Number of subjects, age, and hip joint sheath thickness in control group.
1. Introduction
Chronic renal failure (CRF) is associated with life-threatening accumulation of metabolic products due to the inability of their elimination. On hemodialysis, toxic substances are eliminated from the site of their high concentration (blood) via semipermeable membrane to a lower concentration medium (dialysis fluid) by the principle of diffusion. Hemodialysis has been widely used since the end of the 1960s. Although hemodialysis significantly prolongs life expectancy in CRF patients, hemodialyzers cannot compensate for all kidney functions. Hemodialyzer function has been greatly upgraded by technical innovations, however, many kidney functions in the regulation of homeostasis such as hormone production, e.g., vitamin D active metabolite (calcitriol) and erythropoietin, and many other functions remain unfeasible. Kidneys are involved in mineral metabolism and are target organs for the action of parathormone. In CRF patients, bone metabolism impairment occurs at creatinine clearance of 50-60 mL/min. Therefore, prolonged duration of hemodialysis is associated with development of numerous complications, in particular those involving the osteoarticular system. These complications are due to osteodystrophy and dialysis related amyloidosis (DRA). Tenosinovitis, in particular involving finger and hand flexors, snapping fingers and joint contractures are frequently present, however, tendon rupture may also occur. Muscle atrophy leads to the loss of strength, inability to perform fine finger movements, with a reduced function and range of movements and joint contractures. The hands assume a typical shape of so-called amyloid hand, while fingers look like "guitar players" (Farrell & Bastani, 1997; Fitzpatrick et al., 1996). Pain, swelling, degenerative joint changes and effusions are bilateral and symmetric, and may vary from very mild through severe where movements are painful and limited (Kelly et al., 2007; Zhang et al., 2002). Shoulders, hips and knees are mostly involved, however, all other joints may also be affected (Yamamoto et al., 2008). Soft tissue and joint lesions lead to dysfunction of the musculoskeletal system. Subchondral cysts are seen on the bones and erosions on the joints; pathologic bone fractures may occur in advanced stages of amyloidosis. The number and size of the cysts increase with the length of dialysis. Amyloid bone cysts may frequently be misinterpreted as tumors. On x-ray study, amyloid cysts can be differentiated from "brown" tumors. Whereas the former are found in distal part of the bone, frequently bilateral, multiple, well delineated and with sclerotic edges, located subchondrally or in the area of ligament junction, "brown" tumors are found in the are of long bone diaphysis. β2-microglobulin is a polypeptide, molecular weight of 11800 daltons, found on the surface of most nucleated cells. Lymphocytes and T cells play a crucial role in the formation of β2-microglobulin. In normal individuals, β2-microglobulin is found in tissue fluids, synovia, serum and urine, filtered via glomerular filtration, resorbed and degraded in proximal tubules. Reduced function of proximal tubules results in elevated β2-microglobulin level in urine. Elevated serum β2-microglobulin levels may be due to its enhanced synthesis, as in some inflammatory diseases (e.g., rheumatoid arthritis, systemic lupus erythematosus, Sjögren's syndrome, Crohn's disease, cytomegalovirus infection, infectious mononucleosis, hepatitis C, HIV infection, chronic osteomyelitis), or malignant and lymphoproliferative diseases (multiple myeloma, β-cell lymphoma, chronic lymphocytic leukemia), or because of its decreased secretion due to reduced glomerular filtration in CRF patients. A number of factors are responsible for elevated β2-microglobulin level in the blood of hemodialysis patients. About 100-200 g β2-microglobulin or 2-4 mg/kg body weight are synthesized
In human body, β2-microglobulin is found in extracellular space, circulates as a free monomer and does not bind to plasma proteins (Connors et al., 1985). By polymerization, β2-microglobulin is transformed from soluble to insoluble form and accumulated in the form of amyloid deposits in various tissues causing structural and functional organ lesions. The complications that develop due to amyloid accumulation involve visceral organs and osteoarticular system in particular. The visceral form of amyloidosis involves numerous organs, e.g., heart, lungs, gastrointestinal system and urogenital system; subcutaneous amyloid deposits are quite common, in particular those involving gluteal region, and may also be found intradermally around hair follicles, sebaceous glands and blood vessels (Jimenez et al., 1998). In amyloidosis involving osteoarticular system, amyloid is accumulated between cells (in the interstitium) but rarely in blood vessels, whereas in case of visceral complications in CRF patients, subendothelial amyloid accumulation is seen with deposits in vascular walls to produce intraluminal protrusions in blood vessels. In the second half of the 1970s, carpal tunnel syndrome was observed to occur in hemodialysis patients due to accumulation of a new amyloid type (Kenzora, 1978; Warren & Otieno, 1975). In 1985, Geyo et al. demonstrated β2-microglobulin to be responsible for the development of a new type of amyloidosis in CRF patients (Denesh & Ho, 1998; Geyo et al., 1985; Tsvetkova et al., 2007). According to the World Health Organization 1993 nomenclature, amyloidosis in CRF patients is termed Aβ2m-amyloidosis. It is the most common complication in CRF patients. In the literature, a number of synonyms have been used for this type of amyloidosis, i.e. AB amyloidosis, dialysis amyloidosis, and dialysis related amyloidosis (DRA). As clinical manifestations of this complication occur in the advanced stage of the disease, it is necessary to detect it in its preclinical stage. Therefore, the lesions should be detected and followed-up before the clinical signs of the disease occur, and properly controlled during treatment. There are several diagnostic procedures used to follow-up the lesions involving osteoarticular system, e.g., x-ray, computed tomography (CT), magnetic resonance imaging (MRI), scintigraphy, biopsy, and ultrasonography (US). Changes of the osseous and articular structures are analyzed by use of x-ray studies. Radiological signs of arthropathy are present in patients undergoing hemodialysis for more than 5 years (Tsvetkova et al., 2007). X-ray is a presumptive method, i.e. bone lesions can be identified even before pain occurs. Changes are seen as typically distributed subchondral cystic bone lesions, usually of thin and sclerotic edges, joint erosions, and possibly pathologic fractures. After 10-year hemodialysis, 50%-60% of patients show bone cysts (Fitzpatrick et al., 1996). X-ray changes are not seen in early stages of the disease. Distribution and extension of amyloid pseudotumors and pseudocysts of bones and joints, around joints, small areas of osteolysis or cortical bone erosion are visualized by CT, however, this study is associated with exposure to higher irradiation doses (Kiss et al., 2005). MRI offers useful data on bone, joint and soft tissue changes and particular organ involvement (Fukuda & Yamamoto, 2001; Kiss et al., 2005), however, MRI is a more expensive, less available and more time consuming method, and therefore less commonly employed in clinical routine. The usual noninvasive diagnostic studies include US, classic x-ray and MRI. However, these are nonspecific and low sensitivity studies. Scintigraphy is a specific noninvasive diagnostic method used to identify amyloidosis distribution and extension all over the body (Floege et al., 2001; Hawkins et al., 1990; Ketteler et al., 2001; Linke et al., 2000). Three scintigraphy methods are most widely employed: standard bone scintigraphy by use of Tc-diphosphonates; scintigraphy with iodine 123I labeled serum amyloid P component (SAP); and scintigraphy by use of specific protein precursors in Aβ2M amyloid (131I-β2m). Biopsy is an invasive diagnostic method providing an insight into the local area lesions; however, it may be associated with periprocedural complications. Joint effusion puncture, rectal biopsy, abdominal adipose tissue biopsy (aspiration) and salivary gland biopsy are most commonly performed. Histologic changes of soft tissue develop far before clinical signs of the disease. Clinical signs of hemodialysis related amyloidosis occur in advanced stages of the disease. As clinical symptoms are nonspecific, they may easily be misinterpreted as other joint diseases. Patients undergoing hemodialysis for less than 5 years rarely show clinical signs of amyloidosis (Al-Taee et al., 2003). Carpal tunnel syndrome frequently occurs as the first clinical sign of amyloidosis (Ikegava et al., 1995; Shin et al., 2008). The number and severity of clinical symptoms are known to increase with the length of hemodialysis. After 15-year hemodialysis, clinical symptoms of hemodialysis related amyloidosis are present in 100% of patients (Al-Taee et al., 2003). Therefore, it is of utmost importance to follow-up the course of disease in its preclinical stage. There are direct and indirect diagnostic procedures used to demonstrate amyloidosis. An ideal diagnostic study should be noninvasive, repeatable, highly specific, inexpensive and widely available. Tissue biopsy is considered as the 'gold standard' to demonstrate amyloidosis, however, other diagnostic methods are also employed to reach the diagnosis. US has been widely accepted in the diagnosis of pathology, of the osteoarticular system soft tissues in particular. New US high-resolution devices with many technological innovations (e.g., offering the possibility of changing the frequency, focus, 3D image, using probes of various shape and size, movement analysis, i.e. real-time study, etc.) can measure morphological changes with precision of tenths of millimeter. Hemodialysis patients mostly show lesions of soft tissues, in particular tendons and synovial sheaths, with frequent tenosinovitis and joint effusion. On US, muscle lesions can be visualized, thickness of tendons, ligaments and joint sheaths measured, lesions of para-articular structures observed, and extent of joint effusion followed-up; tissue vascularization can be followed-up by Doppler US. Although not highly specific, US is a presumptive, widely available, noninvasive, repeatable and inexpensive study free from ionizing radiation that can be used to follow-up the course of the disease, therapeutic effects and possible complications involving the osteoarticular system in CRF patients. US can be used as a control tool on therapy administration or puncture of joints, bursae, cysts, ganglia, or on tissue biopsy. The aim of the present study was to assess the impact of hemodialysis duration, patient age and β2-microglobulin concentration at the onset of hemodialysis on morphological changes in the hip region.
2. Patients and methods
Bilateral hip US using a 7-cm linear probe of 7.5 MHz was performed in 106 hemodialysis patients aged >18 to measure articular sheath thickness and articular effusion in both hips. During the procedure, the patient was in supine position, with the leg in neutral position. We used anterior longitudinal approach where the probe is parallel to femoral neck axis. Thickness of the hip joint sheath measured in the concave segment of the femur was determined as distance from the joint sheath inner to outer edge. Synovial effusion in the hip region was expressed as distance between anterior cortex of the femoral neck concave segment and inner edge of the hip joint sheath. A total of 424 US measurements were performed in the study group and 204 bilateral measurements in the control group. Control group consisted of 51 healthy subjects that underwent the same measurements of hip joint sheath thickness and articular effusion. Study patients were divided into three groups according to the length of hemodialysis (<36, 36-72 and >72 months) and age (18-50, 51-65 and >65 years). In study patients, serum β2-microglobulin concentration was determined at the onset of hemodialysis, and in control subjects before US examination. All laboratory tests were performed at Laboratory of Biochemistry, Požega General Hospital, in Požega, Croatia. Beta2-microglobulin concentration was determined by use of the AxSYM β2-microglobulin microparticle enzyme immunoassay (MEIA; Abbott GmbH, Wiesbaden, Germany). Blood samples were obtained from cubital vein by use of Vacutainer system. Blood sample was centrifuged for 10 min at 3500 rpm within 5 hours of venepuncture. Subjects with a history of previous injury or operative procedure on the study joints, inflammatory (chronic osteomyelitis, tuberculosis, HIV infection, hepatitis C), malignant or rheumatic diseases, systemic lupus erythematosus, sarcoidosis, Sjögren's syndrome, Crohn's disease, or lymphoproliferative diseases (multiple myeloma, β-cell lymphoma, chronic lymphocytic leukemia) were excluded. All study patients were undergoing hemodialysis with low-flux hemodialyzers. All examinations were performed by the author himself in order to prevent inter-examiner finding variability. All study subjects were informed on the study protocol, objectives and methods used, expected benefits, possible risks, etc. Inclusion in the study was voluntary and all subjects signed the informed consent form. Study protocol was approved by the Ethics Committees of the Požega General County Hospital, Dr. Josip Benčević General Hospital from Slavonski Brod, and School of Medicine, University of Zagreb from Zagreb, Croatia.
3. Statistical methods
Kruskal-Wallis test was used to test significance of differences between different age groups. In addition, differences between pairs of groups were tested with Mann Whitney U-tests. Spearman's rank correlation coefficient was used to test correlation between age and concentration of β2M. Data were presented as mean, minimum and maximum in tables. The chosen level of statistical significance was p<0.05.
4. Results
Thickness of the hip joint sheath and articular effusion were measured bilaterally in 106 hemodialysis patients and the measured values were compared with those recorded in 51 control subjects. Measurement results were compared according to the length of hemodialysis, body side, age, sex, β2-microglobulin concentration, and measured thickness of the hip joint sheath and articular effusion in control subjects. The mean age of patients undergoing hemodialysis at the time of examination was 64.0 (range 28.2-87.4) years. There were 55 male patients, mean age 60.5 (28.2-87.4) years and 51 female patients, mean age 67.9 (30.7-82.0) years. The mean length of hemodialysis in 18-50, 51-65 and >65 age groups was 16, 53 and 123 months, respectively, mean 56.3 months. In control group consisting of 51 healthy volunteers, the mean age was 62.6 (40.0-86.4) years. There were 25 male subjects, mean age 61.6 (40.0-86.4) years and 26 female subjects, mean age 63.6 (40.5-81.0) years. There was no statistically significant difference in age between hemodialysis patients and controls (P˃0.05). The US measured thickness of hip joint sheath and articular effusion in control group according to age groups is shown in Tables 1 and 2, respectively.
Age (yrs) | Hip joint sheath thickness (mm) | |||
n | M | Min | Max | |
18-50 | 7 | 5.36 | 3.90 | 7.50 |
51-65 | 21 | 5.33 | 3.90 | 7.30 |
"/>65 | 23 | 4.69 | 3.10 | 7.50 |
Total | 51 | 5.04 | 3.10 | 7.50 |
Age (yrs) | Articular effusion thickness (mm) | |||
n | M | Min | Max | |
18-50 | 7 | 4.11 | 1.10 | 6.40 |
51-65 | 21 | 4.85 | 0.80 | 7.10 |
"/>65 | 23 | 4.44 | 2.10 | 7.00 |
Total | 51 | 4.56 | 0.80 | 7.10 |
The US measured thickness of the hip joint sheath and articular effusion using anterior longitudinal approach with the probe parallel to the femoral neck axis is presented in Figure 1.
The US measured thickness of hip joint sheath according to the length of hemodialysis and patient age is presented in Table 3A and B.
Age (yrs) | Length of hemodialysis | |||||||||||
<36 months | 36-72 months | "/>72 months | ||||||||||
n | M | Min | Max | n | M | Min | Max | n | M | Min | Max | |
18-50 | 8 | 5.30 | 3.90 | 6.50 | 5 | 6.32 | 5.10 | 7.40 | 3 | 7.93 | 6.70 | 9.00 |
51-65 | 10 | 5.45 | 4.00 | 6.90 | 9 | 6.44 | 5.00 | 8.70 | 7 | 6.86 | 4.20 | 8.50 |
"/>65 | 24 | 5.53 | 3.10 | 7.10 | 23 | 6.70 | 5.10 | 8.00 | 17 | 7.20 | 3.30 | 10.3 |
Total | 42 | 5.47 | 3.10 | 7.10 | 37 | 6.59 | 5.00 | 8.70 | 27 | 7.19 | 3.30 | 10.3 |
Age (yrs) | Length of hemodialysis | |||
Total | ||||
n | M | Min | Max | |
18-50 | 16 | 6.11 | 3.90 | 9.00 |
51-65 | 26 | 6.17 | 4.00 | 8.70 |
"/>65 | 64 | 6.39 | 3.10 | 10.3 |
Total | 106 | 6.30 | 3.10 | 10.3 |
Simple analysis of variance for independent samples with the length of hemodialysis (categorized into three groups) as independent variable, and hip joint sheath thickness and articular effusion as dependent variables was performed to assess the impact of hemodialysis duration on thickness of the hip joint sheath and articular effusion. A statistically significant difference was found in thickness of the hip joint sheath and articular effusion between groups of patients with different length of hemodialysis, as indicated by the results of simple analysis of variance: joint sheath thickness F=21.319; df=2/103;
Beta2-microglobulin concentration was determined before hemodialysis in the three patient age groups having undergone hemodialysis for a variable period of time. These results are shown in Table 4A and B.
Age (yrs) | Length of hemodialysis | |||||||
<36 months | 36-72 months | |||||||
n | M | Min | Max | n | M | Min | Max | |
18-50 | 8 | 31.020 | 19.874 | 42.662 | 5 | 34.331 | 25.580 | 43.688 |
51-65 | 10 | 28.586 | 10.115 | 50.864 | 9 | 29.241 | 11.032 | 41.376 |
"/>65 | 24 | 26.793 | 10.116 | 42.129 | 23 | 30.704 | 15.552 | 44.824 |
Total | 42 | 28.025 | 10.115 | 50.864 | 37 | 30.838 | 11.032 | 44.824 |
Age (yrs) | Length of hemodialysis | |||||||
"/>72 months | Total | |||||||
n | M | Min | Max | n | M | Min | Max | |
18-50 | 3 | 44.340 | 35.915 | 53.147 | 16 | 34.552 | 19.874 | 53.147 |
51-65 | 7 | 32.122 | 16.188 | 51.791 | 26 | 29.764 | 10.115 | 51.797 |
"/>65 | 17 | 32.069 | 10.328 | 47.997 | 64 | 29.600 | 10.116 | 47.997 |
Total | 27 | 33.446 | 10.328 | 53.147 | 106 | 30.388 | 10.115 | 53.147 |
Simple analysis of variance for independent samples with the length of hemodialysis (categorized into three groups) as independent variable, and pre-hemodialysis β2-microglobulin concentration as dependent variable performed to assess the possible impact of the length of hemodialysis on pre-hemodialysis β2-microglobulin concentration produced the following results: F=3.262; df=2/103;
Age (yrs) | Total | |||
n | M | Min | Max | |
18-50 | 7 | 1.133 | 0.942 | 1.537 |
51-65 | 21 | 1.541 | 0.963 | 2.617 |
"/>65 | 23 | 1.934 | 1.130 | 2.836 |
Total | 51 | 1.662 | 0.942 | 2.836 |
Hip joint sheath thickness was compared between patient and control group and tested for statistically significant between-group difference by use of t-test for independent samples, which yielded the following result: t=1.982; df=91;
Age (yrs) | Length of hemodialysis | |||||||||||
<36 months | 36-72 months | "/>72 months | ||||||||||
n | M | Min | Max | n | M | Min | Max | n | M | Min | Max | |
18-50 | 8 | 5.26 | 3.50 | 6.90 | 5 | 6.02 | 2.90 | 9.70 | 3 | 6.30 | 5.10 | 8.60 |
51-65 | 10 | 5.41 | 3.20 | 7.70 | 9 | 5.87 | 3.30 | 8.90 | 7 | 6.40 | 4.20 | 8.30 |
"/>65 | 24 | 6.14 | 3.90 | 11.5 | 23 | 6.86 | 4.40 | 9.40 | 17 | 7.06 | 2.70 | 11.0 |
Total | 42 | 5.80 | 3.20 | 11.5 | 37 | 6.50 | 2.90 | 9.70 | 27 | 6.80 | 2.70 | 11.0 |
Age (yrs) | Length of hemodialysis | |||
Total | ||||
n | M | Min | Max | |
18-50 | 16 | 5.69 | 2.90 | 9.70 |
51-65 | 26 | 5.84 | 3.20 | 8.90 |
"/>65 | 64 | 6.64 | 2.70 | 11.5 |
Total | 106 | 6.30 | 2.70 | 11.5 |
5. Discussion
Complications involving the osteoarticular system are common in CRF patients. These complications develop at a slow rate, their clinical signs make only the tip of the iceberg that mostly indicate an advanced stage of the disease and are generally due to renal osteodystrophy and hemodialysis-related amyloidosis. Increased intra-articular effusion and greater hip joint sheath thickness are not specific changes and may occur consequentially to many other pathologic conditions. There are numerous diagnostic procedures to detect and follow-up changes in the osteoarticular system. As most of these methods are associated with high requirements related to duration, price, equipment, room, exposure to ionizing radiation, invasiveness and potential complications, ultrasonography imposes itself as an inexpensive, noninvasive, presumptive, widely available and repeatable examination free from ionizing radiation. As dialysis-related amyloidosis is a multifactorial disease and its pathogenesis has not yet been fully clarified, we embarked upon this study to assess the effect of patient age, hemodialysis duration and β2-microglobulin concentration on morphological changes in the hip region. Thickness of the hip joint sheath and magnitude of intra-articular effusion were found to be proportional to the length of hemodialysis. Thus, early lesions of the osteoarticular system can be detected by measuring the magnitude of articular effusion in the hip area. The increase in intra-articular effusion could be explained by changes involving joint sheath and cartilage due to hemodialysis-related amyloidosis and initial signs of chronic arthropathy in patients with dialysis-related amyloidosis. Biochemical and histologic tests of joint structures can explain the presence of articular effusion and lesions involving the osteoarticular system. In CRF patients, the level of advanced glycation endproducts (AGE) is considerably elevated. These endproducts are formed in the state of uremia
The mechanism by which patient age influences the prevalence of complications in hemodialysis patients remains unknown. The concentration of AGEs is higher in elderly subjects (Sell & Monnier, 1990). As AGEs influence collagen metabolism, it may explain the impact of age on anatomic structure changes in this population. Schiffl et al. (2000) investigated the prevalence of complications involving osteoarticular system in hemodialysis patients aged <55 and >55. The latter had a higher rate of complications including carpal tunnel syndrome, amyloid arthropathy and bone cysts as compared to patients aged <55 at the time of starting hemodialysis. The older patient age, the higher was the rate of complications. The time elapsed from starting hemodialysis to the onset of complications was shorter in older than in younger patients. Kurer et al. (1991) found carpal tunnel syndrome to be more common in elderly patients and in those starting hemodialysis at an older age. In older patients, carpal tunnel syndrome developed after a shorter period of hemodialysis than in younger ones. However, opposite results have also been reported in the literature. Using the Glasgow Ultrasound Enthesitis Scoring System (GUESS) scale, Kerimoglu et al. (2007) found changes of the osteoarticular system anatomic structures in hemodialysis patients to be related to the length of hemodialysis, while demonstrating no effect of patient age and β2-microglobulin concentration. Weybright et al. (2003) point to the possible misinterpretations and false-positive results of US measurement of articular effusion in the hip area. Ultrasonography performance is limited in overweight patients. Synovial membrane of the hip joint covers fibrous membrane and cannot be visualized on US. Hypoechogenic synovia may push as the articular sheath, thus yielding an image of articular effusion. This is especially pronounced in obese subjects, where hypoechogenic synovia may appear as articular effusion on US. In our study, β2-microglobulin concentration influenced the hip joint sheath thickness in the group of patients on hemodialysis for <36 months, whereas no statistically significant correlation was observed in the other two patient groups. Serum β2-microglobulin concentration had no effect on the amount of articular effusion in the hip area in any patient group with different length of hemodialysis. In addition, there was no statistically significant difference in β2-microglobulin concentration among the three patient groups, however, β2-microglobulin concentration was higher in patients with longer hemodialysis duration. A high serum β2-microglobulin concentration is one of the preconditions for the development of hemodialysis-related amyloidosis; therefore, higher β2-microglobulin concentration is expected to be associated with more pronounced morphological changes of anatomic structures. There are no reports on hemodialysis-related amyloidosis in patients with β2-microglobulin concentration <10 mg/L (Farrell & Bastani, 1997). Because of different dialyzer membrane properties, β2-microglobulin concentration is by 30% lower in patients on hemodialysis with low-flux hemodialyzers (Jadoul, 1998). In their study including 50 patients, McCarthy et al. (1997) found residual kidney function to be preserved for a longer time in patients on hemodialysis with high-flux hemodialyzers. During the first 12-24 months of hemodialysis, β2-microglobulin concentration also depends on residual kidney function, i.e. the longer it is preserved, the later the onset of amyloidosis complications (Schiffl et al., 2000). The membrane of high-flux hemodialyzers is characterized by higher biocompatibility and lower rate of stimulating β2-microglobulin concentration production through complement activation. The high-flux dialyzer membrane can remove β2-microglobulin molecules and AGE modified proteins, thus influencing the process of amyloid formation (Henle et al., 1999; Jadoul, 1998). Therefore, the use of high-flux dialyzers is expected to be associated with a lower rate of complications involving the osteoarticular system (Geyo, 2001). Beta2-microglobulin concentration does not correlate with the activity of dialysis-related amyloidosis, thus serum β2-microglobulin concentration is not a diagnostic test to determine the severity of dialysis-related amyloidosis (Farrell & Bastani, 1997; Koski et al., 1989). A number of studies have confirmed that clinical symptoms of complications involving the osteoarticular system are more common in patients undergoing hemodialysis for a prolonged period of time, as well as in those with higher β2-microglobulin concentration (Barišić et al., 2007).
Shin et al. (2008) compared two groups of patients with different β2-microglobulin concentration and found the prevalence of carpal tunnel syndrome to be lower in patients with lower β2-microglobulin concentration. Barišić et al. (2007) report on a higher β2-microglobulin concentration in the group of hemodialysis patients articular pain as compared with those free from articular pain. In contrast, Kerimoglu et al. (2007) found no statistically significant correlation between GUESS scale and serum β2-microglobulin concentration. In the present study, intra-articular effusion in the hip area was statistically significantly greater bilaterally in all three hemodialysis patient groups as compared with control group. Difference in the hip joint sheath thickness did not reach statistical significance between control group and the group of patients on hemodialysis for <36 months, but was statistically significant in the groups of patients on hemodialysis for 36-72 and >72 months.
6. Conclusion
The present study demonstrated that changes involving osteoarticular system soft tissues in CRF patients could be followed-up by use of US. Although the National Kidney Foundation Kidney Disease Outcomes Quality Initiative (NKF KDOQI, 2003) recommendations do not recommend routine follow up of CRF patients by β2-microglobulin amyloidosis because there is no therapeutic option other than kidney transplantation for hemodialysis-related amyloidosis, we consider US a useful and widely available diagnostic method to detect and follow-up soft tissue changes in hemodialysis patients. In our study, pre-hemodialysis serum β2-microglobulin concentration did not influence the magnitude of articular effusion, but did influence hip joint sheath thickness in patients undergoing hemodialysis for <36 months, with no statistically significant correlation recorded in the other two groups of patients. Morphological changes correlated with the length of hemodialysis, but not with patient age. As the osteoarticular system changes are multifactorial, additional studies are needed to determine the effect of particular factors on these changes in CRF patients. Research should be focused on complications in patients undergoing hemodialysis with high-flux dialyzers in order to identify the possible impact of the type of hemodialyzers on osteoarticular system changes. US study is the method of choice to follow-up the dynamics of changes involving soft tissue structures (Bother et al., 2006; Drüeke, 1999; Kay et al., 1962; Kerimoglu et al., 2007; Kiss et al., 2005; Negi et al., 1995). Early and asymptomatic lesions of the joints, tendons and ligaments can be detected by US (Barišić et al., 2002; Jeloka et al., 2001; Lanteri et al., 2000; Takahashi et al., 2002). The need for the best possible care of hemodialysis patients points to the use of US as a adjunctive method to clinical examination to assess soft tissue changes of the osteoarticular system by providing better insight into the pathology of articular tendons, ligaments, cartilage and effusion (Backhaus et al., 2001; Takahashi et al., 2002). US analysis of morphological changes of the osteoarticular system can be of prognostic value in patients undergoing hemodialysis. Maintaining good function of the osteoarticular system helps the CRF patients achieve appropriate social inclusion and better quality of life, while reducing the cost of treatment for severe complications.
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