medical goods, food additives, herbal teas, extracts, essential oils, etc [6 - 9].
There is an expansion of the market of herbs and herbs based medical preparations all over the world. The income a decade ago in the North American market for sales of medicinal plants has climbed to about $3 billion/year [10]. In South America, Brazil is outstanding with 160 millions USD for 2007 while in Asia, China is at the leading trade position with 14 billions USD for 2005, etc. [11]. Similar increase was observed in Western Europe with 6 billion USD income for a period of two years from 2003 to 2004. The sales increased in Czech Republic by 22 % from 1999 to 2001 and jumped twice in Bulgaria [12].
Medicinal plants are precious part of the world flora. More than 80 000 species out of the 2 500 000 higher plants on Earth are reported to have at least some medicinal value and around 5 000 species have specific therapeutic value. The contemporary phytotherapy and the modern allopathic medicine use raw materials from more than 50 000 plant species [13]. About two thirds of these fifty thousand plants utilized in the pharmacological industry are harvested from nature [14]. Small portions like 10%-20% of the plants used for remedies preparations are cultivated in fields or under controlled conditions [15]. Ages-old exploitation of the natural resources and the dramatically increased interest are a real thread for the biological diversity. Bad harvesting management and insufficient cultivation practices may lead to extinction of endangered species or to destruction of natural resources. Science has already recorded diminishing natural populations, lost in the genetic diversity, local extinction of many species and/or degeneration of their natural habitats [16]. This alarming situation is raising the questions about special efforts which should be paid both to protection of the plant populations and to up-to-date knowledge concerning more reasonable and effective utilization of these plants [12].
Bulgaria as a country with a rich and diverse flora (comprising of 7 835 species) and with old traditions in herbs’ use faces the same global problems. One of the most serious challenges is the control and the limitation of the expanding gathering of endangered medicinal plants [17]. The Biodiversitry Act covers Sideritis scardica (mursala tea), Alchemilla vulgaris, Acorus calamus, Rhodiola rosea, Leucojum aestivum, Gentiana sp., Glycyrrhiza glabra, Ruta graveolens, and some medicinal plants under special rules of protection and use e.g. Inula helenium, Carlina acanthifolia, Berberis vulgaris, Rhammus frangula, Rubia tinctorum, Atropa belladona, Origanum heracleoticum etc. More than 750 herbs are used in the folk medicine while 150 - 250 are used in the official medicine and can be found at the market [18 - 20]. A considerable number of the wild species are rare, endangered or under protection [21, 22], and 12.8% are endemics [23]. Recently 120 herbs have been traditionally collected from their natural populations, 47 are under protection, 38 are included in the Red Data Book of Bulgaria, 60 have been cultivated, 35 are main industrial crops [24]. Bulgarian medicinal plants are famous for their high content of biologically active substances. Their high value qualities are due to the unique combinations of specific soil and climatic conditions in the different sites of the country [25]. Bulgaria is the European leader in herbs export and occupies the 8th world position with trade in 40 countries all over the world. The greatest export of 50% is to Germany being 3 600 tones in 1991 and doubling to 6 000 tones in 2 000 [8]. Spain, Italy, France, Austria and USA are also major trade partners. The export is increasing steadily from 6 - 7 t in 1992 to 12 tones in 2000 – 2003, to 15 - 17 000 tones in 2007 [22, 26 - 28,]. These amounts represented about 70% - 80% out of all harvested and processed medicinal plants in Bulgaria [27]. The bigger number of these species is wild growing [29] but recently cultivation in fields has been applied as a measure to protect medicinal plants included in the list of protected species. At present about 20% of the medicinal plants are cultivated, but this share comprises about 40% of the export [24].
Worldwide the constant expansion of herbs’ trade, the insufficient cultivation fields, and the bad management of harvesting and overharvesting have led to exhaustion of the natural resources and reduction of the biodiversity. According to the data of the Food and Agricultural Organization (FAO) at the United Nations annually the flora bares irretrievable losses which destroy the natural resources and the ecological equilibrium [30]. Four thousand to 10 000 medicinal species were endangered of disappearing at the beginning of this century [14]. To stop the violence against nature, efforts should be directed both to preservation of the plant populations and to elevating the level of knowledge for sustainable utilization of these plants in traditional, alternative, and allopathic medicine [12].
This great issue is in the focus of science which offers different decisions to solve the global problem. Cultivation of the valuable species in experimental conditions is one of the approaches. The latter refers to application of classical methods for multiplication by cuttings, bulbs, and so forth, as well as by biotechnological methods of in vitro cultures and clonal propagation for production of enormous number of identical plants. The micropropagation is considered to have the greatest commercial and iconomical importance for the rapid propagation and ex situ conservation of rare, endemic, and endangered medicinal plants [31 - 34]. Except for clonal multiplication and maintaining the genetic structure biotechnology is powerful for modifying genetic information and gene expression to obtain new valuable compounds with new properties or with increased amounts [35 - 37]. Micropropagation, cell and callus cultures, metabolic engineering and genetic manipulations are especially appropriate for species which are difficult to propagate in vivo [36].
In Bulgaria quite successful investigations have been performed for in vitro clonal multiplication of valuable, endemic, rare and endangered medicinal species: Rhodiola rosea, Gentiana lutea, Sideritis scardica, Pancratium maritimum, Scabiosa argentea, Cionura erecta, Jurinea albicaulis subsp. kilaea, Peucedanum arenarium, Linum tauricum subsp. bulgaricum, Aurinia uechtritziana, Silene thymifolia, Glaucium flavum, Stachys maritima, Astrodaucus littoralis, Otanthus maritimus, Plantago arenaria, Verbascum purpureum,\n\t\t\t\tAlchemilla sps, etc. [38 - 44]
More than 2 000 different species are used in Europe for production of medicinal and other herbal preparations. Seventy percents of these species are growing in wild nature [17, 29] with already limiting resources which demands search for alternative methods friendly to nature. Biotechnological methods seem appropriate ones with their potential for multiplication, selection and protection of medicinal plants. In this respect biotechnological approaches are convenient for use of cells, tissue, organs or entire organism which grow and develop in in vitro controlled conditions, and can be subjected to in vitro and genetic manipulations [33] to obtain desired substances [45]. These methods are especially appropriate and reasonable to apply when the targeted species have high economical or trade value, or plant resources are limited concerning the availability of wild area or good healthy plants, or when the plants are difficult to grow [46, 47].
In vitro cultivation may be directed to development of different systems depending on the practical needs. At present production of a large number of identical plants by clonal micropropagation is the most prominent one. Complex and integrated approaches for cultivation of plant systems may be the basis for future development of new, effective, safe and high quality products. These scientific achievements might be used for the establishment of ex situ and in vitro collections, multiplication of desired species and to obtain raw material for the pharmaceutical and cosmetic industries [48]. In vitro technologies offer some or most of the following advantages: easier extractions and purification of valuable substances from temporary sources; new products which may not be found in nature; absence of various environmental and seasonal effects, automation, better control of the biosynthetic pathways and flexibility in obtaining desired product; shorter production cycles and cheaper less costly products. Here should also be mentioned the potential of the sophisticated techniques of genetic engineering, which might be applied respecting the rules of contained use [33; 47]. At present the methods of plant cell and tissue cultures have found many proper sites for application in the medicinal plants utilization. The achieved results and the confidence for further success drive the efforts for wider application of plant biotechnologies in more spheres concerning medicinal plants [37].
Plant cell methods and techniques were initially used in fundamental scientific investigations at the beginning of their development in the early 60-ties of the last century. Plant biotechnology is based on the totypotence of the plant cell [35; 49]. This process of de novo reconstruction of an organism from a cell in differentiated stage is highly linked to the process of dedifferentiation when the cell is returning back to its early embryogenic/meristematic stage. In this stage cells undergo division and may form nondifferentiated callus tissue or may redifferentiate to form new tissue, organs and an entire organism. Morphogenesis in vitro is realized via two major pathways: (i) organogenesis when a group of cells is involved for de novo formation of organs and (ii) somatic embryogenesis when the new organism is initiated from a single cell.
Micropropagation is a vegetative propagation of the plants in vitro conditions (in glass vessels under controlled conditions) leading to development of numerous plants from the excised tissue and reproducing the genetic potential of the initial donor plant.
Usually tissues containing meristematic cells are used for induction of axilary or adventitious shoots but induction of somatic embryos can be achieved from differentiated cells as well.
Micropropagation is used routinely for many species to obtain a large number of plants with high quality. It is widely applied to agricultural plants, vegetable and ornamental species, and in some less extent to plantation crops. One of the substantial advantages of micropropagation over traditional clonal propagation is the potential of combining rapid large-scale propagation of new genotypes, the use of small amounts of original germplasm (particularly at the early breeding and/or transformation stage, when only a few plants are available), and the generation of pathogen-free propagules. [50]. Compared to the other spheres of in vitro technologies clonal propagation has proved the greatest economical and market importance in industry including pharmaceutical industry which needs for raw material from the medicinal plants is increasing constantly. It offers faster and alternative way for production of raw material and from another side overcoming the problems arising from the limited natural resources.
At present, there is a long list of research groups worldwide investigating hundreds of medicinal species. Various success procedures and recipes for many of these species have been developed. However, there is not a universal protocol applicable to each species, ecotype, and explant tissue. From another side all these continuous tedious studies on the standardization of explant sources, media composition and physical state, environmental conditions and acclimatization of in vitro plants have accumulated information, continuously enriched, which is a good basis for elaboration of successful protocols for more species. Wider practical application of micropropagation depends on reduction of costs so that it can become compatative with seed production or traditional vegetative propagation methods (e.g., cuttings, tubers and bulbs, grafting) [50].
The plant cell culture systems have potential for commercial exploitation of secondary metabolites. Similar to the fermentation industry using microorganisms and their enzymes [35, 51, 52] to obtain a desired product plant cells are able to biotransform a suitable substrate compound to the desired product. The latter can be obtained as well by addition of a precursor (a particular compound) into the culture medium of plant cells. In the process of biotransformation, the physicochemical and biological properties of some natural products can be modified [53]. Thus, biotransformation and its ability to release products into the cells or out of them provide an alternative method of supplying valuable natural products that occur in nature at low levels. Generally, the plant products of commercial interest are secondary metabolites, which in turn belong to three main categories: essential oils, glycosides and alkaloids [51]. Plant cell cultures as biotransformation systems have been highlighted for production of pharmaceuticals but other uses have also been suggested as new route for synthesis, for products from plants difficult to grow, or in short supply, as a source of novel chemicals. It is expected that the use, production of market price and structure would bring some of the other compounds to a commercial scale more rapidly and in vitro culture products may see further commercialization [54]. The application of molecular biology techniques to produce transgenic cells and to effect the expression and regulation of biosynthetic pathways is also a significant step towards making in vitro cultures more generally applicable to the commercial production of secondary metabolites [54]. However, because of the complex and incompletely understood nature of plant cells growing in in vitro cultures, case-by-case studies have been used to explain the problems occurring in the production of secondary metabolites from cultured plant cells.
Genetic manipulations (direct and indirect genetic transformation) are other different approaches to increase the content biological active substances in plants. Genetic engineering covers a complex of methods and techniques applied to the genome in order to modify it to obtain cells and organisms with improved qualities or possessing desired traits. These might refer to better yield or resistance, as well as, to higher metabolite production or synthesis of valuable biologically active substances [55]. Gene transfer may be direct when isolated desired DNA fragments are inserted into the cell most often by electrical field or adhesion. This method is less used in medicinal plants. Indirect genetic transformation of plants uses DNA vectors naturally presenting in plant pathogens to transfer the isolated genes of interest and to trigger special metabolic pathways [56]. Agrobacterium rhizogenes induces formation of "hairs" at the roots of dicotyledonous plants. Genetically modified "hairy" roots produce new substances, which very often are in low content. Hairy roots are characterized with genetic stability and are potential highly productive source for valuable secondary metabolites necessary for the pharmaceutical industry [57, 58]. Manipulations and optimization of the productivity of the transformed hairy roots are usually the same as for the other systems for in vitro cultivation [59]. They also depend on the species, the ecotype, the explant, the nutrient media, cultivation conditions, etc [60].
All these application of the principles of plant cell division and regeneration to practical plant propagation and further manipulations could be possible if there are reliable in vitro cultures, which efficiency depends on many various factors.
The ability of the plant cell to realize its totypotence is influenced in greatest extend by the genotype, mother/donor plant, explant, and growth regulators what was confirmed by the tedious empirical work of in vitro investigations [61, 62]. Here, some of the specific and most important requirements will be mentioned in order of understanding the efforts and originality of some ideas when establishing in vitro cultures of medicinal plants.
Genotypes. Morphogenetic potential of excised tissue subjected to cultivation in vitro is in strong dependence of the genotype [63]. Genetically plants demonstrate different organogenic abilities, which were observed for all plants groups including medicinal plants [64 - 72]. Some of the species (like tobacco and carrot) are easy to initiate in in vitro cultures while others are more difficult - reculcitrant (cereals, grain legumes, bulbous plants). Many of the wild species like most of the medicinal plants and especially those producing phenols are more difficult or extremely difficult to handle.
Donor plant. The donor plant should be healthy, in the first stages of its intensive growth, not in dormancy. Rhyzomes and bulbs usually need pretreatment with low or high temperatures for different periods of time [35, 73].
Explant. The explant type might determine the organogenesis potential and the genetical stability of the clonal material. Physiological age of the explant is also crucial. Immature organs and differentiated cells excised from stem tips, axilary buds, embryos and other meristematic tissues are the most appropriate [35, 62, 73]. However, despite the development of cell and molecular biology the limits still exist in receiving easy information about the genetic, epigenetic and physiological status of the explant. Empirical approach is the most common to specify the chemical and physical stimuli triggering cell totypotence.
Nutrient media. Although more than 50 different media formulations have been used for the in vitro culture of tissues of various plant species the formulation described by Murashige and Skoog (MS medium) [74] is the most commonly used, often with relatively minor changes. Other famous media are those of Gamborg [75; 76], Huang and Murashige [77] Nischt and Nischt etc. The nutrient medium usually consists of all the essential macro- and micro salts, vitamins, plant growth regulators, a carbohydrate, and some other organic substances if necessary [62].
Plant growth regulators. Plant growth regulators, including the phytochormones, are essential for cell dedifferentiation, division and redifferention leading to callus tissue and organ formation. The auxins and cytokinins are the most important for in vitro development and morphogenesis. However, the most appropriate plant regulators and their concentrations in the nutrient media depend on the genotype, explants type and the donor plant physiological status. Hence, numerous combinations could be designed and the optimal ones are validated empirically. All that creates the difficulties of the experimental work, which is dedicated to find the balance between the factors determining reliable in vitro development.
Cytokinins. Different groups of cytokinins might be used but the most efficient ones for induction of organogenesis and a large number of buds are the natural cytokinins (zeatin and kinetin) or the synthetic ones - 6-benzylaminopurine (benzyl adenine (BA, BAP), 6-γ(-dimethylallyl-amino)-purine (2iP) and thidiazuron (TDZ).
Auxins. The auxins also are obtained from natural plant materials like indolyl-3-acetic acid (IAA), indole 3-butyric acid (IBA), α- naphthyl acetic acid (NAA) or are chemically produced like 2,4-dichlorophenoxyacetic acid (2,4-D), 2,4,5-trichlorophenoxyacetic acid (2,4,5-T), picloram, etc. The auxins have a wide spectrum of effects on different processes of plant development and morphogenesis. Depending on their chemical structure and concentration, they induce or inhibit cell division, stimulate callus or root formation.
Gibberellins. The group of gibberellins includes more than 80 compounds, which stimulate cell division and elongation. The most commonly used one is gibberellic acid (GA3).
Vitamins and supplements. Growth regulatory functions are attributed to some of the vitamins B group – thiamine (B1), niacin (vit B3, nicotinic acid, vitamin PP), piridoxin (vit B6), which in fact are the most popular for in vitro recipes. Supplements like yeast extract, coconut milk, maize extract and some other might effect tissue growth and bud development.
The best morphogenesis could be achieved when the optimal balance between the effect of genotype, explant and growth regulators is identified.
The processes of root formation and adaptation have their specific requirements and not all of the quoted cases of organogenesis, embryogenesis, regeneration are followed by rhizogenesis and adaptation. These processes depend on the genotype and in most of the cases on the ecotype of the species [62], whereas the necessary culture conditions are chosen in an empirical way. The reduction of the sucrose from 2 % - 3% to 1% - 0.5% stimulates root induction and formation. Aclimatization of the obtained in vitro plants is a critical moment for establishment of good protocol for micropropagtion. Adaptation of plants in greenhouse, field or in the nature is another delicate and difficult stage. Usually in in vitro conditions, regenerants formed well-developed root system. However, they quickly loose their turgor after transfer to soil. Their leaves withered and dried. These plants underwent stress due to the changes in humidity and culture medium.
The light, temperature and air humidity are important parameters for in vitro cultivation of the plant cells and tissues. The light is one of the important factors for morphogenetic process like bud and shoots formation, root induction and somatic embryogenesis. Light spectrum and intensity as well as the photoperiod are very important for successful cultivation [78]. The recommended temperature in the cultivation rooms or phytothrone chamber is about 23-25 °C but the cultures of tropical species require higher temperature (27-30°C), while arctic plants cultures – lower (18-21° C).
Efficient protocolos for in vitro propagation (plant cloning) were established for a long list of medicinal plants like Panax ginseng [79, 80], Aloe vera [81], Angelica sinensis, Gentiana davidii [82], Chlorophytum borivilianum [83, - 86), Tylophora indica [87, 88], Catharanthus roseus [89], Holostemma ada-kodien and\n\t\t\t\tIpomoea mauritiana [90], Saussurea involucrata [91], Kniphofia leucocephala [92], Podophyllum hexandrum [93], Saussurea obvallata [94], Ceropegia candelabrum [95], Syzygium alternifolium [96], Chlorophytum arundinaceum [97], Rotula aquatica [98, 99], etc.
Establishment of micropropagation system is a base for conservation of the species and for protection of the genefund, as well as for studies of valuable substances in important medicinal plants. Different strategies are developed as well for establishment of cell cultures aiming at production of biologically active compounds. These systems could be used for large scale cultivation of plant cells for obtaining of secondary metabolites. These methods are reliable and give possibility for continuous supply of raw materials for production of natural products [45, 82].
In this chapter a small part of the successful in vitro research in medicinal plants and the application of “green biotechnology” methods for protection of endangered species will be illustrated by examples from the investigations in the genera of Gentiana, Leucojum and Rhodiola. These groups of medicinal plants were chosen because the three of them are with outstanding importance for the pharmaceutical and nutraceutical industries. The species belonging to them are worshiped for their multiple beneficial health effects and have been used for thousands of years in folk medicine all over the world. However, their distribution is at different parts of the Earth – Gentians are the most widely spread in various climatic zones, Rhodiola covers less territory, predominantly in the cold regions in north and high mountains, while Leucojum can be found in limited warm and south regions in Europe. Many species from Gentiana, Rhodiola and Leucojum genera can be found in Bulgaria but most of them are endangered and included in the Red Book like Gentiana lutea, Rhodiola rosea and Leucojum aestivum. In world scale level of protection – Leucojum spp are in the list of the most threatend with heavy measures of restriction. Nearly all Gentiana species are endangered while many Rhodiola species are under special regime of use. However, one and the same Rhodiola species may be close to extinction in one country but widely spread (even as a weed) in another country. Another consideration of ours is the ability of the plants from these genera to be cultivated in field what was possible for Gentiana, partially for Rhodiola and not possible for Leucojum. Described here examples illustrate different levels of development of in vitro cultures and application of biotechnology to the three chosen groups of herbs. Development of in vitro cultures started about 40 years ago in Gentiana, 25 years ago in Rhodiola and 20 years ago in Leucojum.
The most intensive in vitro research was carried in Gentiana obtaining all kinds of in vitro cultures, including somatic embryo cultures, with success in cryopreservation, in biotransformation and genetic metabolic engineering. Rhodiola occupies a middle position with considerable success in callus, suspension and micropropagation systems. Cultivation in bioreactors, biotransformation and genetic transformation were successful.
Leucojum seems to be the most difficult, though protocols for clonal propagation have been established and gene bank in vitro has been reported (in Bulgaria). Callus, suspension and organogenic cultures could be obtained and growth in bioreactors with possibilities for biotransformation and even genetic transformation (though at this stage without synthesis of galanthamine).
Bulgaria is a pioneer in Leucojum aestivum biotechnology. It is in the frontiers of micropropagation of Rhodiola rosea and has less investigation in Gentiana in vitro cultures.
Genus Gentiana belongs to family Gentianaceae and is a group of medicinal plants of special interest. It is a large genus comprising of about 400 species widely distributed in the mountain areas of temperate zones [100], including Central and South Europe. Most of the species are interesting to horticulture for their beautiful and attractive flowers but they have more important medicinal value, which is due to the production of secondary metabolites in their roots (Radix Gentianae). The most efficient ones are the bitter secoiridoid glucosides (gentiopicroside, amarogentin), xanthones, di- and trisacharides, pyridine alkaloids [66, 101]. Traditionally, the pharmaceutical industry largely depends on wild sources exploiting intensively the natural areals. The annual drug demands have been much higher than the production from wild sources [66]. At the same time many gentians are either difficult to grow outside their wild habitat or their cultivation (if possible) proved to be not economic. Continuous collection of plant material from natural habitats has led to the depletion of Gentiana population and many representatives of the genus are protected by law. Some of the gentians having the status of endangered species, for example, are: Gentiana lutea L. - included in the Red Book of Bulgaria and of other European and world countries [66]; Gentiana kurroo Royle - close to extinction and legally protected by law [102]; Gentiana dinarica Beck - a rare and endangered species of the Balkan Dinaric Alps; Gentiana asclepiadea L. - distributed in South and Central Europe, Gentiana triflora, Gentiana punctata, Gentiana pneumonanthea - under protection of its progressively decreasing habitats; Gentiana dahurica Fisch – with exhausted natural resources though this species could be cultivated in some areas of the northwest of China; Gentiana straminea Maxim an endangered medicinal plant in the Qinghai-Tibet Plateau [103]. Due to problems with germination of seeds in in vivo conditions as well as the high variability of generatively propagated plants these species have attracted the attention of scientists being aware of the potential of biotechnology. The genetic variability of endemic or endangered species is usually very low and methods (like in vitro micropropagation) of conservation and restoration of natural resources have been given much attention in the last years. Despite the remarkable success of the tedious and wide investigations worldwide in vitro cultures of Gentiana species proved to be very difficult to achieve because of their low natural capacity of regeneration which was manifested in the multiplication in vitro, too [104].
First investigations on establishment of in vitro cultures of Gentiana were reported a quarter of century ago. Wesolowska et al. [105] succeeded in induction of callogenesis in G. punctata and G. panonica and of organogenesis and rhizogenesis in G. cruciata and G. purpurea. Authors observed that regenerated plants synthesize secoiridoids, which could not be found in the wild plants. This raised the hopes for the application of biotechnology techniques to other species of the Gentiana genus. The next decade the scientists explored the basic factors and plant requirements for establishment of in vitro cultures and micropropagation in various gentians. Different explants were tested for development of efficient regeneration schemes.
Using shoots and node fragments as explants, regeneration systems of Gentiana scabra var buergeri [106], Gentiana kurroo [107], Gentiana cerina, Gentiana corymbifera [65], Gentiana punctata [108], Gentiana triflora [109, 110] and Gentiana ligularia [111] were established. Stem segments with meristem tissue were appropriate explants to initiate tissue cultures and to induce formation of shoots de novo in four other species of Gentiana: G. lutea G. cruciata, G. acaulus and G. purpurea [66]. Different explants (shoot tips, lateral green buds, and root segments) were tested in Gentiana lutea [112]. Leaf explants were used as well to induce shoots of Gentiana macrophylla [113] and G. kurroo Royle [107, 114]. Vinterhalter et al. [115] micropropagated Gentiana dinarica Beck using axillary buds as explants.
Seeds in different stage of maturity were object of quite strong interest as an initial plant material for in vitro cultures. Considerably high germination of 54 % was achieved when seeds of G. corymbifera were cultured on a Murashige and Skoog (MS) medium containing 100 mg/l gibberellic acid (GA3) for 70 days. In the absence of GA3 germination did not exceed 5% [65].
Immature seeds in different stages of ripening were tested in order to find out the most suitable initial material to obtain in vitro cultures and multiplication of Gentiana lutea. Despite the addition of 0.5 mg/l of gibberellic acid to the MS medium, the average germination was quite low 21% [112]. Seedlings from immature and mature seeds of Gentiana pneumonanthe and Gentiana punctata were also chosen as initial material to excise shoot tips and one-nodal cuttings for induction of organogenesis and further clonal propagation [104, 116]. Petrova et al. [40] studied the possibility for micropropagation of Bulgarian ecotype of Gentiana lutea using stem segments with two leaves and apical or axillary buds excised from mature seeds germinated in vitro (Figure 1). To increase the germination seeds were treated with 0.03% GA3 for 24 hours. Some of the seeds were mechanically scarified in the micropile region. Germination was initiated on three variants of nutrient media based on MS and different concentration from 25 to 100 mg/l of GA3. In these investigations, GA3 and scarification stimulate G. lutea seed germination. Only 20 % of the non-scarified and 33.33 % of the scarified seeds germinated on the control medium. Giberrellic acid in concentration of 50 mg/l proved to have optimum effect resulting in 42.5 % germination for the nonscarified seeds and 60 % for the scarified ones. Lower and higher levels of GA3 stimulated in a less extend the seed germination but the response to GA3 of the scarified seeds was stronger than that of the non-scarified ones.
In vitro response is determined, as mentioned before, not only by the explant type but by the media composition as well and by the effect of the plant growth regulators on the dedifferentiation and redifferentiation processes undergoing in the explants cultured in vitro. Many reports, especially at the beginning of the in vitro investigations of gentians, pointed out that the cytokinine benzyl aminopurine BAP (or benzyl adenine BA) and the auxines indolacetic acid (IAA) or naphtilacetic acid (NAA) were the best plant growth regulators for induction of organogenesis and regeneration of plants which allowed establishment of a micropropagation schemes. Among the numerous examples, some of them were mentioned below as an illustration.
The initial results of Sharma et al. [107] were very promising reporting fifteen-fold shoot multiplication of Gentiana kurroo, which was obtained every 6 weeks on Murashige and Skoog\'s medium (MS) containing 8.9 μM benzyladenine and 1.1 μM 1-naphthaleneacetic acid. The efficiency of these plant growth regulators were confirmed in the experiments with other species. Optimal shoot multiplication of G. dinarica was achieved on MS medium enriched with 1.0 mg/l BA and 0.1 mg/l NAA [115]. The ideal medium for adventitious buds formation and for differentiation of calli contained 0.6 mg/l BA and 0.1 mg/l NAA [117] while the ideal medium for induction of calli from tender stems of Gentiana scabra was by substitution of NAA with 2,4 D in concentrations of 1.0-1.5 mg/l at the background of the same cytokinin –BA at lower concentration of 0.2 mg/l.
Momcilovic еt al. [66] observed that the optimal concentrations of the two plant hormones BAP and IAA were slightly different in the four investigated species Gentiana acaulis L., G. cruciata L., G. lutea L. and G. purpurea after different combinations of concentrations were tested (1.14 µM IAA with BA in various concentrations of 1.11-17.75 µM, or 8.88 µM BA with various IAA concentrations 0.57-9.13 µM). Excised nodal segments of axenically germinated seedlings were initially transferred to MS, supplemented with 8.88 µM BA and 1.14 µM IAA. Axillary buds started to grow on all node segments within a few days. Their stems remained short (5 to 15 mm for G. acaulis and G. cruciata, respectively) though the leaves reached a length between 25 mm (G. acaulis) and 120 mm (G. cruciata). Since only the shoots of 5-10 mm were chosen for subculturing, a four to six-fold multiplication was achieved every 4 weeks. Production of well-developed shoots was stimulated by increasing BA concentrations in the presence of 1.14 µM IAA. Indoleacetic acid concentrations higher than 2.28 µM suppressed shoot size in all investigated species. Similar observations were made by Zeleznik et al. [112] who induced shoots proliferation from Gentiana lutea shoot tips on MS medium supplemented with 1 mg/l of indoleacetic acid (IAA) and 0.1 mg/l benzyladenin (BA) which caused proliferation in one third of the cultured shoots in a period of 21 days.
The experiments went further in investigating the effect of more plant growth regulators. Based on the well known Murashige and Skoog nutrient medium and commonly used BAP and IAA a comparison was made with other cytokinins and auxins.
Seed germination of G. lutea on MG2 medium (MS basal medium enriched with 50 mg/l GA3) [40].
In vitro micropropagation of Gentiana lutea L. on MPl medium (MS basal medium enriched with 2 mg/l zeatin and 0.2 mg/l IAA) (The mean number of shoots per explant reaching 9 in Vth passage.) [40].
Bach and Pawlowska [116] studied the efficacy of four cytokinins (BA, kinetin, thidiazuron, 2-iP) and gibberellin at the concentration of 1.5 µM for propagation of Gentiana pneumonanthe. The highest multiplication rate was achieved in the culture of the one-nodal cuttings on medium supplemented with 10.0 µM BA. In other experiments [104] media supplemented with 2-iP or zeatin and IBA ensured a low multiplication of Gentiana punctata. Clonal propagation was slightly improved by addition of maize extract to the culture media.
Different concentrations and combinations of BAP (1 – 2 mg/l), zeatin (1 – 2 mg/l), IAA (0.1 – 0.2 mg/l), 2-iP (0.5 mg/l), and 2,4-D (0.5 mg/l) were used for bud induction and shoot multiplication of Gentiana lutea [40]. Best results were recorded on MP1 nutrient medium supplemented with 2 mg/l zeatin and 0.2 mg/ IAA. The mean shoot number per explant was relatively high reaching 4.57 and the average shoot height - 3.90 cm. Second in efficiency was MP3 nutrient medium supplemented with 2 mg/l BA and 0.2 mg/l IAA inducing 4.00 shoots on average per explant (Figure 2).
In vitro response may be influenced by other characteristics of the culture media like medium consistence. Sadiye Hayta et al [118] observed that efficient production of multiple shoots of G. cruciata L. directly from nodal segments, inducing 3.9 shoots per explants on average was stimulated on a semi-solidified Murashige and Skoog (MS) basic medium enriched with 2.22 μM 6-benzyladenine (BA), 2.46 μM indole-3-butyric acid (IBA) [118].
In gentiana’s experiments plant growth regulators were investigated not only as a factor for establishment of in vitro cultures but as a factor which may effect biosynthesis of the biologically active substances in the regenerated plantlets or shoots induced in vitro.
Similar observation about the influence of the plant growth regulators on the synthesis of secoiridoids, flavonoids and xantones was studied by Mencovic et al. [119]. There was tendency for a negative correlation between the levels of biologically active substances produced by the regenerants and the concentration of BAP and IAA added into the culture media.
Dević et al. [120] were interested in the effect of applied phytohormones on content of mangiferin in Gentiana asclepiadea L. in vitro cultures. The content of mangiferin in different plant material was determined by High Performance Liquid Chromatography (HPLC) analysis revealed that the content of mangiferin in the shoots obtained in vitro varied with different concentration of applied cytokinine and different auxins. There was no detectable content of mangiferin in roots obtained in vitro [120].
Rooting is the next crucial step after successful regeneration and multiplication of plants. Rooting was accomplished successfully in excised Gentiana kurroo shoots grown on MS basal medium containing 6% sucrose [107]. Pawlowska and Bach [116] observed too that in vitro multiplied shoots of Gentiana pneumonanthe formed roots on a medium without growth regulators. However, the auxins IAA, NAA, and IBA at a concentration of 0.5 µM and 1 µM stimulated rhizogenesis in excised axillary shoots with IAA demonstrating the best effect. Relatively high percentage of 52 % formation of roots from multiplied shoots of Gentiana lutea was achieved on MS medium supplemented with 2 mg/l of naphtalenacetic acid (NAA) [112]. Better results were reported by Petrova et al. [40] for Gentiana lutea when shoots were transferred to half strength MS medium enriched with either IAA (1 or 2 mg/l), IBA (2 or 3 mg/l) or NAA (0.5 or 3 mg/l). The best results of 92% and 91% rooting were obtained on half strength MS nutrient media containing 3 mg/l IBA or 3 mg/l NAA, respectively. Mean root length was almost equal in the both cases varying from 1.48 cm to 1.95 cm. Spontaneous rooting on plant Gentiana dinarica growth regulator-free medium occurred in some 30 % of shoot explants. Rooting was stimulated mostly by decreased mineral salt nutrition and a medium with half strength MS salts, 2% sucrose and 0.5–1.0 mg/l IBA was considered to be optimal for rooting. Wen Wei and Yang Ji [117] confirmed that the ideal medium for the rooting culture and rooting sub-culture of G. scabra tube seedling was 1/2 MS with 0.1 mg/l IAA and 0.3 mg/l NAA. The highest rooting of 81.7% of G. cruciata regenerants was also observed on half-strength MS medium supplemented with 2.46 μM IBA [118]. Beside the successful combinations of plant growth regulators inducing rooting there were reports on less favorable culture media. Butiuc-Keul et al. [104] report about failure in rhizogenesis induction in Gentiana punctata shoots transferred on medium supplemented with 1.0 mg/l each NAA and 2iP [104].
Acclimatization and adaptation efficiency varied with the species. In the early experiments, Pawlowska and Bach [116] achieved 65 % survival of rooted plantlets of Gentiana pneumonanthe after being potted in soil in a greenhouse. Further, the plants were successfully planted outdoors in field conditions. These in vitro regenerants had a greater number of flowers and stems than plants grown in a natural habitat. In vitro plantlets of Gentiana punctata have been transferred to soil after six weeks of culture and acclimatization was successfully obtained, too [104]. Peat-based substrate for rooting plantlets of Gentiana dinarica was successfully used, too [115].
Turf/vermiculite mixtures were very appropriate for acclimatization of plants with well-developed roots transferred to pots in growth chambers. All the acclimatized plants (100%) survived, remained healthy and analysis of the content of secondary metabolites in the clones was determined by HPLC. The presence of gentiopicroside, loganic acid, swertiamarin, and sweroside in the samples was confirmed. Gentiopicroside was found to be the major compound [118].
For the purposes of conservation of the endangered species and for restoration of their habitats it is of a great importance to maintain the genetic stability of the regenerated plants in vitro. In this aspect the investigations of Kaur R et al [121] are very interesting. Genetic stability of Gentiana kurroo micropropagated plants maintained in vitro for more than 10 years was studied using randomly amplified polymorphic DNA (RAPD) and karyotype analysis. A large number of micropropagated plantlets developed from nodal segment explants were assessed for genetic variations and compared with donor mother plant maintained in the arboretum. Out of 20 RAPD primers, 5 displayed the same banding profile within all the micropropagated plants and donor mother plant. No chromosomal variations were observed by the karyotype analysis. High multiplication rate of healthy plant material associated with molecular and karyotypic stability ensures the efficacy of the protocol to be used across a long period for in vitro propagation of this important medicinal plant species. These results are extremely important for the application of biotechnological methods and especially of micropropagation for the multiplication of the species for their conservation when in vitro clones should be identical to the donor mother plants from the natural habitats.
Somatic embryogenesis is another morphogenetic pathway for regeneration of plants, which is considered the most efficient way to regenerate plants [122]. In contrast to organogenesis when the buds and shoots are not formed obligatory from one cell, a somatic embryo derives from a single cell. This way of development assures greater genetic stability and identity with the initial plant. It opened new possibilities for large-scale multiplication of valuable plants with many expectations for mass production of artificial seeds.
However, somatic embryogenesis is more difficult to obtain. Nevertheless, it was successfully induced in a number of Gentiana species: Gentiana lutea [122, 123], Gentiana crassicaulis, Gentiana cruciata [123, 124], Gentiana pannonica [123], Gentiana tibetica [123], Gentiana pneumonanthe and G. kurroo Royle [116, 123, 125, 126, 127], Gentiana davidii var. formosana (Hayata) [128], Gentiana straminea [103, 129].
Like in the previously described experiments for micropropagation, one of the requirements leading to success is the appropriate choice of explants. The most commonly used explants were: leaves from the first and second whorls, the apical dome, and axenic shoot culture used for Gentiana kurroo (Royle), Gentiana cruciata (L.), Gentiana tibetica (King. ex Hook. f.), Gentiana lutea (L.), and Gentiana pannonica (Scop.) [123]; stem explants for initiation of callus and cell suspension cultures of G. davidii var. formosana [128]; hypocotyl (adjacent to cotyledons) of 10 days old seedlings of Gentiana cruciata [124]; seedling explants (root, hypocotyl and cotyledons) for Gentiana kurroo (Royle) embryogenic callus [125]; immature seeds (claimed to be superior initial material) of Gentiana straminea Maxim [129].
Plant growth regulators are the other very important factor for triggering the totipotence of the plant cell to develop somatic embryo. Unlike organogenesis and shoot formation in gentians where among the numerous tested plant growth regulators several cytokinines and auxins could be distinguished as more prominent, in the case with somatic embryogenesis it was difficult to point out the best ones. In a large number of combinations a wide spectrum of natural phytohormones and synthetic phytoregulators were examined: auxins like α-naphthaleneacetic acid (NAA), 2,4-dichlorophenoxyacetic acid (2,4-D), 3,6-dichloro-o-anisic acid (dicamba), and cytokinins: zeatin, 6-furfurylamonopurine (kinetin), N-phenyl-N′-1,2,3-thiadiazol-5-ylurea (TDZ), N-(2-chloro-4-pyridyl)N′-phenylurea, 6-benzylaminopurine (BAP) or benzyladenine (BA), and adenine sulfate. However, the natural auxin indoleacetic acid is not seen in this list. It makes impression that more auxins of synthetic origin are involved in the studies.
The role of the plant growth regulators will be illustrated by several examples of establishment of cell suspension cultures and somatic embryogenesis. One of the pioneer investigations was performed by Fu-Shin Chuen et al. [128]. Fast-growing suspension cell cultures of G. davidii var. formosana were established by subculturing callus, which was initiated from stem explants on MS basal medium supplemented with 0.2 mg/l kinetin and 1.0 mg/l NAA. Cell suspension growth was maintained in liquid MS basal medium supplemented with 0.2 mg/l kinetin and 3% sucrose. The cultures were incubated on an orbital shaker (80-100 rev/min) at 25 ± 1°C and low light intensity (2.33 μEm-2s-1). The low pH of 4.2-5.2 was crucial for the successful cell division and growth.
Quite interesting work from the early period of somatic embryogenesis was that one of Mikula et al., [124]. Authors investigated the effect of phytoregulators on Gentiana cruciata structure and ultrastructure changes occurring during tissue culture. MS induction medium containing 1.0 mg/l dicamba, 0.1 mg/l NAA, 2.0 mg/l BAP and 80 mg/l adenine sulfate was used for culturing of hypocotyl (adjacent to cotyledons) explants from 10 days old seedlings. During the first 2 days of culture cell division of epidermis and primary cortex was the first response. Numerous disturbances of karyo- and cytokinesis were observed, leading to formation of multinuclear cells. With time, the divisions ceased, and cortex cells underwent strong expansion, vacuolization and degradation. About the 6th day of culture, callus tissue was formed and the initial normal divisions of vascular cylinder cells were observed. Cells originating from that tissue were small, weakly vacuolated, with dense cytoplasm containing active-looking cell organelles and actively dividing leading to formation of embryogenic callus tissue. During the 6–8th week of culture, in the proximal end of the explant, masses of somatic embryos were formed from outer parts of intensively proliferating tissue. Production of somatic embryos was more effective from suspension culture than from agar medium. Liquid culture made it possible to maintain the cell suspension’s embryogenic competence for 5 years.
Quite vast and extensive studies on the establishment of gentians embryogenic cultures and their biotechnological potentials were carried by a research group with impressive publishing activity [114, 126, 130, 131]. Culture initiation and intensive callus proliferation of Gentiana cruciata were stimulated by 2,4-D and kinetin using various explants [130]. However, only some of the tissues of initial explant were able to form embryogenic callus. Cytological, ultrastructural and scanning analysis brought evidences that almost each of the cotyledon cells responded by callus formation and somatic embryo differentiation. Central cylinder of the hypocotyls gave the best response for embryogenic proliferation compared to other tissues of hypocotyls. Another medium containing 1.0 mg/l dicamba, 0.1 mg/l NAA, 2.0 mg/l BAP and 80 mg/l SA proved to be very efficient to maintain very long-term cell suspension cultures of proembryogenic masses. Long-term culture provided opportunities for numerous analysis to have evidences of the single cell origin of somatic embryos which originated from freely suspend single cells or single cells from the embryogenic clusters. Medium supplemented with GA3 helped to complete development and stimulated the somatic embryo conversion in germlings. Embryogenic potential was genotype dependent with G. tibetica and G. kurroo being outstanding generating more than hundreds somatic embryos from 100 mg of tissue for more than two years. Interestingly the regeneration ability was maintained not only in the long-term suspension cultures but it was demonstrated in the protoplast cultures, too [126].
Protoplasts with very high viability ranging from 88 to 96 % were isolated from cell suspensions derived from cotyledon and hypocotyl of Gentiana kurroo [126]. Three techniques of culture and six media were evaluated in terms of their efficiency in producing viable cultures and regenerating entire plants. The best results of plating efficiency (68.7% and 58.1% for cotyledon and hypocotyl derived suspensions, respectively) were obtained with agarose bead cultures in medium containing 0.5 mg/l 2,4-D and 1.0 mg/l kinetin. Regeneration of plants was also possible when embryos were transferred to half-strength MS medium. However, flow cytometry analysis revealed increased amounts of DNA in about one third of the regenerants which limits the application of isolated protoplasts in the programs for conservation and reproduction of an endangered species. Hence, the efforts were directed again to cell and tissue cultures examining the factors for efficient and reliable plant regeneration, even to examining photosynthetic activity in dependence of the sucrose content in the emryogenic culture media [126].
Fiuk and Rybczyn´ski [123, 125] expanded their studies using leaves derived from axenic shoot culture of five Gentiana species (Gentiana kurroo, Gentiana cruciata, Gentiana tibetica, Gentiana lutea, and Gentiana pannonica) and cultured on MS basal medium supplemented with three different auxins: 2,4-D, NAA, or dicamba in three concentrations of 0.5, 1.0, or 2.0 mg/l; and five different cytokinins: zeatin, kinetin, BAP, TDZ, and N-(2-chloro-4-pyridyl)N′-phenylurea in concentrations between 0.25 and 3.0 mg/l depending on the cytokinin activity. After two months the percentage of embryogenesis was the highest for G. kurroo reaching 54.7% and depending on plant growth regulators. This gentian was the only species responding to the all tested combinations of auxins and cytokinins, while none of the 189 induction media stimulated somatic embryogenesis from G. lutea explants. Efficiency of embryogenesis was genotype dependent G. tibetica and G. cruciata both produced an average of 6.6 somatic embryos per explant, while G. pannonica and G. kurroo regenerated at 15.7 and 14.2 somatic embryos per explant, respectively. Optimum regeneration was achieved in the presence of NAA combined with BAP or TDZ. NAA also stimulated abundant rhizogenesis. Somatic embryos were also regenerated from adventitious roots of G. kurroo, G. cruciata, and G. pannonica. Somatic embryos developed easily into plantlets on half strength MS medium.
The same research group extended its investigations on the factors influencing efficiency of somatic embryogenesis in cell suspension of Gentiana kurroo (Royle) - the species revealing the best morphogenic potential in their previous studies [125]. Suspension cultures were initiated in liquid MS medium supplemented with 0.5 mg/l 2,4-D and 1.0 mg/l kinetin from embryogenic callus derived from seedling roots, hypocotyls and cotyledons. Unexpectedly the highest growth rate was observed for root derived cell suspensions. Further more differences in aggregate structure depending on their size were detected by microscopic analysis. In order to assess the embryogenic capability of the particular culture, 100 mg of cell aggregates were implanted on MS agar medium supplemented with 0–2 mg/l kinetin, 0–2 mg l/l GA3 and 80 mg/l adenine sulfate. The highest number of somatic embryos was obtained for cotyledon-derived cell suspension on GA3-free medium, but the presence of the other plant growth regulators (0.5–1.0 mg/l kinetin, 0.5 mg/l GA3 and 80 mg/l adenine sulfate) determined the best morphological quality of embryos. The morphogenic competence of cultures also depended on the size of the aggregate fraction and was lower when size of aggregates decreased. Flow cytometry analysis revealed 100% uniformity for regenerants derived from cotyledon suspension but lack of uniformity of plantlets obtained from hypocotyls suspension. These observations were of great significance for the choice of appropriate explants and culture media conditions for the multiplication of a particular gentian species via somatic embryogenesis.
Cai YunFei et al. [129] confirmed the role of the explant and its interaction with the plant growth regulators added into the media of Gentiana straminea Maxim. They observed that calli induced from immature seeds were superior to those from hypocotyls or young leaves in regeneration via somatic embryogenesis and demonstrated that 2,4-D was efficient for both callus induction and embryogenesis, IAA is suitable for embryogenic callus proliferation, and BAP promotes both embryo development and the accumulation of gentiopicroside in the cultures. Experiments went further in exploring Gentiana in vitro cultures potentials by selecting regenerated plants for high gentiopicroside content. A highly productive clone was selected. Its cells contained 5.82 % of gentiopicroside, which levels were two folds higher than the control plants (1.20-3.73 %). Genetic stability of the regenerated plants was also proved both by cytological and random amplified polymorphic DNA analyses.
Similar experiments were performed with Gentiana straminea Maxim. MS medium supplemented with 2 mg/l 2,4-D and 0.5 mg/l BA was the best medium for embryogenic callus induction from leaf explants [103]. Genetic stability of the regenerants was assessed by 25 inter simple sequence repeat (ISSR) markers. Out of 25 ISSR markers, 14 produced clear, reproducible bands with a mean of 6.9 bands per marker confirming that the regenerants maintained high genetic fidelity.
One of the recent reports [122] presented interesting results for the possibility to use recurrent somatic embryogenesis in long-term cultures of Gentiana lutea for production of synthetic seeds. After induction of somatic embryogenesis in the presence of auxins in the first cycle of in vitro cultures, recurrent somatic embryogenesis was performed in long-term cultures in the absence of phytohormones but in the presence of the sugar alcohols mannitol and sorbitol. Adventive somatic embryos were generated continuously at a high rate along with maturation, germination and development into plants.
One of the possibilities of biotechnology for conservation of rare species is the establishment of in\n\t\t\t\tvitro germplasm banks, which may include cryopreservation of in vitro multiplied valuable plant material. There are several interesting publications of one research group dedicated to this problem [124].
For preservation of proembryogenic masses of G. cruciata, four protocols of cryopreservation were studied: direct cooling, sorbitol/DMSO treatment, vitrification, and encapsulation. Direct cooling and sorbitol/DMSO treatment was unsuccessful. Vitrified tissue required a minimum 3 weeks culture on solid medium for cell proliferation to reach the proper fresh weight for manipulation. Alginate beads with PEMs were transferred directly to liquid medium for post-freezing culture. Vitrification and encapsulation maintained high viability of post-freezing proembryogenic masses, but encapsulation ensured faster restoration of G. cruciata cell suspension [124]. A reliable technique for cryopreservation by encapsulation was developed for two suspension cultures of Gentiana species (Gentiana tibetica and G. cruciata) of different ages and embryogenic potential. A water content of 24-30% (fresh weight basis) after 5-6 h dehydration of encapsulated cells of gentians yielded the highest survival (68% for G. tibetica and 83% for G. cruciata) after cryopreservation. Flow cytometry showed that cryopreservation did not change the genome size neither of the somatic embryos nor of the regenerants [132]. The embryogenic cell suspension culture of Gentiana cruciata, cryopreserved by the encapsulation/dehydration method, survived both short- (48 h) and long-term (1.5 years) cryostorage with more than 80% viability. The (epi)genetic stability of 288 regenerants derived from: non-cryotreated, short-term, and long-term cryo-stored tissue was studied using metAFLP markers and ten primer combinations. AFLP alterations were observed but they were not associated with the use of cryopreservation, but were probably related to the in vitro culture processes [133]. These results gave great hopes for the use of cryo-techniques in preservation of valuable medicinal species.
Genetic transformation was also applied to gentiana species aiming at obtaining higher production of biologically active substances or biosynthesis of new valuable compounds. Agrobacterium rhizogenes mediated transformation was achieved in shoots of micropropagated Gentiana acaulis, G. cruciata, G. lutea, and G. purpurea inoculated with suspensions of Agrobacterium rhizogenes cells [134, 135]. Few years later Menkovic et al [119] after infection with Agrobacterium rhizogenes managed to obtain nine hairy root clones which differed in the amount of secondary metabolites. Agrobacterium\n\t\t\t\ttumefaciens was also used for inoculation of Gentiana punctata [136] and Gentiana dahurica Fisch by A.\n\t\t\t\ttumefaciens [137]. However, due to the great opposition in many countries against the genetically modified organisms, especially these ones with potential use in food and nutraceutical industries genetic transformation experiments remained more in the laboratory mainly to study the metabolic pathways.
Genus Leucojum.\n\t\t\t\tLeucojum aestivum (summer snowflake) is one of the most worshiped medicinal plants on the Balkan region and in the world. Leucojum aestivum L. (Amaryllidaceae family) is a polycarpic geophyte distributed in the wetlands of Central and South Europe (Mediterranean and the Balkans) and in West Asia. L. aestivum grows on alluvial soils with high nitrogen levels. The mean size of the plants increased with the water content of the soil. Seed reproduction is whimsical. Seed set of the plants was not influenced by the size of a population, but strongly increased with the density of flowering plants. Optimal temperature for seed germination is 20-25oC [138]. Overharvesting of its bulbs for medical purposes has brought to a destruction or alteration of its habitats across Europe [138]. Therefore, summer snowflake has turned into an endangered species and is protected in several European countries (e.g. Bulgaria, Hungary and Ukraine).
Leucojum aestivum L. is used as a source of galanthamine - an isoquinoline alkaloid produced exclusively by plants of the family Amaryllidaceae (mainly belonging to the genus Galanthus, Leucojum and Narcissus). Due to its acetylcholinesterase inhibitory activity, galanthamine is used for various medical preparations for the treatment of neurological disorders and especially for senile dementia (Alzheimer’s disease) and infantile paralysis (poliomyelitis). A very effective Bulgarian remedy to cure poliomyelitis was produced from L. aestuvum in the middle of the XXth century. This marked tremendous interest and respect of the plant and enormous demands for raw material. Despite the possibility for organic synthesis, galanthamine is still extracted from natural sources. For industrial purposes L. aestivum plants are harvested from wild populations in their natural habitats which causes increasing problems regarding quality of the plant material as well as natural populations depletion. The limited availability of the plants and the increasing demands for this valuable metabolite has imposed urgent search for alternative approaches both for protection of the species and for production of galanthamine. In this respect biotechnology methods could be used for in vitro storage of genotype accessions from different natural populations with proven alkaloid profiles, for rapid propagation of this threatened medicinal plant for both industry and natural resource protection, and for production of its valuable biologically active substances under controlled conditions. However, not so much data are available in the literature concerning in vitro cultures of this plant.
The Bulgarian scientists Stanilova et al. [38] and Zagorska et al [139] are pioneer in establishment of in vitro cultures and micropropagataion of Leucojum aestivum. One of the prerequisites for their success was the elaboration of a successful procedure for decontamination of the plant material gathered from nature. Plant material should be used 42 days after collecting. The bulbs were rinsed for 16 hours with stream water followed by immersion in 70% ethanol for 30 s and sterilized with 0.1% HgCl2 for 3 min. Relatively good decontamination was achieved for leaf explants applying hypochlorites – 47.46% using 5% Ca (ClO)2 for 6 min and 54.76% - 15% NaClO for 20 min. During their initial studies of the morphogenetic potential of the basal and apical parts of bulbs, stems, leaves and ovaries it was observed that the scales of L. aestivum possessed the highest regenerative ability producing 4.08 - 4.19 regenerants per explant. Whereas leaf explants had lower regeneration potential – 1.67 regenerants per explant. Murashige and Skoog (MS) medium supplemented with 1 mg/l benzyladenine (BA) and 1 mg/l kinetin as well as Linsmaier and Skoog (LS) medium enriched with 0.5 mg/l NAA and 0.1 mg/l kinetin proved to be the most suitable for direct organogenesis [38]. Rhyzogenesis was induced on MS basal medium with reduced sugar content of 15 g/l and enriched with 0.1 mg/l NAA, 0.1 mg/l kinetin and 0.1 mg/l BAP. Further investigations focused on in vitro clonal propagation of L. aestivum. Twenty four clones were obtained and most of them demonstrated high regeneration rates and stable alkaloid profiles. Galanthamine levels of some of the in vitro obtained clones was as high as galantamine levels of commercially important representative of Bulgarian L. aestivum populations. Five clones: four galanthamine-type and one lycorine-type were selected as promising for further investigations [140].
In Turkey Karaogˇlu [141] confirmed the effectiveness of bulb-scales explants for micropropagation of Leucojum aestivum and tested immature embryos for initiation of in vitro cultures. Using 2 and 4 bulb-scales explants the highest number of bulblets (6.67 and 5.83) were achieved on MS medium containing 1 mg/l BA and 1 mg/l NAA or 2 mg/l BAP and 0.5 mg/l NAA, respectively. Regeneration capacity of immature embryos was twice lower reaching 2.27 bulblets on MS medium containing 0.5 mg/l BA and 4 mg/l NAA. The best rooting of bulblets regenerated from bulb scales was obtained on MS medium containing 1 mg/l NAA. Rooted bulbs were finally transferred to compost and acclimatized to ambient conditions [141].
Later in vitro cultures of Leucojum aestivum were reported in Hungary. Kohut et al. [142] succeeded to obtain from 81 % to 92 % contamination free material. Prior to surface sterilization the old leaves and roots were dissected from the bulbs and they were stored at low temperature of 2–3°C for 1 and 5 week periods. The bulbs, bulb scales and leaves of the bulbs were placed on MS medium containing 1 mg/l BA and 0.1 mg/l NAA.
Shoot in vitro cultures were initiated also from bulb explants in others’ experiments [143]. However, Gamborg’s B5 medium was used for the initiation and maintaining of the cultures, which were kept in darkness. This medium contained 30 g/l of sucrose, 1 mg/l 2,4-D, 0.5 g/l casein hydrolysate, 2 mg/l adenine, and 10 mg/l glutathione. The in vitro cultures were subcultured at 2.5 month intervals in MS medium supplemented with 1 g/l Ca(NO3)2, 0.5 mg/l BAP, 0.01 mg/l IBA, and 2.93 mg/l paclobutrazol. During the subcultures, shoot-clumps which were formed were cut to increase the number of explants, and the newly formed shoot clumps were separated. The in vitro cultures were maintained at 23-25o C with a 16/8 h light /dark photoperiod. Later the same research group [144] offered a three step protocol for in vitro long-term conservation of L. aestivum which was used to create a genebank with accessions from 31 Bulgarian populations. For in vitro cultures dormant bulbs were used, which were cut into 8, 16 or more segments. For sterilization, these segments called “twin-scale” were treated with 70% ethanol for 30 s and sterilized with 1% HgCl2 for 3 min. The development of the shoot-clumps started from the basal parts of the scales at the end of the first week. The development of in vitro shoot-clump cultures was tested on three nutrient media: МS, B5, and QL with or without plant growth regulators, BAP (0.5 - 3.0 mg/l), IBA (0.01 - 1 mg/l) NAA (0.2 - 2 mg/l) and TDZ (1 - 2 mg/l), sucrose (0 - 120 g/l), and charcoal (2g/l). Shoot-clumps were obtained, from explants cultivated on B5 medium (6), supplemented with 0.5 g casein hydrolyzate, 1 mg/l 2,4-D, 10 mg/l adenine, 10 mg/l glutathione, 30 g/l sucrose, 6 g/l agar. The fastest multiplication however was observed on МS medium with 30 g/l sucrose, 2 mg/l BAP, 1.15 mg/l NAA. Increasing sucrose concentration up to 90 g/l resulted in higher mass of the obtained bulbs. About 1000 regenerated bulbs with well-developed roots were successfully adapted at ex vitro conditions. Authors observed that plant ex vitro adaptation depended on the bulb size. The biggest bulbs (over 1.5 cm in size) were the most adapted (99 %) whereas about 60% of the medium size bulbs (0.5-1.5 сm) and 20% of the small bulbs (less than 0.5 сm) survived. Mainly easily rooting bulbs were formed on hormone free nutrient medium (МS with vitamins, sucrose-30 g/l, charcoal - 2 g/l, and pH-5.6) [144].
Callus cultures from young fruits of Leucojum aestivum\n\t\t\t\tL. were obtained, too [145]. Non-differentiated cell growth was stimulated by high concentrations of the auxin 2,4-D (4 mg/l) and the cytokinin BA 2 mg/l. Callus tissue formed regenerants when 1.15 mg/l NAA and 2 mg/l BA were added to the MS medium.
Somatic embryos were formed from callus tissues cultivated on MS medium containing 2 μМ or 5 μМ picloram (4-amino- 3,5,6-trichloropicolinic acid) and 0.5 μМ BAP [146]. Regeneration of plants was possible on medium enriched with zeatin (0.5 μМ). Authors observed that the processes of differentiated or non-differentiated growth leading to somatic embryogenesis or callus growth, respectively, were influenced by ethylene or its precursor ACC (1-aminocyclopropane-1-carboxylic acid). At higher concentrations (25 μМ) of picloram callus cultures produced ethylene (9.5 nL/g fresh weight: F.W.) whereas no ethylene was detected in cultures of somatic embryos cultivated on medium supplemented with 0.5 μМ NAA and 5 μМ zeatin. Application of ACC increased ethylene production thus suppressing callus growth and enhancing somatic embryos induction and globular embryos development. Another effect of ACC was to induce galanthamine production in somatic embryo cultures (2% dry weight). However, galanthamine production in callus cultures was induced by silver thiosulphate (STS) though in low levels (0.1% dry weight). These results are promising for use of somatic embryos cultures in bioreactors for production of galanthamine [146].
Alkaloid content in Leucojum aestivum wild plants and their in vitro cultures was studied in a series of experiments carried out by a Bulgarian research group [143, 145, 147 - 150]. Callus cultures were obtained from young fruits of Leucojum aestivum on MS nutrient medium supplemented with 4 mg/l 2,4 D and 2 mg/l BAP. Further, shoot cultures were established by subculturing the obtained calli on the same nutrient medium supplemented with 1.15 mg/l NAA and 2.0 mg/l BAP. These in vitro systems were used to study the growth and galanthamine accumulation. The authors observed that the amount of accumulated galanthamine strongly depended on the level of tissues differentiation. The maximum yield of biomass (17.8 g/l) and the maximum amount of accumulated galanthamine (2.5 mg/l) were achieved under illumination after the 35th day of submerged cultivation of one of the lines L. aestivum -80 shoot culture.
The alkaloids of intact plants, calli and shoot-clump cultures of L. aestivum were analyzed by capillary gas chromatography – mass spectrometry (CGC-MS). In one series of experiments fourteen alkaloids of galanthamine, lycorine and crinane types were identified (11 in the intact plants and eight in the in vitro cultures) in alkaloid mixtures extracted from intact plants and in vitro cultures. Excellent peak resolution for the alkaloids was exhibited and isomers of galanthamine and N-formylnorgalanthamine were well separated [147]. Applying the same methods of CGC-MS, extracts from bulbs collected from 18 Bulgarian populations and from shoot-clumps obtained in vitro from eight different populations were subjected to analysis and nineteen alkaloids were detected. Typically, galanthamine type compounds dominated in the alkaloid fractions of L. aestivum bulbs but lycorine, haemanthamine and homolycorine type alkaloids were also found as dominant compounds in some of the samples. Galanthamine or lycorine as main alkaloids presented in the extracts from the shoot-clumps obtained in vitro. The galanthamine content ranged from traces to 454 μg/g dry weights in the shoot-clumps while it was from 28 to 2104 μg/g dry weight in the bulbs [143]. In other investigations twenty-four alkaloids were detected analizing intact plants, calli and shoot-clump cultures. Shoot-clumps had similar profiles to those of the intact plant while calli were characterized with sparse alkaloid profiles. Seven shoot-clump clones produced galanthamine predominantly whereas another three were dominated by lycorine. It was also observed that illumination stimulated accumulation of galanthamine (an average of 74 µg/g of dry weight) in shoot-clump strains while in darkness galanthamine levels were two folds less (an average of 39 µg/g of dry weight). The shoot-clumps, compared to intact plants, accumulated 5-folds less galanthamine. The high variability of both the galanthamine content (67% and 75% of coefficient of variation under light and darkness conditions, respectively) and alkaloid patterns indicated that the shoot-clump cultures initiated from callus could be used as a tool for improvement of the in vitro cultures production of the valuable substances [148]. The investigations extended on the alkaloid patterns in L. aestivum shoot culture cultivated at temporary immersion conditions where 18 alkaloids were identified, too. The temperature of cultivation influenced enzyme activities, catalyzing phenol oxidative coupling of 4\'-O-methylnorbelladine and formation of the different groups Amaryllidaceae alkaloids. Decreasing the temperature of cultivation of L. aestivum 80 shoot culture led to activation of para-ortho\' phenol oxidative coupling (formation of galanthamine type alkaloids) and inhibited ortho-para\' and para-para\' phenol oxidative coupling (formation of lycorine and haemanthamine types alkaloids). The L. aestivum 80 shoot culture, cultivated at temporary immersion conditions, was considered a prospective biological matrix for obtaining wide range of Amaryllidaceae alkaloids, showing valuable biological and pharmacological activities [150]. The most recent report was about successful cultivation of shoot culture of summer snowflake in an advanced modified glass-column bioreactor with internal sections for production of Amaryllidaceae alkaloids. The highest amounts of dry biomass (20.8 g/l) and galanthamine (1.7 mg/l) were obtained when shoots were cultured at temperature of 22°C and 18 l/(l h) flow rate of inlet air. At these conditions, the L. aestivum shoot culture possessed mixotrophic-type nutrition, synthesizing the highest amounts of chlorophyll (0.24 mg/g DW (dry weight) chlorophyll A and 0.13 mg/g DW chlorophyll B). The alkaloids extract of shoot biomass showed high acetylcholinesterase inhibitory activity (IC50 = 4.6 mg). The gas chromatography–mass spectrometry (GC/MS) profiling of biosynthesized alkaloids revealed that galanthamine and related compounds were presented in higher extracellular proportions while lycorine and hemanthamine-type compounds had higher intracellular proportions. The developed modified bubble-column bioreactor with internal sections provided conditions ensuring the growth and galanthamine production by L. aestivum shoot culture [149]. The influence of the nutrient medium, weight of inoculum, and size of bioreactor on both growth and galanthamine production was studied in different bioreactor systems (shaking and nonshaking batch culture, temporary immersion system, bubble bioreactor, continuous and discontinuous gassing bioreactor) under different culture conditions. The maximal yield of galanthamine (19.416 mg) was achieved by cultivating the L. aestivum shoots (10 g of fresh inoculum) in a temporary immersion system in a 1l bioreactor vessel which was used as an airlift culture vessel, gassing 12 times per day (5 min) [151].
Completely different types of experiments were the attempts of genetic transformation with Agrobacterium. Agrobacterium rhizogenes strain LBA 9402 has been tested [152] for its capacity to induce hairy roots of this monocotyledonae plant. Diop et al. [152] have developed an efficient transformation system for L. aestivum, which could be used to introduce genes encoding enzymes of isoquinoline alkaloid biosynthesis into L. aestivum to enhance the production of target molecules in this medicinal plant. However, the transformed roots obtained did not synthesize galanthamine.
At this stage of in vitro research establishment of organogenic cultures and optimization of galanthamine production by differentiated cells using the methods of biotransformation are more promising and reliable.
Genus Rhodiola is highly varied among others in family Crassulaceae (comprising of 1500 species in 35 genus). The genus Rhodiola includes over 200 quite polymorphic species, out of which 20 species (Rh. alterna, Rh. brevipetiolata, Rh. crenulata, Rh. kirilowii, Rh. quadrifida, Rh. sachalinensis, Rh. Sacra etc.) have pharmacological properties and are used for production of medical preparations [153].
Intensive and unscrupulous exploitation of the natural habitats in many countries has led to extinction of these species in these regions [154]. This provoked nature-protecting measures to be undertaken like (1) cultivation under appropriate conditions, (2) protection of the populations in the protected areas, (3) including the species in Red Books of rare and endangered plants species. Rhodiola species contain various quantities of salidrosid – one of the most important ingredients in the biological active complex [155 - 159]. Salidroside content in plants varies depending on the genetical structure, the developmental stages, the plant age, the ecological and agrobiological conditions [160] what is one of the reasons for the scientists to look for conditions minimizing these effects by biotechnological way of more controlled production of this biologically active compound. From another hand extracts from medicinal plants are rich in other metabolites bringing to the multiple health benefits [159] what stimulates search and identification of more biologically active substances which can be produced in cultures in vitro.
In Bulgaria Rhodiola rosea (Golden root, Roose root) (Sedum roseum (L.) Scop., S. rhodiola DC.) is under protection of the Act for biological diversity [161]. Rhodiola rosea is included in the Red Books of Republic of Buryatia AR, of Yakut ASSR, of Mongolia; “Rare and Extinct Plant Species in Tyva Republic,” “Rare and Extinct Plant Species in Siberia,” in Great Britain—Cheffings & Farrell, in Finland—category “last concerned.”(according to IUCN Red List Categories and Criteria: Version 3.1 (IUCN, 2001).
Rhodiola rosea species are worshiped for their roots and rhizomes therapethical role in many diseaases. Rhadix et Rhizoma Rhodiolae of Rh. rosea are used in medicine for optimization of own-body biochemical and functional reserves of the organism, for stimulation of body’s nonspecific resistance for regulation of the metabolism, central nervous system, cardiovascular system and the hormonal system [162 – 164] for rehabilitation after heavy diseases, for prophylactics of onco disease [153, 159, 165], etc. Rhodiola quadrifida (Pall.) Fisch. et May is a perennial grassy plant growing predominantly in some highland regions of the former USSR (Altai, Sayan), in East Siberia, in some mountainous regions of China (Sichuan) and in high mountain regions of Mongolia. It is used in traditional medicine of Mongolia and Tibet, against fatigue, stress, infections, inflammatory diseases and protection of people against cardiopulmonary function problems when moving to high altitude [166; 167]. The phytochemical composition of the ingredients (without cinnamic alcohol and rosiridin) is similar to that of Rh. rosea [168]. Rhodiola kirilowii is a Chinese medicinal herb. Roots and rhizomes extracts are used in Asiatic medicine independently of their adaptogenic properties also as antimicrobial and anti-inflammatory drugs [169, 170]. Rhodiola sacra grow in the Changbai Mountain area, Tibet and Xinjiang autonomous regions in China. In Tibetan folk medicine, Rhodiola Radix is used as a hemostatic, tonic and contusion releaf factor. Positive effects on learning and memory have been reported, too [171, 172]. Rhodiola crenulata is distributed in the high cold region of the Northern Hemisphere in the high plateau region of southwestern China, especially the Hengduan Mountains region including eastern Tibet, northern Yunnan and western Sichuan. It has strong activities of anti-anoxia, antifatigue, anti-toxic, anti-radiation, anti-tumour, anti-aging, and active-oxygen scavenging [173, 174]. Rhodiola sachalinesis A. Bor. is used as a drug of “source of adaptation to environment” in Chinese traditional medicine. Salidroside can effectively enhance the body’s ability to resist anoxia, microwave radiation, and fatigue. Furthermore, its effect on extending human life was also found [175]. Rhodiola imbricata Edgew commonly known as rose root, is found in the high altitude regions (more than 4000 m altitude) of India. The radioprotective effect, along with its relevant superoxide ion scavenging, metal chelation, antioxidant, anti-lipid peroxidation and anti-hemolytic activities were evaluated under both in vitro and in vivo conditions [176]. Rhodiola iremelica Boriss. – is an endemic plant of Middle and South Ural mountain. It is included in the Red Book of Republic of Bashkortostan (Bashkiria) in the category of rare and endangered species. Rh. iremelica is located in places with different climatic conditions making them unique [177].
Despite the incontestable/undisputed interest to Rh. rosea and the wide intensive research in phytochemistry, the potential area of the plant biotechnologies, remains less studied and exploited in comparison to other medicinal species. Some of the researchers studied the possibility for induction of calli cultures, biotransformation and organogenesis. Other authors focus their research on Rhodiola potential for regeneration and investigation of biologically active substances. Experiments are focused mainly in two directions: 1) looking for possibilities for in vitro synthesis of valuable metabolites and/or 2) establishment of effective systems for micropropagation, for reintroduction of the plant in nature or in the field for protection of the species.
Pioneer experiments on golden root in vitro cultures were initiated 20 years ago [178] from a Russian scientist who described rooting of assimilating of sprouts R. rosea. Later a few other reports have appeared concerning the effect of culture media composition and of explant type on the ability for callogenesis, organogenesis and regeneration of R. rosea, as well as other factors influencing growth and morphogenesis. Using leaf segments Kirichenko et al. [179] studied callus and regeneration ability for propagation in vitro of rose root while Bazuk et al. [180] focused on the rooting potential of shoots obtained from stem segments with two adjacent leaves. Investigations that are more detailed were carried using seeds and rhizomes from three ecotypes from the High Altai and South Ural region, which served as the explant source to study induction of callogenesis and organogenesis [181]. Explant development was observed on MS media containing various phytoregulators (BAP, IAA, NAA, IBA, 2,4-D). Very high percentage of 86% of the explants formed abundant calli on MS medium supplemented with 0.1 - 0.2 mg/l IAA. BAP and IAA in concentrations of 0.2mg/l and 0.1mg/l, respectively, was the optimal combination for multiple bud formation in Rhodiola rosea from stem segments, while for Rhodiola iremelica the efficient concentrations were lower—0.1 mg/l BAP and 0.05 mg/l IAA. The processes of efficient callogenesis and organogenesis were influenced by ecotype differences. Adaptation of regenerants in vermiculite for two weeks in conditions of high humidity (85–90%) and later in mixture of soil, peat, and vermiculite in proportion of 1 : 1 : 1 was successful, but with considerable differences in the survival rate (from 10% to 95%). In the later experiments [182], the effect of 5% or 10% v/v liquid extracts of Rh. rosea extracts on the morphogenic abilities of Rh. rosea and Rh. iremelica were studied. Different in vitro responses were provoked. Bud induction was stimulated by the lower concentration and inhibited by the higher ones leading to formation of 8.5 shoots per explant in the first case and 1.1 in the second case.
Unlike the previously described investigations with the Altai ecotype of Rhodiola rosea the optimal concentrations of the cytokinin BAP were 10–15-fold higher for induction of in vitro cultures from immature leaves explants from a Tibetan ecotype of golden root [183]. The authors noted interaction between the growth regulators and the illumination of the cultures. Two mg/l BA and 0.2 mg/l NAA added to the MS medium stimulated formation of incompact callus tissue. However, when explants were cultivated under dark conditions, higher concentrations of the same phytoregulators BA (3 mg/l) and NAA (0.25 mg/l) were more efficient. MS medium containing 2 mg/l BA and 0.25 mg/l NAA induced shoot multiplication while rooting was induced on MS medium containing 0.5 mg/l or 1 mg/l IAA.
In Bulgaria the first investigations on Rhodiola rosea were on the content of polyfenols and salidrosid in the local populations in Rila, Pirin and Balkan Mountain [184]. The highest salidrosid levels in the rhizome and root were found in the plants from Rila Mountain while the lowest ones in the plants from Pirin Mountain 1.55 % and 0.72 %, respectively. From another side polyphenols were in highest concentration in rose root from Pirin population. Salidrosid is accumulated in roots and rhizomes while polyphenol content is equal in all parts of the plant [185, 186].
Seeds of Rhodiola rosea lose their germination potential for a relatively short perod of time compared to other species. Stratification is one of the approaches for overcoming this problem. Revina et al. [187] reported about higher germination up to 75 % after treatment of seeds for one month at temperatures of 2-4 оС. Other authors confirm the role of stratification [188] and report about stimulation of germination up to 50-75 % after subjecting seeds to lower temperatures of -5оС for a period of 3 months [189]. Dimitrov et al. [190] applied a new approach for in vitro cultivation of seeds. Golden root germination of seeds started on the 7th day of cultivation and lasted until the 40th day reaching from 37.5% to 97.0% depending on media composition. Germination was stimulated when seeds were cultured on MS basal medium enriched with 50-100 mg/l giberrellic acid. These high concentrations of GA3 enhanced germination while lower concentrations of 5-25 mg/l GA3 favored obtaining of seedlings with bigger size [43].
The initial investigations for establishment of golden root in viro cultures in Bulgaria were dedicated to find out a suitable ecotype for in vitro experiments [190 – 192]. Tasheva et al. [193, 194] optimized seed germination in vitro and later report the first successful results for in vitro propagation of Rhodiola rosea. A large number of explants isolated from in vitro seedlings (stem segment with leaf node, apical bud, explants excised from the seedling root basal area) and in vivo plant (apical bud, adventitious shoots, stem expalnt, rhizome buds, rhizome segments) were used to study in vitro response [195] on Murashige and Skoog (MS) basal medium containing various hormonal combinations including benzyladenine, kinetin, zeatin, 2-ip etc. In vitro development led to formation of plantlets, leaf rosette, various type of callus (compact green, pale, soft liquidy) and callus degeneration without bud formation. The authors observed that the explants of seedling and apical bud are more suitable for mass clonal propagation. Multiple shoots proliferation from leaf node explants was most effective on nutrient medium containing 1.0 or 2.0 mg/l zeatin, 0.1 mg/l IAA and 0.4 mg/l GA 3 (Figure 3 a,\n\t\t\t\tFigure 3 b). Rooting in vitro proved to be the most efficient on nutrient medium containing IBA (2.0 mg/l), IAA (0.2 mg/l) and GA3 (0.4 mg/l) [195]. Interestingly, it was observed that the coefficient of propagation varied during the different seasons. Highest level of proliferation was recorded in May-June, when the mean number of shoots per explant was 6.78, while during the cold seasons multiplication was relatively lower with 2.11 shoots per explant [196]. Adaptation of obtained plants was done under controlled conditions in a cultivation room for 2-3 months and later grown plants were transferred to green house, where survival rate reached high levels of 85% (Figure 3 c). After 6 months, these regenerants were rooted in natural conditions in the Rhodopes Mountains experimental field where the survival rate was 68%, after winter has passed. In April, vigorous vegetation was observed with formation of sprouts, floweres, seeds and rhizomes like plants in their natural environment.
Genetic stability of in vitro regenerated plants is very important for micropropagation aiming production of elite plant material or conservation of the species. Chromosome number in the root tip cells of in vitro regenerats of Rhodiola rosea was examined. All the plantlets though obtained on different media had 22 chromosomes which number was identical with the diploid chromosome number of 2n = 22 of the wild plant. These results indicate that the regeneration schemes developed by authors [197] favor stability of the initial caryotype. This fact is very important for the purposes of restoration of the species and for creating nurseries and fields of Golden root serving the pharmacological needs.
Another very important fact is the ability of in vitro obtained plants to synthetize salidroside what was confirmed by the analysis of one and two years old regenerants. Salidroside content in all the samples taken from the roots of regenerants reintroduced in nature was higher than those in plants, which developed from seeds in the mountains [198].
Roots and rhizome from one year old plant regenerants growing in the green house have lower salidroside content compared to the plants growing in the experimental field in the mountains at an altitude of 560 m. However, at the same conditions high levels of rosavin 3.2 % and 3.3 % were detected in green house plants and in mountain plants, respectively (unpublished data). Golden root extracts used in major part of the clinical research are standardized to 3.0 % of rozavins and 0.8% salidroside, which is a ratio of 3:1. This ratio was 10.75:1 in the experiments of the authors (unpublished data) for green house one year old regenerants. Similarly one and three years old regenerants growing in the mountains had higher portion of rozavins compared to salidroside (1 : 8.6 and 1 : 3.75, respectively) which was very positive fact (unpublished data)
Recently replanting of Rhodiola rosea regenerants in natural conditions was reported from other authors, too [199] but unlike the previous report [43] reintroduced regenerants differ morphologically. Several types of explants and nutrient media were used to reveal the morphogenic potential suitable for elaborating shemes for micropropagation [199]. The most efficient combinations were when explants from shoot nodes and apices were cultured on MS medium containing 2.0 mg/l NAA, followed by hormone free MS, then KN (1 mg/l kinetin and 0.5 mg/l NAA), and AZ (0.2 mg/l IAA and 2 mg/l zeatin). The in vitro generated neo plantlets reached survival rate over 90% after transfer to septic environment in a hydroponic system for 5-7 days. After acclimatization, the regenerants were potted into soil until the first summer when they were transferred to their native habitat (at 1750 m altitude in Ceahlău Mountains, Romania). During the next summer about 73.5 % of the few dozens of reintroduced regenerants survived. This percentage dropped at 57 % during the third year. It was observed that the in vitro regenerants of Rh. rosea developing in their natural habitat differed in leaf color (light green), compared to the native individuals of this region (green- grey).
In vitro regenerants of Rhodiola rosea Bulgarian ecotype: (a) and (b) – propagated plants on MS medium enriched zeatin; (c) – two years old regenerants growing in green house.
For the first time an original protocol for in vitro micropropagation of Rhodiola rosea in a RITA bioreactor system was reported [200]. Three clones were obtained from in vitro germinated seedlings of wild Finland golden root. Stimulation of organogenesis was studied using thidiazuron and zeatin. Two to four μM thidiazuron stimulated shoot induction but inhibited shoot growth while 1-2 μM zeatin favored shoot growth and leaf number per shoot. Multiplication rate of the clones differed significantly but the most efficient was obtained on solidified medium enriched with 2 μM zeatin. In the bioreactor 0.5 μM thidiazuron maintained rapid shoot proliferation but induced hyperhydracity at higher concentrations. However, hyperhydracity was abolished when shoots were transferred for 4 weeks on gelled medium enriched with 1-2 μM zeatin. Shoots formed roots for 5-6 weeks on medium without phytoregulators. Regenerants transferred to soil in the green hause surved at high rate (85–90%) and after acclimatization had normal shoot and leaf morphology.
After establishment of reliable Rhodiolain vitro cultures, research has continued for their implementation for practical use like production of valuable secondary metabolites in bioreactors, for biotransformation, for manipulation of the metabolic pathways and metabolic engineering. Biotransformation is a key mechanism to increase production of the biologically active compounds in callus cultures. There are few reports on golden root callus cultures with acompaning analysis of their biologically active metabolites and description of the parameters for their efficient synthesis in vitro. The first attempts dated a decade ago [201]. Callus was induced on leaf explants of Rhodiola rosea and transferred into MS liquid medium. Thus obtained suspension culture was used to to study the possibility to increase synthesis of rosavin and other cinnamyl glycosides. In the cells for about 3 days, more than 90% of the added transcinnamyl alcohol (optimal concentration of 2.5 mM) was transformed into various unidentified products. However, one of them, 3-phenyl-2-propenyl-O-(6′-O-α′-L-arabinoryranosyl)-β-D-glucopyranoside, found in the intracellular spaces, both of green and yellow strains of cell cultures, was defined as potential rozavin by very precise methods.
Biotransformation was used for increasing of biologically active substances production in callus culture in Rhodiola rosea. The effect of different precursors of biologically active substances on the biomass and the metabolite production was studied in Rhodiola rosea compact callus aggregates in liquid medium [202, 203]. Cinnamyl alcohol concentrations up to 0.1 mM in media did not bring to a significant deviation from the control; 2 to 5 mM changed slightly callus color from dark to light green. In these cultures rosin content was elevated to 1.25 % dry weight while rosavin was 0.083% dry weight. Cinnamyl alcohol induced synthesis of four new products, too. Tyrosol from 0.05 mM and 2 mM did not influence callus growth while concentrations of 3 mM up to 9 mM caused decrease in biomass production. Two mM of tyrosol were the optimal levels for salidroside production reaching 2.72 % dry weight. Addition of glucose had no positive effect on salidroside accumulation but doubled the rosin production.
Callus tissues cultivated on solid media could produce active substances characteristic for the species [204] Rh. rosea Addition of yeast extract in the media doubled salidroside content (from 0.8 % to 1.4) and was twice as high as in five-year-old roots of the intact plants. In the later experiments [205] Rh. rosea callus induced from axillary buds or from seedling hypocotyls transformed exogenous cinnamyl alcohol into rosin. However, the biotransformation process was more efficient in the hypocotyl callus where the application of 2.5 mM cinnamyl alcohol resulted in the increase of rosin content up to 1056.183 mg/100 g on solid medium and 776.330 mg/100 g in liquid medium. Callus tissue obtained from axillary buds and treated in the same way produced rosavin in a higher concentration of 92.801 mg/100 g and reached 20% of the amount produced by roots [206].
Krajewska-Patan et al. and György et al. [205, 202, 203] obtained and maintained callus from Rh. rosea in liquid medium adding different precursors of the biologically active substances to increase the synthesis of the substances from the main biologically active complex.
The same Bulgarian group successfully established callus cultures, too [207]. Induction of callogenesis was achieved from leaf explants, isolated from in vitro propagated plants, on MS media enriched with BAP in concentration from 0.5 mg/l to 2.0 mg/l; 2-iP—0.3 and 3.0 mg/l; 2,4-D—from 0.1 to 2.0 mg/l; IAA—0.2, 0.3 and 1.0 mg/l; NAA—0.5, 1.0, 1.5 mg/l; glutamine—150 mg/l and casein hydrolysate 1000 mg/l. The highest response of 62.85 % and 73.17 % formation of callus was observed on two media, both containing 1 mg/l BAP and either 1 mg/l or 0.5 mg/l 2,4-D (Figure 4 a, b, c, d, e, f, g, h). The authors observed (unpublished data) that when calli were cultured on media with the same phytoregulators as mentioned above but with higher content of sucrose (3 % instead of 2 %) the induction of of callogenesis was several folds lower and variations in callus structure and color were noted. Sucrose concentration influenced synthesis of biologically active substances. Phytochemical analysis revealed that at 2 % sucrose in the medium salidroside and rozavins were not detected in the calli (unpublished data)
Various callus cultures induced on MS basal medium enriched with: (a) – BAP (1 mg/l), 2,4-D (1 mg/l) and 3% sucrose; (b) - BAP (1 mg/l), 2,4-D (1 mg/l) and 2% sucrose; (c) – BAP (1 mg/l), 2,4-D (0.5 mg/l) and 3% sucrose; (d) – BAP (1 mg/l), 2,4-D (0.5 mg/l) and 2% sucrose; (e) – BAP (1 mg/l), 2,4-D – 1 mg/l, Casein hydrolysate 1000 mg/l and 3 % sucrose; (f) – BAP (1 mg/l), 2,4-D – 1 mg/l, Casein hydrolysate 1000 mg/l and 2 % sucrose (g) – BAP (1 mg/l), NAA (0.5 mg/l), Casein hydrolysate 1000 mg/l and 3% sucrose; (h) BAP (1 mg/l), NAA (0.5 mg/l), Casein hydrolysate 1000 mg/l and 3% sucrose;
Similar investigations were performed with other Rhodiola species. Rh. sachalinesis calli cultured with 5% sucrose produced high salidrosid content (0.41 % on the basis of dry wt) than normal root (0.17 %) [208]. A compact callus aggregate strain and culturing system for high yield salidroside production was established in Rhodiola sachalinensis [209].
Organogenic callus was obtained from leaves with efficiency of 88.33 % [210]. Among the yellow, green, and red colored calli, only green callus formed buds though with poor efficiency. Despite this, regenerated plantlets were rooted on half strength MS medium. Experiments with Rhodiola sachalinesis proved that cryopreservation of calli is possible followed by successful recovery of fresh and green tissues for 6 weeks. Isolation of protoplasts was also reported for this species [211].
in vitro cultures were obtained from Rh. crenulata, Rh. yunnanensis, Rh. fastigata [212, 213] and Rh. quadrifida [214] proving the role and interactions of the explant type, genotype and phytohormones for the efficiency of in vitro response and regeneration was also function of the genotype and the phytohormones. The authors underlined the role of 2,4-D and BA for production of biologically active substances. Similar observations about the role of the explant, the temperature of cultivation and the pretreatment duration on salidroside synthesis in Rhodiola kirilowii callus were made by others [215].
Genetic transformation opens new perspectives for production of biologically active compounds. Hairy roots induced by Agrobacterium rhizogenes grow faster accumulating greater biological material. Genetic transformation of Rhodiola sachalinensis was performed with Agrobacterium rhizogenes [216, 217]. The authors studied conditions for high salidroside production (the major compounds from the roots of Rhodiola sachalinensis) when precursors (tyrosol, tyrosine, and phenylalanine) and elicitors (Aspergillus niger, Coriolus versicolor, and Ganoderma lucidum) were added into the medium. For high salidroside production, the optimal light intensity, pH value and nitrogen levels were determined, too. The optimal concentration for the elicitor was 0.05 mg/l while the optimal concentration of the precursor was 1 mmol/l. The 1000 lx scatter light, pH 4.5 - 4.8, and nitrogen (NH4+: NO3- =1:1) concentration of 80 mmol/l were the optimal condition for salidrosid production. Authors conclude that hairy roots can be used as alternative material for the production of secondary metabolites of pharmaceutical value in Rhodiola.
Examples, given here, though covering a small part of the enormous and tedious work on medicinal plants, and more particularly on representatives of the genera of Gentiana, Leucojum and Rhodiola, which are protected in Bulgaria, could give impression on the potential of different spheres of plant biotechnology (Table 1). The most promising ones being in vitro clonal propagation of endangered species to create in vitro and ex situ collections, and for obtaining of raw material and valuable compounds (Figure 5).
Relative share of the achievements in different spheres of biotechnology in the three genera: Gentiana, Rhodiola, Leucojum.
Plant Species | \n\t\t\tCalluso- genesis | \n\t\t\tSomatic embryo- genesis | \n\t\t\tOrgano- genesis | \n\t\t\tRegene- ration | \n\t\t\t\n\t\t\t\tMicropropagation \n\t\t\t | \n\t\t\tAdapta- tion | \n\t\t\tBiotrans- forma- tion | \n\t\t\tGenetic transfor- mation | \n\t\t
\n\t\t\t\tG. lutea\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t
\n\t\t\t\tG. kurroo\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t
\n\t\t\t\tG. cruciata\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t
\n\t\t\t\tG. pannonica\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tG. punctata\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t
\n\t\t\t\tG. straminea Maxim. | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tG. crassicaulis,\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
G. dinarica Beck, | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t |
\n\t\t\t\tG. corymbifera,\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tG. pneumonanthe\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t |
\n\t\t\t\tG. purpurea,\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t
\n\t\t\t\tG. davidii var. Formosana\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tG. scabra\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tG. acaulis\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t
\n\t\t\t\tG. tibetica\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tG. dahuria\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t
\n\t\t\t\tG. triflora\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tG. ligularia\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tG. cerina\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t |
\n\t\t\t\tG. asclepiadea \n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tRh. rosea\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t |
\n\t\t\t\tRh. crenulata\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tRh. kirilowii\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tRh. quadrifida\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tRh. sachalinensis\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t
\n\t\t\t\tRh. yunnanensis\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tRh. iremelica\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tRh. fastigata\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tRhodiola coccinea\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t | \n\t\t\t | \n\t\t\t | \n\t\t |
\n\t\t\t\tLeucojum aestivum\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tYes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t\t\n\t\t\t\tyes\n\t\t\t | \n\t\t
Examples of biotechnological achievements in Gentiana, Rhodiola and Leucojum species.
Presented data and results in this chapter aimed at enlightening the potential of plant biotechnologies in protection of valuable plant species, including the medicinal ones, which have become rare or are close to extinction as a result of the intensive industrialization, urban economy and climatic changes. One of the measures for overcoming this global problem could be the cultivation of valuable medicinal plants in experimental conditions. For this purpose along with the traditional methods for cultivation fields and nurseries, “green” biotechnologies can be used. Many scientists have realized that plant biotechnology is an important tool for multiplication and conservation of the endangered and rare populations of medicinal plants. Using environmental friendly in vitro technologies a great number of identical plants, can be propagated, regenerated and transferred back in nature thus restoring and expanding wild habitats. From another hand, the areas of the medicinal plants will be less subjected to vulnerable exploitation if the valuable raw material could be obtained by alternative means. In this sense by micropropagation of plants, enormous amounts of biomass can be produced continuously and/or for short period of time. In addition, production of biologically active substances in laboratory conditions contributes to less utilization of the natural resources and thus protecting the species. The fact that in vitro cultures, cells, tissues, organs and plantlets can produce metabolites, specific for the intact donor plant, is of tremendous importance for production of desired compounds. Development of more sophisticated instrumentation and original approaches allowing biotransformation and metabolic engineering is a revolutionary step for high technological production of valuable substances and biologically active compounds demanded from the food, nutraceutical, pharmaceutical and cosmetic industries.
MS – Murashige and Skoog medium, 1962; BAP – N6-benzylaminopurine; IAA – Indolyl-3-acetic acid; 2-iP – 6-(y,y-dimethylallyl amino) purine; 2,4-D – 2,4- dichlorophenoxyacetic acid; NAA - α- naphthyl acetic acid; TDZ – Thidiazuron; Kin – Kinetin; GA3 – Gibberellic acid; IBA – Indole 3-butyric acid
Since 1962 when the first Clark’s biosensor was introduced [1], enzymatic electrochemical devices have attracted increasing attention, recently being regarded as a powerful tool for the development of emerging wearable bioelectronics [2]. Integrating enzymes with electrochemical transduction units is one of the most popular and well-built bioelectronic systems due to outstanding selectivity and natural behaviors of enzymes [2, 3, 4]. Employing enzymes, as a catalytic system, in order to substitute nonselective metal catalysts, is interesting. Because of inherent behaviors of enzymes, enzyme-based bioelectronics offers favorable operations under mild physiological conditions of pH and temperature, unlike nonenzymatic approaches [5, 6]. In addition, enzymes will usually catalyze only one particular reaction. Therefore, such enzyme specificity enables bioelectronics to operate selectively even in complex solutions, including biofluids. Recently, there is an increasing interest in transforming traditional enzymatic bioelectronics into modern wearable platforms. Wearable enzyme electronics expands appealing spectra of a variety of applicable fields, ranging from personalized healthcare, fitness, to the environment. These applications comprise of noninvasive diagnosis of biomarkers in biofluids, such as sweat, and the monitoring of the surrounding of the wearer. Besides, electron collectors can be functionalized with enzymes to develop BFCs for energy and self-powered applications. These biodevices employ enzymes to obtain electrocatalytic oxidations of biofuels, such as glucose and lactate. This aims to achieve next-generation energy autonomy for the whole wearable system. In addition to energy-harvesting purposes, BFCs can also act as self-powered electrochemical sensors. Three main applications of enzyme-based electrodes, including biosensors, biofuel cells (BFCs), and self-powered sensors, along with their relevant aspects, will be discussed (Figure 1). An enzymatic biosensor employs an enzyme, immobilized on an electrochemical transducer, to recognize and react with the target, generating a readable electrical signal (Figure 1B). A BFC energy harvester can convert chemical energy into electricity and power wearable devices (Figure 1C) [7]. A BFC can also be designed to act as a self-powered sensor by displaying power signals proportional to the target concentration (Figure 1D) [8, 9].
\n(A) Skin-worn enzyme-based electrochemical devices. The soft electrode platform is functionalized with enzymes, allowing various applications, including (B) biosensors, (C) energy-harvesting biofuel cells, and (D) self-powered biosensors.
Skin-worn enzyme-based electrochemical devices are among the most significant wearables because the skin offers the largest organ interface and unique opportunities to be accessed noninvasively [10, 11, 12, 13]. The large epidermal area also provides sweat, which contains a variety of biomarker-rich information, such as levels of glucose, lactate, hormone, urea, pH, and electrolytes. Advantageously, skin-worn electrochemical devices can be attached directly close to the location of sweat generation, enabling the fast access for monitoring or energy harvesting before the unwanted biodegradation. In addition to physical parameters obtained from existing skin-worn biodevices (such as temperature and heartbeat), chemical data is also crucial to step further to understand comprehensive insights of individual [14]. The history of sweat content analysis began many decades ago with the development of cystic fibrosis diagnosis [15]. Establishing new “lab-on-skin” electrochemical devices enables noninvasive detection of such biometrics, essential for health monitoring and early disease diagnosis. In addition, such wearable electrochemical tools are also helpful for drug testing and chemical threat screening, such as in sports [12] and in the surrounding environment [16]. Importantly, for emerging energy technologies, sweat also contains relevant biofuels, such as glucose and lactate; this is useful to BFCs as energy-harvesting and self-powered devices, which exemplify new exciting wearable autonomous bioelectronic systems.
\nAlthough researchers are battling to create new enzymatic bioelectronics, there is a continuing need for further development. Revolutionizing traditional electrodes toward wearable bioelectronics needs careful engineering to address several key challenges associated with electrochemistry, the integration of biocatalysts, mechanical stability, environment effects (e.g., O2 fluctuations), and sweat extraction. Therefore, the bulk of this chapter will focus on examples of progress in skin-worn enzymatic electrochemical devices. Key working principles and opportunities of biosensors and BFCs will be described. In addition, perspectives emphasizing on main challenges will be discussed. The outlooks of emerging wearable electrochemical technologies will also be concluded.
\nWearable enzymatic electrochemical biosensors utilize enzymes, which are functionalized in spatial contact with electrochemical transduction units. In principle, biosensors consist of electrodes and enzyme receptors, allowing the specific binding capabilities and catalytic activity to target analytes. Interfacing enzymes with electrodes will be discussed further in Section 3.3. It should be remarked that the key consideration to fabricate a successful biosensor for nonspecialist wearers is choosing highly specific biocatalysts. Enzymatic biosensors can also function continuously because enzymes are not consumed in reactions, offering an advantage for wearable sensors.
\nEnzymatic biosensors are based on numerous mechanisms. The popular mechanism relies on the conversion of the analyte as an enzymatic substrate into a product, enabling the detection by using electrochemical transducer. Another way is to monitor the analyte (e.g., a toxic compound) that acts as an enzyme inhibitor. In addition, the enzyme can be used as a labeling transducer for bioaffinity recognition. Besides, a reverse approach can be designed to detect the enzyme level. In this case, the enzyme acts as an analyte, while the substrate is immobilized on the electrode surface. When the enzyme reaches the electrode sensor, it will generate the signal, corresponding to the concentration level of the enzyme target.
\nIn recent decades, enzymatic biosensors have been proven to be modern wearables to monitor numerous analytes, such as glucose, lactate, alcohol, and organophosphate nerve agents. Among several enzymes, oxidoreductase and hydrolase, such as glucose oxidase (GOx), lactate oxidase (LOx), alcohol oxidase (AOx), and organophosphorus hydrolase, are predominant for wearable biosensing applications. A temporary tattoo with the integration of transdermal enzymatic glucose biosensor has been introduced since glucose is a key biomarker for diabetes mellitus, which still affects hundreds of millions of patients globally (Figure 2A) [17]. The iontophoretic ISF extraction system was coupled with the amperometric detection to extract the sample containing glucose. The glucose biosensor, located near the negative iontophoretic electrode, relied on GOx immobilization on the Prussian blue (PB)-carbon electrode; this PB facilitates the electroreduction of H2O2 product, generated by the GOx reaction. The amperometric reduction of H2O2 could be detected at a potential of −0.1 V versus Ag/AgCl. The iontophoresis strategy will be discussed in Section 3.5. Additionally, the tattoo-based alcohol sensor was also invented (Figure 2B). The AOx-/PB-based sensor was designed to be close to the positive iontophoretic electrode to determine ethanol in sweat induced by transdermal delivery of the pilocarpine drug [18]. Moreover, recent efforts have been made to combine these two concepts, including glucose and alcohol sensors, on a single tattoo [19]. This holds a possibility for multianalyte sweat analysis.
\nSkin-worn enzyme-based electrochemical biosensors. (A) Transdermal tattoo-based glucose sensors, coupled with reversed iontophoresis [17]. Adapted with permission from ref [17]. Copyright 2015 American Chemical Society. (B) Tattoo-based alcohol biosensors, coupled with pilocarpine iontophoresis and wireless electronics [18]. Adapted with permission from ref [18]. Copyright 2016 American Chemical Society. (C) Biosensors integrated with a microfluidic patch for sweat collection and analysis [20]. Adapted with permission from ref [20]. Copyright 2017 American Chemical Society. (D) Microneedle-based β-lactam sensors [22]. Adapted with permission from ref [22]. Copyright 2019 American Chemical Society. (E) Integrated glucose/lactate enzymatic biosensors with electrolyte and temperature sensors. (F) Integrated sweat monitoring biosensing and transdermal drug delivery system.
Skin-worn microfluidic devices can enable the continuous flow of renewed sweat over operational periods. This addresses the challenge of mixing and carry-over between new and old sweat. Figure 2C shows an example of sweat collection microfluidic devices, coupled with glucose and lactate biosensors [20]. This offers wearable effective continuous sweat sampling and flow electroanalysis.
\nFurthermore, minimally invasive microneedles for continuous glucose monitoring have been demonstrated. For example, a GOx/tetrathiafulvalene microneedlebased amperometric sensor (~1.2 mm needle height) could be used for in vivo studies [21]. The data were also validated with the finger-prick technique, indicating a promising alternative for on-skin analysis. In addition, a minimally-invasive microneedle-based potentiometric sensor for tracking β-lactam antibiotic concentrations in vivo and real time was demonstrated Figure 2C [22]. This example represents a possibility to tailor individual therapy with the optimal efficacy.
\nMoreover, reading several parameters can complete a clear picture of individual health. A fully integrated sensor array for sweat analysis was demonstrated (Figure 2E) [23]. These integrated sensors can monitor information of glucose, lactate, electrolytes (e.g., sodium and potassium ions), and temperature. The temperature sensor is also helpful to standardize the biosensing amperometric response. Furthermore, in order to apply the biosensor glucose device for health management, a transdermal closed-loop drug delivery integrated with a sweat-based glucose electrochemical sensor was demonstrated (Figure 2F) [24]. The sense-treat concept aimed to give feedback of transdermal administration of type 2 diabetes drugs in response to the glucose level. This idea represents a possible opportunity to overcome insulin overtreatment, helping patients to maintain their homeostasis.
\nBFCs are energy-conversion devices that utilize biocatalysts to convert chemical energy into electricity. For wearable electronics, the need to anatomically power sources has attracted many research groups to develop a BFC, as a “green” energy-harvesting alternative, in order to extract energy from metabolites present in biofluids, such as perspiration. Since glucose, lactate, and oxygen are present in physiological fluids, in general, a majority of wearable enzymatic BFCs rely on (1) the generation of electrons from glucose or lactate biofuels and (2) the electron reduction by oxidants (such as oxygen). Figure 1C shows a typical example of a glucose/O2 BFC. In principle, a glucose BFC uses GOx, functionalized on the bioanode, to catalyze the glucose oxidation reaction to generate electrons. After this oxidation process, these harvested electrons are driven through an external circuit to the biocathode compartment where such electrons are accepted by oxidant molecule (commonly O2) and, eventually, generate complete electrical work. In addition to Pt-based catalysts, multicopper oxidases such as laccase, bilirubin oxidase, and polyphenol oxidase are commonly used for electrocatalyzing oxygen-reduction reaction (ORR) in the BFC cathode [25].
\nEnzymatic BFCs represent an interesting alternative due to their unique advantages, such as outstanding selectivity and behaviors of enzymes. Unlike most traditional inorganic catalyst-based fuel cells, which require harsh conditions (such as acidic conditions or high temperatures ranging from 45°C to more than 100°C), the enzyme-based BFC can operate under mild conditions (20–40°C at neutral pH). Moreover, non-specific catalyst-based fuel cells require to separate anode and cathode chambers by a thin membrane. Unfortunately, this common use of separation membrane between the anode and the cathode compartments will be unsatisfactory for skin-worn miniaturized devices. Thanks to the nature of enzymes, utilizing high specificity of enzymatic catalysis can obviate this membrane requirement, facilitating the fabrication and applications [26]. In addition, enzyme-based BFCs can operate selectively in complex biofluids.
\nInterestingly, BFCs also offer opportunities to design self-powered biosensors (Figure 1D). For example, the power is proportional to the concentration of the fuel (also acting as analyte); self-powered output itself can determine the level of the target. This offers opportunities to eliminate external energy sources for powering potentiostat and signaling systems [9].
\nAn initial concept integrating enzymatic BFCs with skin-worn technologies represented an exciting way to scavenge bioenergy available in human perspiration (Figure 3A). This demonstrated the first epidermal tattoo-based BFC that converted sweat lactate biofuel and oxygen into electricity [27]. The lactate oxidation by LOx electrocatalyzation was mediated by tetrathiafulvalene on the carbon nanotube (CNT)-based anode, while electroreduction on the oxygen-reduction cathode relies on Pt black catalyst. This system facilitates mediated oxidation of lactate at −0.1 V with a peak potential of 0.14 V (versus Ag/AgCl). This low anodic onset potential indicates the efficient electron-donor-acceptor TTF/CNT. The successful on-body test displayed a power up to 70 μW cm−2. This idea was also established on fabrics and could power a light-emitting diode with an integrated DC-DC converter [28].
\nSkin-worn BFCs and self-powered sensors. (A) Epidermal tattoo-based lactate BFCs. (B) Stretchable glucose BFCs [29]. Adapted with permission from ref [29]. Copyright 2016 American Chemical Society. (C) Stretchable textile-based BFCs acting as self-powered biosensors [30]. Adapted with permission from ref [30]. Copyright 2016 The Royal Society of Chemistry. (D) Photoelectric BFCs. (E) Textile-based BFC-supercapacitor hybrid devices [31]. Adapted with permission from ref [31]. Copyright 2018 The Royal Society of Chemistry. (F) Built-in BFCs with transdermal iontophoresis patches.
Mechanical stability has been the focus in the development of the next-generation of skin-worn BFCs due to the multiplex mechanical movements experienced in vivo. In order to minimize cracking of the device and maintain good electrochemical performance, screen-printable stretchable inks and judicious stretchable design have been engineered (Figure 3B) [29]. Combining additional degrees of stretchability with intrinsic mechanical resiliency of soft CNT/polyurethane (PU) composite offers the desirable stretchable platform. The BFC was then functionalized on the soft electrodes, allowing good mechanical stability. This holds promise applications for on-body bioenergy fields wherein resilience toward mechanical distortions is compulsory.
\nIn addition to energy-conversion applications, BFCs can be applied further as another significant tool for wearable bioelectronics. Enzymatic BFC can serve as self-sustainable biosensors (without an extra powering device). In order to expand the spectrum of BFC applications for on-skin electroanalytical chemistry, the pioneering stretchable textile-based BFCs that can act as self-powered was demonstrated (Figure 3C) [30]. These biodevices can deliver two key functions: (1) harvesting electrical power from sweat glucose and lactate and (2) displaying signals of such metabolites. Extracted bioenergy from the wearer’s sweat can directly indicate the metabolite levels. Sock-based biodevices were successfully demonstrated on human subjects, representing a promising concept for modern wearable self-powered biosensors.
\nMaximizing the loading amount of active enzyme, mediator, and conductive materials can improve the power performance of BFCs. The high amount of such active materials can be packed by a compress. However, this strategy will affect mechanical softness. Therefore, further engineering was to fabricate island-bridge assemblies merging the high enzyme loading packed islands with stretchable serpentine bridges [34]. This combination offered a soft bioelectronic skin for harvesting a good power density of 1.2 mW cm−2. This energy was sufficient to power a Bluetooth Low Energy (BLE) radio integrated with a DC-DC converter.
\nRecently, additional efforts have been made to scavenge, improve, and store energy by hybridizing textile-based energy conversion with energy storage devices (BFCs and supercapacitors, respectively) (Figure 3E) [31]. The on-body demonstration showed that after perspiring, the supercapacitor could be charged by the BFC energy and reach a stable 0.4 V output.
\nFurthermore, a photoelectric BFC was developed to convert external light andchemical energy from wearer’s perspiration into electrical energy (Figure 3D) [32]. The anode relied on a LOx/Meldola’s blue/buckypaper electrode, while the photocathode relied on an organic polyterthiophene semiconductor, which drove a reduction reaction under illumination (wavelengths of 350 nm to over 600 nm). This system presented an attractive example of on-skin autonomous power sources and sensors.
\nAdditional efforts have been made to explore new biomedical applications of BFCs. Figure 3F shows an integrated fructose/O2 BFC patch that was conjugated with transdermal iontophoresis [33]. The current generated by the BFC was used to drive an osmotic flow from the anode to the cathode, resulting in the net ionic movement of small-molecule drug into the skin. The level of transdermal current to control the drug administration could be adjusted by connecting a thin poly(3,4-ethylenedioxythiophene)/PU resistor of a programmable resistance value.
\nYoung’s modulus of the human skin is in a range of 10–500 kPa [35, 36], while the moduli of common electronic materials, such as silicon and gold, are much higher (high GPa), indicating significant mechanical mismatch when integrating with the skin. Therefore, functionalities of non-stretchable electrodes will deteriorate after multiplex deformations commonly experienced by daily life activities. Furthermore, such rigidity and bulkiness of traditional devices also restrict the wearability and comfortability [14]. Non-compliant electrochemical devices will limit continuous long-term functions due to cracking and increasing of material resistance. This increasing of resistivity, which opposes the current flow in bioelectronics, causes poor electron communication at the enzyme-electrode interface.
\nThis major challenge of skin-integrated electronics can be addressed by exploring stretchable materials which display mechanical properties in a similar range of skin’s modulus. One approach is using polymers due to their low mechanical toughness. For example, conducting materials with high moduli can be blended with soft polydimethylsiloxane or Ecoflex materials (Young’s moduli of 0.4–3.5 MPa and 125 kPa, respectively) in order to tune the mechanical properties while keeping good electrochemical functions [37]. CNT-based materials, which are powerful for electrochemical devices [38], are used to combine with soft elastomers, such as PU and styrene-butadiene-styrene (SBS) [29, 39]. PU and SBS composites have moduli of ~700–800 kPa. As shown in Figure 3C, CNT filler (with the high-aspect ratio ∼1300) was combined with PU [30], achieving stretchable conductive electrode materials. The percolation of dispersed CNTs can facilitate the electric flow in stretchable bioelectronics. Combining the intrinsic stretchability of this engineered inks with the structural stretchability of the serpentine design allows the device to tolerate strains as high as 500% with a small effect on its electrochemical performance [29]. This concept can be expanded by adding new functionalities into electrodes. For example, platinum-decorated graphite was mixed with PU to obtain stretchable electrocatalytic materials, allowing the fabrication of stretchable electrodes for glucose biosensors [40].
\nGrowing demand of wearable technologies has stimulated the need of the development of viable energy sources. The lack of anatomically power sources becomes a key bottleneck for the progress in wearable bioelectronics. Skin-worn bioelectronics mandates the compliant and efficient energy sources to supply multitasks, including sensing and data communication. In addition to developing low-power-consuming electronic microelectronics [9, 41], there is an increasing interest in advancing bioenergy-harvesting devices. Enzymatic BFCs are attractive self-sustainable energy devices to meet this growing energy demand. For example, 0.3-V complementary metal-oxide-semiconductor (CMOS) wireless glucose or lactate biosensing systems, which consumed power of ~1.2 μW, could be powered by BFCs [9]. Nevertheless, several applications of enzymatic BFCs still have some challenges, such as low-power output. The major challenge in enzymatic BFC is faced by the electrical “wiring” of enzymes with electrodes. The difficulty of electrical wiring, referring to electron transfer, and their possible solutions will be detailed in Section 3.3.
\nCompared with traditional fuel cells, enzymatic BFCs are challenging due to their multicomponent including redox potentials of enzyme, cofactor, and mediator. This results in the typical unwanted deviation of open-circuit voltages (OCV) from their theoretical maximum values, referring to “cell voltage losses.” The redox potential for electrocatalytic oxidation at the bioanode required to be higher than that of the biocathode for reduction reaction in order to deliver a sufficient electromotive force for electron transfer between enzyme active site and mediator. The voltage difference between the formal redox potentials (E°′) of redox enzyme cofactors in the active sites, in the anode and cathode, will govern the maximum cell voltage. Parameters, including redox potential of mediator and cofactor redox potential in the enzyme, can influence the resulting potential output of BFCs. Therefore, the mediator should be carefully chosen. For example, ferrocene derivatives coimmobilized with GOx at a graphite electrode can be used for glucose sensors [42]. Nevertheless, ferrocene derivatives display high redox potentials (0.1–0.4 V versus SCE); these will cause cell voltage losses in the GOx-based BFC if they are used as anode mediators. It should be noted that the difference between the redox potentials of the enzymes wired at the anode and the cathode determines the cell voltage. An example of a successful anode mediator used in skin-worn BFCs is 1,4-naphthoquinone [30]. This quinone compound is also almost insoluble in cold water, preventing leaching during on-body operations. One challenge of using GOx on the anode is the O2 competition with a mediator, decreasing the oxidation current on the bioanode. Moreover, O2 competitive reaction on the anode can produce H2O2. This by-product can inhibit GOx activity and decrease the overall BFC performance. Therefore, catalase should be cofunctionalized to the bioanode to diminish the undesirable H2O2 [43].
\nA single-enzyme BFC can usually convert only a partial portion of biochemical energy, resulting in low current output. For instance, wearable BFCs, such as for harvesting energy from lactate sweat, commonly employ a single enzyme-based bioanode, catalyzing the oxidation of lactate to pyruvate, which only harvests two electrons. In other words, they utilize only a portion of the biofuel energy and leave most of the energy in the oxidized product. Therefore, it is interesting to harvest the total of 12 electrons in order to maximize the energy-conversion efficiency. A potential solution is to design an enzyme cascade system for complete oxidation of lactate fuel. For example, the bioinspired multienzyme catalytic cascade could complete the metabolic cycle, successfully enhancing net BFC power [44].
\nFurthermore, in order to optimize the current output, diffusion and enzyme loading should be enhanced. The engineering of specific enzyme activity and three-dimensional structure of enzymatic electrodes should be explored.
\nThe selection of enzymes is a primary subject which should be discussed. Enzymes must be selected by considering their particular reactions to target analytes or biofuels for electroanalytical monitoring and energy harvesting, respectively. One of the most predominant enzymes used to develop wearable bioelectronics is GOx from Aspergillus niger. It represents an example of commercially available biocatalyst that has good stability, substrate specificity, and electron turnover rate [3, 4, 45]. It is a powerful biorecognition element for glucose biosensors, the most widely interesting devices for diabetes health management. As shown in Figure 4 (A–C), the enzyme is immobilized on the electrode, establishing a biosensor. GOx contains two 80 kDa subunits. Each holds a tightly bound flavin adenine dinucleotide (FAD) cofactor, the important redox center which has a redox potential −0.32 V (vs Ag/AgCl) at pH 7. This redox center is crucial to transfer electrons and specifically oxidize β-D-glucose to gluconolactone. However, this FAD is shielded by the protein and a glycan structure, hindering electron exchange at the enzyme-electrode interface. Inevitably, this requires research efforts to address this roadblock [46, 47]. FAD plays an important role as a common cofactor for glucose oxidation biocatalysis. The redox process for FAD/FADH2, involving two electrons, is shown in Figure 4D, where the R group represents adenosine diphosphate and ribitol connected with the flavin. However, it is O2-dependent; accordingly, O2 fluctuations can vary the performance of this type of oxidase-based bioelectronics. Although alternative O2-independent electrodes utilized NAD-dependent electrodes can be used, they require a diffusional cofactor, not simple for wearable applications. Hence, FAD-dependent dehydrogenases are becoming interesting choices since they are O2-independent and do not depend on diffusional mediators [48, 49].
\nPrinciples of interfacing the enzyme, such as glucose oxidase (GOx), with the electrode. Different generations of strategies (A–C: first, second, and third generations) are illustrated. (D) Reactions involving the glucose oxidase biocatalyst.
The first generation of biosensors relies on quantifying O2 generation or H2O2 depletion (Figure 4A). This leads to key drawbacks, such as low dynamic range, dependency to oxygen fluctuations, and interfering effects. For instance, for glucose amperometric sensors, the detection of H2O2 at common first-generation electrodes needs the high applied detection potential where interfering compounds existing in sweat, e.g., ascorbic acid, uric acid, and some drugs, are also electroactive. Lowering the applied potential for the detection is a strategy to minimize such electroactive interferences. One approach is to incorporate electrocatalysts in wearable electrodes, such as PB or Pt [17, 40]. This offers low-potential detection of H2O2 to mitigate interference effects.
\nFurthermore, researchers have developed two strategies to wire enzymes to the electrode interface (Figure 4B and C). These include (1) mediated electron transfer (MET) and (2) direct electron transfer (this may refer to mediatorless electron transfer between the enzyme and the electrode). Such new tactics are not only useful for enzymatic biosensors but also for enzymatic BFCs which also involve bioelectrocatalysis.
\nFirst, the MET strategy utilizes a redox mediator, acting as an electron-shuttle assistant between the enzymatic active center and the electrode. The substrate level, such as glucose, can then be monitored by the redox process of the mediator. This results in the independence of oxygen and mitigating the interfering signals due to the operation at low potentials. The first consideration in electrically wiring the enzyme with the electrode is the choice of the mediator that should be close to the redox potential of the active center of the enzyme to facilitate efficient electron communication between the enzyme and the conductive electrode surface. In particular, for enzymatic BFCs, the selection of mediators is crucial to positively control the cell voltage and enhance heterogeneous electron transfer to the order of a homogeneous transfer [50]. However, challenges of using mediators, particularly for BFCs, are their stability and deviated cell voltage. In addition, biocompatibility is highly vital for skin-worn applications. In spite of the assistance of electron shuttle by redox mediators, major concerns are their biocompatibility. One possible solution is employing nanomaterials or highly biocompatible catalysts. For example, mushroom/plant extracts could be used to obtain efficient “green” bioelectrocatalytic reactions for ethanol BFCs [51].
\nSecond, direct electron transfer is an ideal goal of electrical wiring. It can be achieved by employing nanomaterials which suggest the direct electron transfer between enzyme active site and electrode. This wiring strategy is based on the shortening of the electronic contact of the enzyme and electrode (a short distance of ~1.5 nm) where the redox center of the enzyme can be regenerated directly by the electrode [52]. Therefore, this strategy can maximize the performance of bioelectronics. The engineering needs to consider the position of the active site inside the protecting protein and the conformation of the protein in order to wire the conducting materials with the redox center. This still remains the most challenging topic.
\nSeveral variables also affect the response nature of enzyme bioelectronics. Consideration of the fundamental theory of their functions will help to improve their performances. A key well-known model of enzyme behaviors is Michaelis-Menten kinetics, \n
In addition, extra membranes can be a biocompatible barrier to address challenges from biofouling and interferents, especially when electrochemical operations are made in real matrices, samples, such as sweat. A perfluorinated sulfonated membrane (Nafion®) is an example membrane, which is also easy to drop-cast. This coating membrane can protect the enzymatic layer and also prevent anionic interferents, such as ascorbate [53].
\nShelf life and operational stabilities of enzymatic electrodes are among the most critical challenges. The enzyme and active materials, such as mediators, can also leach during operations. Extensive studies have been made to improve enzyme bioelectrodes, such as by crosslinking hydrogels in the presence of the enzyme [54, 55]. Such crosslinking can entrap the enzyme to be more stable; moreover, this way enhances the loading of the enzyme, while the three-dimensional structure can facilitate the transport of analytes or biofuels, improving bioelectrode functions. Nevertheless, crosslinking enzyme or covalent binding of the enzyme can change the conformation of the enzyme and thus affect the activity [56]. Furthermore, one alternative to stabilize the enzyme electrode is the addition of stabilizers, such as polyelectrolytes, dextrans, glycerol, polyethyleneimine, and hydrophobic oils [57, 58, 59]. For instance, hydrophobic mineral oil or silicone grease can be used to minimize enzyme denaturation [58, 59]. The pasting liquid helps to lower protein mobility, maintain conformational rigidity of enzymes, and barrier to hydronium ions from acid environments. This strategy can stabilize many enzymes, such as GOx, LOx, AOx, horseradish peroxidase, amino acid oxidase, and polyphenol oxidase.
\nIncreasing enzyme loading can also improve the performance of biocatalytic devices. Employing high surface nanomaterials is useful to enhance the surface loading of the target catalyst. A graphene-based electrode is a good example platform to offer a high enzyme loading (1.1 nmol cm−2); in addition, it offers a fast heterogeneous electron transfer rate (ks) of 2.8 s−1 [60]. Moreover, CNTs, which have high conductivity and specific surface, represent an outstanding candidate nanomaterial for electrochemical wiring [38, 61]. The thin nanoscale structure can intimately incorporate with the active enzyme. Adsorption of GOx on CNTs provides the apparent ks, of 1.5 s−1 [62]. The ks of GOx at the hybrid biocomposite can be as high as 11.2 s− 1 [63]. Therefore, mediatorless bioelectrodes with excellent electron transfer could be demonstrated. Their high three-dimensional architecture also offers an enhanced loading of enzyme and/or redox mediator immobilizations. As a result, this can enlarge the current output from the biosensor or BFCs. Importantly, for BFCs, the maximized OCV and current density could be observed [43]. This BFC consists of a GOx/catalase/CNT bioanode and laccase/CNT biocathode without additional mediators. The CNT/enzyme matrix was compressed together under high hydraulic pressure (10 kN). The resulting output in an air-saturated electrolyte (200 mM glucose in 0.2 M phosphate buffer solution, pH 7 at room temperature) after 3 days displayed a high maximum OCV of 1 V. Note that the GOx/catalase/CNT bioanode and the laccase/CNT biocathode showed OCV values of −0.35 and +0.6 V, respectively.
\nImportantly, biofluids from the skin (such as sweat and extracted interstitial fluids) contain a variety of chemicals that can inhibit enzyme activity, reflecting challenges in biosensing and BFC functions in real-time on-body applications. For instance, heavy metals can be found in sweat as the body expels chemicals or balances the charges. One example is Cu2+ which has been reported as an inhibitor to deactivate the enzyme. The Cu2+ in sweat can be in a range of 1.6–16 μM [11]. 0.1 μM Cu2+ could decrease the OCV value of the glucose BFC [64]. However, this enzyme-inhibitor electrochemical behavior is analytically attractive toward the development of self-powered biosensors, such as for direct heavy metal screening or indirect cysteine monitoring. For example, cysteine prefers to bind with Cu2+ via the Cu-S bond; this superior conjugation between cysteine and Cu2+ removes metal ions from the bioanode, consequently turning on the OCV.
\nSince the O2 level in biofluids may vary, first-generation biosensors, employing O2-dependent mechanism, are subject to inaccuracy. This issue can be addressed by using fluorocarbon pasting liquids to supply internal O2 [65]. Using redox mediator as a second-generation sensor is another way to eliminate this error. Furthermore, FAD-dependent glucose dehydrogenase is an option to address O2-dependent problems due to its O2-insensitive nature, compared with GOx [49]. In addition, because of the high rate of homogeneous electron transfer rate between GOx and oxygen, GOx prefers to transfer electrons to oxygen rather than to the electrode, causing undesirable O2 competition effect [66]. Moreover, for BFCs and self-powered sensors, the commonly used ORR cathode may cause the error under anaerobic conditions. The use of Ag2O/Ag redox cathode, which does not depend on ORR, can be used to operate BFCs, mitigating the possible O2 errors [30, 67]. Note that the reduction potential of Ag2O/Ag (0.342 V vs. SHE) is close to that of O2/OH− (0.401 V vs. SHE) at pH 7. Moreover, using O2-rich cathode is another possible option to mitigate O2-deficit effects [68].
\nEach person has 2.03 million sweat glands; sweat gland densities vary broadly across the skin surface and subjects, ranging from 16 to 530 glands cm−2 [11, 13, 69]. Normally, during exercise, sweat can be secreted around 20 nL gland−1 min−1 [11]. For example, the forehead or arm can generate sweat around 3 μL cm−2 or even lower. The fluctuation of sweat rate is also related to numerous factors, such as activity intensity and hydration level. Therefore, the limited volume of sweat causes a challenge in sweat analysis and operations. This leads to the development of miniaturized skin-worn electrochemical devices that can be practical in such small dead volume. For instance, the textile-based energy-harvesting BFC requires sweat volume per area of 40 μL cm−2 to deliver steady outputs [31]. Designing a capillary chamber is a possible route for low-volume electroanalytical systems [70].
\nIn addition to a passive way to collect sweat, one strategy is an active electrical-based approach, called “iontophoresis” [71, 72]. This active strategy offers on-demand sweat generation as the device can be placed to a local skin target. There are two main approaches to extract sweat: (1) iontophoresis with pilocarpine drug and (2) reversed iontophoresis without the drug. These are attractive routes for continuous sweat analysis.
\nFirst, pilocarpine iontophoresis can be used to stimulate the sweat. In principle, a small electrical current is applied to enable the pilocarpine administration across the epidermis as illustrated in Figure 5A. For example, the tattoo-based enzymatic alcohol sensor consists of a pair of electrodes located in contact with the skin surface. Small constant current (0.2 mA cm−2) was applied through the cryogel material containing pilocarpine at the anode (positive) iontophoretic side [18]. The applied electrical force will push the pilocarpine drug, which possesses a large positive charge, to eventually enter into the skin. Such transdermal drug delivery of pilocarpine can induce the local sweat, sufficient for the subsequent electrochemical detection. In addition, interstitial fluid (ISF) located under the skin can be extracted. Without this iontophoretic strategy, it is challenging to access ISF through wearable technology.
\nElectrical-based strategies using iontophoretic electrodes to extract biofluids, including (A) pilocarpine iontophoresis and (B) reversed iontophoresis.
Second, the reversed iontophoresis without pilocarpine drug can be used to extract relevant analytes, such as glucose [17]. For instance, as presented in Figure 5B, a current (0.2 mA cm−2) is applied to extract glucose in ISF. During the reverse iontophoresis process, glucose is pulled out at the negative iontophoretic compartment. Even though glucose holds no charge, the inherent permiselective characteristic of the skin prefers to transport positive species, allowing such glucose extraction. Applying electric field on mobile electric charge can cause Coulombic force, leading to a net convective flow in the skin from the anode to cathode direction. Accordingly, dissolved analytes (e.g., glucose) are also moved toward the cathode where they can be extracted and monitored. Therefore, the glucose amperometric working electrode, adjacent to the cathodic iontophoretic side, can detect the glucose level from the extracted sample.
\nThis chapter has reviewed some examples of new trends of skin-worn enzyme-based electrochemical systems, focusing on biosensors, BFC, and self-powered sensors. The existing systems provide significant advances toward the painless and point-of-care applications and personalized electrochemical biodevices, which was not possible without such new biodevices. However, researchers still face many challenges, such as electrochemistry, electrical wiring of enzymes, enzyme behaviors, the fabrication of stretchable electrodes, O2 fluctuations in biofluids, interferences, and difficulty in sweat extraction. Moreover, the workability and reliability of biodevices can be limited due to the limited fluctuating and volume of biofluids. In order to avoid frequent recalibrations, the stability of biodevices or self-calibration systems are also important. Precise electrochemical functions for on-skin applications are still very challenging. Therefore, it is required careful attention to address all challenges in order to advance such wearable technologies.
\nAlthough main skin-worn BFCs have been driven by glucose and lactate fuels, it is interesting to explore new opportunities, such as from alcohol-based BFCs, where the bioanode can be functionalized with alcohol dehydrogenases. Future efforts may be made to expand the spectrum of current concepts. New integrated devices can be achieved by designing multifunctional sensors that can provide informative series of personalized data. This will require the incorporation of big-data analysis and Internet of things (IoT) to build up integrated networks and personalized baselines of each wearer. Big data collected from networks and individuals can then warn the user whether the body is in a healthy and equilibrium state or not. It is expected that developing new electrochemical biodevices will eventually track “fingerprints” of various pathologies and disorders. This aims toward wearable systems for early disease diagnosis. Moreover, full closed-loop concepts such as biocomputing logic gate, sensing, and therapeutic systems can also be further exploited in the integration of biosensors, BFCs, and drug delivery devices, in order to obtain both diagnostic and therapeutic applications. The next success of wearable biodevices needs the hybrid of multidiscipline, including physiological medicine, electronics, electrochemistry, bio- and nanoengineering, and computer science. These continued collaborative efforts will open fantastic opportunities for addressing current challenges and step further to create novel wearable devices and acquire comprehensive big data. Ultimately, it is expected that innovative wearable electrochemical technologies and new findings will contribute to revolutionizing diverse personalized wearables and biomedical applications.
\nThe author would like to acknowledge Hassler Bueno for proof reading.
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