Objective To explore the effect of tri pterygium glycoside (TG) on the skeletal muscle atrophy and apoptosis after nerve allograft. Methods Twenty Wistar male rats were adopted as donors, weighing 200-250 g, and the sciatic nerves were harvested. Fifty SD male rats were adopted as recipients, weighing 200-250 g. Fifty SD rats were made the models of10 mm right sciatic nerve defect randomly divided into five groups (n=10): group A, group B, group C, group D and group E.groups A and B received fresh nerve allograft, groups C and D received sciatic nerve allograft pretreated with TG, and group E received autograft. The SD rats were given medicine for 5 weeks from the second day after the transplantation: groups A and E were given physiological sal ine, groups B and D TG 5 mg/ (kg·d), and group C TG 2.5 mg/ (kg·d). At 3 and 6 weeks, respectively, after nerve transplantation, general observation was performed; the structure of skeletal muscles was observed by HE staining; the diameter of skeletal muscles was analyzed with Image-Pro Plus v5.2; the ultrastructure of skeletal muscles was observed by TEM; the expressions of Bax and Bcl-2 were detected by immunohistochemical staining; and the apoptosis of skeletal muscles was detected by TUNEL. Results All rats survived to the end of the experiment. In general observation, the skeletal muscles of SD rates atrophied to different degrees 3 weeks after operation. The muscular atrophy in group A was more serious at 6 weeks, and that in the other groups improved. The wet weight, fiber diameter and expression of Bcl-2 in group A were significantly lower than those in groups B, C, D and E (P lt; 0.01);those in groups B, C and D were lower than those in group E (P lt; 0.05); and there were no significant differences among groups B, C and D (P gt; 0.05). The apoptosis index and expression of Bax in group A were significantly higher than those in groups B, C, D and E (P lt; 0.01);those in groups B, C and D were higher than in groupE (Plt; 0.05); and there were no significant differences among groups B, C and D (P gt; 0.05). Three weeks after nerve allograft, under the l ight microscope, the muscle fibers became thin; under the TEM, the sarcoplasmic reticulum was expanded. Six weeks after nerve allograft, under the l ight microscope, the gap of the muscle fibers in group A was found to broaden and connective tissue hyperplasia occurred obviously; under the TEM, sarcomere damage, serious silk dissolution and fragmentary Z l ines were seen in group A, but the myofibrils were arranged tidily in the other groups, and the l ight band, dark band and sarcomere were clear. Conclusion TG can decrease the skeletal muscle atrophy and apoptosis after nerve allograft. The donor’s nerve that is pretreated with TG can reduce the dosage of immunosuppressant for the recipient after allograft.
Objective To investigate the effect of exogenous erythropoietin (EPO) on the denervated muscle atrophy. Methods Twenty-four SD male rats, weighting 200-220 g were made the models of denervated gastrocnemius muscle after sciatic nerves were transected under the piriform muscle at the right lower leg, and were randomly divided into two groups (n=12). rhEPO (2 500 U/kg) was injected daily into the denervated gastrocnemius muscle in EPO group, and normal sal ine was injected into the denervated gastrocnemius muscle in control group. To observe the general state of health of the experimental animal, the muscle wet weight, the muscle cell diameter, the cross section area, the protein amount, thepercentage of the apoptotic muscle cells, and the Na+-K+-ATPase and Ca2+-ATPase activities were measured 2 and 4 weeks after operation. Results All experimental animals were survived during experiment without cut infection, and all animals could walk with pull ing the right knee. At 4 weeks after operation, 7 cases showed ulcer in the right heel, inculding 5 in the control group and 2 in the EPO group. At 2 and 4 weeks after operation, the muscle wet weight in EPO group was (885.59 ± 112.35) and (697.62 ± 94.74) g, respectively; in control group, it was (760.63 ± 109.05) and (458.71 ± 58.76) g, respectively; indicating significant differences between two groups (P lt; 0.01). The protein amount in EPO group was (77.37 ± 5.24) and (66.37 ± 4.87) mg/mL, respectivly;in control group, it was (65.39 ± 4.97) and (54.62 ± 6.32) mg/mL;indicating significant differences between two groups (P lt; 0.01). At 2 and 4 weeks after operation, the myofibrillar shapes were nearly normal in EPO group while there were muscle fiber atrophy, some collapse and obviously hyperblastosis between muscle bundle. There were significant differences in the muscle cell diameter and the cross section between two groups (P lt; 0.01). However, the percentage of the apoptotic muscle cells was 11.80% ± 1.74% and 28.47% ± 1.81% in control group, respectively, which was significantly smaller than that in EPO group (21.48% ± 2.21% and 55.89% ± 2.88%, P lt; 0.01). At 2 and 4 weeks after operation, Na+-K+-ATPaseand Ca2+-ATPase activities in EPO group were higher than those in control group (P lt; 0.01). Conclusion EPO can delay the denervated muscle atrophy.
Objective To observe whether the motor nerve babysitter could improve the delayed nerve anastomosisand promote the functional recovery. Methods Sixteen SD rats weighing 200-250 g were randomly divided into 2 groups.In group A, the left musculocutaneous nerve was transected to make the model of biceps brachii denervation and anastomosed to its proximal end 6 weeks later; In group B, the musculocutaneous nerve was transected and the distal end was coapted to the purely motor medial pectoral nerve immediately (nerve babysitter) and the musculocutaneous nerve was separated from the medial pectoral nerve, and reanastomosed to its proximal end 6 weeks later. In the animal model, the left l imbs served as experimental sides, the right l imbs as control sides. After 6 and 12 weeks of the second surgery, behavioral test (grooming test) was performed and the degree of the biceps brachii atrophy was observed, the latent period and the ampl itude of the maximun action potentials of the biceps brachii were detected, the wet muscle weight, muscle fiber cross-section area and the activity of Na+-K+-ATPase of the biceps brachii were measured. Results After 4 weeks of the second surgery, grooming behavior was found in group B, while few grooming behavior was seen in group A till 6 weeks after the secondary surgery. After 6 weeks of the second surgery, the recovery rate of the latent period and the ampl itude, the wet muscle weight, muscle fiber cross-section area and the enzymatic activity of Na+-K+-ATPase of the biceps brachii in group A was 187.25% ± 1.97%, 46.25% ± 4.63%, 55.14% ± 1.99%, 49.97% ± 1.71%, and 65.81% ± 2.24%, respectively, which was significantly different from that in group B (155.96% ± 3.02%, 51.21% ± 2.13%, 74.18% ± 1.82%, 55.05% ± 1.64% and 71.08% ± 1.53%, respectively, P lt; 0.05). After 12 weeks of the second surgery, the recovery rate of the latent period and ampl itude, the wet muscle weight, muscle fiber cross-section area andthe enzymatic activity of Na+-K+- ATPase of the biceps brachii in group A was 145.36% ± 3.27%, 51.84% ± 5.02%, 77.92% ± 1.73%, 61.04% ± 2.68% and 71.94% ± 1.65%, respectively, which was significantly different from that in group B (129.83% ± 8.36%, 75.22% ± 2.78%, 84.51% ± 1.34%, 78.75% ± 3.69% and 84.86% ± 1.81%, respectively, P lt; 0.05). Conclusion Motor nerve babysitting could reduce muscular damage after denervation, improve the effect of delayed nerve repair and promote the functional recovery of musculocutaneous nerve.
Objective To summarize the recent progress in research on the mechanism of denerved skeletal muscle atrophy. Methods The recently-publ ished l iteratures at home and abroad on denerved skeletal muscle atrophy were reviewedand summarized. Results The mechanism of denerved skeletal muscle atrophy was very complex. At present, the studyof the mechanism was based on the changes in histology, cytology and molecules. Fiber thinning and disorderly arrangement of denerved skeletal muscles were observed and apoptotic bodies were detected. Apoptosis-promoting genes expressed upregulatedly and apoptosis-restraining genes expressed down-regulatedly. Muscle satell ite cells increased after denervation, but then they decreased and disappeared because they could not differentiate to mature muscle fibers. The structural change of cytomiscrosome and down-regulation of metabol ism-related enzymes induced cell metabol ism disorder. Conclusion The histological change of skeletal muscle fibers, the change of the number of muscle satell ite cells and differentiation, the structural change of cytomiscrosome and the change of apoptosis-related and metabol ism-related gene expressions contribute to denerved skeletal muscle atrophy.
Objective To investigate the delay of the denervated skeletal muscle atrophy with the method of restraining the increment of the connective tissues by tetrandrine and hormone. Methods The left hind limbs of 42 male adult SD rats were made into models of the denervated gastrocnemius, and then the rats were randomly divided into 3 groups, with 14 rats in each. In Group A, tetrandrine (8 mg/L)was injected into the denervated gastrocnemius; in Group B, triamcinolone acetonide(1.6 g/L) was injected; in Group C (the control group),normal saline was injected. Enough samples were obtained according to the different observation indexes at 30 days after operation. Electromyography, muscle wet weight measurement, light microscopy,electron microscopy,and microimage analysis were performed. ResultsThe fibrillation potential amplitude was 0.195 8±0.041 9 μV in Group A and 0.185 2±0.050 3 μV in Group B, and there was no significant difference betweenthe two groups (Pgt;0.05). However,in Group C the fibrillation potential amplitude was 0.137 7±0.058 9μV. The fibrillation potential amplitude was significantly greater in Group A than in Group C(Plt;0.05). The muscle wet weight was 1.740 0±0.415 9 g in Group A and 1.940 1±0.389 4 gin Group B, and there was no significant difference between the two groups(Pgt;0.05).However, in Group C the muscle wet weight was 0.800 0±0.100 0 g. The muscle wet weight was significantly greater in Group A than in Group C(Plt;0.05).The microscopy showed that more remarkable atrophy occurred in the control group. The muscle fibers were more complete, thicker and larger, with more nuclei and clearer cross-lines. More connective tissue and flat cells could be observed in Groups A and B. The myogenic protein amount was 440.124 2±46.135 6 in Group A and 476.211 4±41.668 8in Group B, and there was no significant difference between the two groups(Pgt;0.05).However, in Group C the amount was 380.040 0±86.315 9.The myogenic protein amount was significantly greater in Group A thanin Group C(Plt;0.05). The muscle fiber number, diameter, cross section, and connective tissue increment were all significantly greater in Group A than in Group C(Plt;0.05); however, there wasno significant difference between Groups A and B (Pgt;0.05). The electron microscopy showed that there were more degeneration changes, such as muscle silk disorder, chondriosome disappearance, and hepatin reduction, could be observed inGroup C than in Groups A and B. Conclusion Tetrandrine and hormone can delay the denervated skeletal muscle atrophy by restraining the increment of the connective tissues.
Muscle atrophy of the residual limb after lower-limb amputation is a disadvantage of amputees' rehabilitation. To investigate the biomechanics mechanism of muscle atrophy of the residual limb, we built a finite element model of a residual limb including muscle, skeletons and main vessels based on magnetic resonance images of a trans-femoral amputee, and studied the biomechanics effects of the socket of the lower-limb prosthesis on the soft tissue and vessels in the residual limb. It was found that the descending branch of the lateral femoral circumflex artery suffered the most serious constriction due to the extrusion, while that of the deep femoral artery was comparatively light. Besides, the degree of the constriction of the descending branch of the lateral femoral circumflex vein, femoral vein and deep femoral vein decreased in turn, and that of the great saphenous vein was serious. The stress-strain in the anterior femoral muscle group were highest, while the stress concentration of the inferior muscle group was observed at the end of the thighbone, and other biomechanical indicators at the inferior region were also high. This study validated that the extrusion of the socket on the vessels could cause muscle atrophy to some degree, and provided theoretical references for learning the mechanism of muscle atrophy in residual limb and its effective preventive measures.
This study analyzed the inherent relation between arterial blood mass flow and muscle atrophy of residual limb to provide some necessary information and theoretical support for the clinical rehabilitation of lower limb amputees. Three-dimensional arterial model reconstruction was performed on both intact side and residual limb of a unilateral transfemoral amputee who is the subject. Then hemodynamic calculation was carried out to comparatively analyze the mass flow state at each arterial outlet of both lower extremities. The muscle atrophy ratio of residual limb was calculated by measuring the cross-sectional area of bilateral muscles. Based on the blood supply relationship, the correlation between arterial blood flow reduction ratio and muscle atrophy ratio was discussed. The results showed that the mass flow of superficial femoral arteries and lateral circumflex femoral arteries severely reduced. Meanwhile rectus femoris, vastus lateralis and vastus medialis which were fed by these arteries showed great atrophy too. On the contrary, the mass flow of deep femoral arteries and medial femoral circumflex arteries slightly reduced. Meanwhile gracilis, adductor longus, long head of biceps which were fed by these arteries showed mild atrophy too. These results indicated that there might be a positive and promotion correlation between the muscle atrophy ratio and the blood mass flow reduction ratio of residual limb during rehabilitation.
Objective To investigate the role of cysteinyl aspartate specific proteinase-3 (Caspase-3)/ gasdermin-E (GSDME)-mediated pyroptosis in skeletal muscle atrophy induced by cigarette smoke in mice.Methods To construct a mouse model of COPD, C57BL/6 mice were exposed to cigarette smoke (CS) for 24 weeks. HE staining was used to observe the changes in the morphology of the gastrocnemius muscle in mice. Immunohistochemistry was used to detect the expression of pyroptosis-related proteins in gastrocnemius muscle. To construct a model of skeletal muscle cell atrophy in vitro, C2C12 myoblasts were induced to differentiate into skeletal muscle cells with 2% horse serum, and then skeletal muscle cells were treated with cigarette smoke extract (CSE). Skeletal muscle cells were further treated with the caspase-3 inhibitor Z-DEVD-FMK and the GSDME inhibitor Dimethyl fumarate (DMF) to explore the effects of inhibition of caspase-3/GSDME on CSE-induced skeletal muscle cell atrophy. To observe the effects of TNF-α on the expression of caspase-3 and GSDME proteins as well as the impact on myotubes, skeletal muscle cells were stimulated with tumor necrosis factor-alpha (TNF-α). Western blotting was applied to detect protein expression levels of caspase-3 and GSDME in skeletal muscle cells. Hoechst 33342/ Hoechst33342/ Propidium Iodide (PI) staining was applied to detect the PI-positive rate of skeletal muscle cells. The lactate dehydrogenase (LDH) release of C2C12 myotubes was measured by LDH release test. Immunofluorescence was used to detect changes in myotube diameter. Results CS-induced skeletal muscle atrophy was observed in mice, accompanied by increased pyroptosis- associated proteins (c-caspase-3 and GSDME-N) (P<0.05). CSE also induced elevated c-caspase-3 and GSDME-N expression in C2C12 cells , resulting in increased LDH release, positive ratio of PI, along with reduced myotube diameter (P<0.05). In addition, TNF-α promotes myotube atrophy and the expression of cleaved-caspase-3 and GSDME-N proteins in skeletal muscle cells. ConclusionCS can induce skeletal muscle atrophy through activated TNF-α/Caspase-3/GSDME-mediated pyroptosis.