Objective To investigate the early change of brain-derived neurotrophic factor (BDNF) in denervated red and white muscles and the regeneration of nerves innervating the muscles and to discuss the effect of the target organs on regeneration of the injured nerves.Methods Forty Wistar rats were divided into 5 groups. The sciatic nerves in 4 groups were sheared to make the models of the denervated muscles and the other one as control group. The amount of BDNF in muscles was measured with immunohistochemistry 1 day, 3 days, 7 days and 14 days after injury. The models of the regeneration of the nerves were made in another 15 rats whose sciatic nerves were disconnected with forceps. The nerve conduction velocity and electromyogram were tested with neuroelectrophysiology7 days and 14 days after injury. Results The expression of BDNF in soleus increased significantly on the 1st day, the 3rd day and the 7th day (P<0.01); theexpression ingastrocnemius was lower, but there was no significant difference(P>0.05) on the 1st day, the 3rd day,the 7th day and the 14th day when compared with control group. After 14 days of injury in the nerves innervating GAS and SOL, the nerve conduction velocities and the amplitudes of wave M recovered to (36.60±7.40)% and (19.9±6.4)% of normal value, and (42.50±3.50)% and (13.7±4.0)% of normal value respectively; there were no significant differences between the two muscles(P>0.05).Conclusion There is- difference in BDNF amount between the denervated red and white muscles, but the recovery of the two kinds of the motornerves is similar,and the neurotrophism of denervated muscles was determined by all kinds of neurotrophic factors.
OBJECTIVE To observe the degeneration and regeneration of the Meissner’s corpuscles after implanted sensory nerve into the denervated monkey’s fingers under electron microscope. METHODS The two finger nerves of the monkey’s fingers were denervated. Afterwards, one finger nerve was cut off, and the other was reimplanted into the denervated finger. After 1, 3, 5, 8 and 12 months, the finger skin was cut off and observed under electron microscope. RESULTS The degenerative changes of nerve ending in Meissner’s corpuscles were observed after 1 month of denervation, and the basic structure of the corpuscles had no obvious changes. After 3 months, the axons of corpuscles were disappeared, and the volume of corpuscles was shrunk. The basic structure of nerves was disappeared, and the lemmocyte and neurolemma plate were changed after 5 months. The collagen fibrils in the corpuscles were gradually increased in 8 months, the endoneurial structure and interneurial matrix were completely disappeared and replaced by collagen fibrils in 12 months. After 3 months of nerve implantation, unmyelinated nerve fibers were appeared and grew into the corpuscles. A part of corpuscles innervated in 5 months. Most of corpuscles innervated and myelinated nerve fibers were observed in 8 months. And in 12 months, corpuscles innervated to normal level. CONCLUSION The implantative sensory nerve by means of reinnervating the original corpuscles and regenerating new corpuscles could innervate the degenerative Meissner’s corpuscles.
OBJECTIVE: To clarify the character of nerve growth factor (NGF) in the denervated red and white muscles and the relationship between the amount of NGF and sensitive neurotrophism of denervated red and white muscles. METHODS: The model of the denervated gastrocnemius and soleus was made by clipping the sciatic nerve of Wister rats. The immunohistochemistry was taken to measure the amount of NGF in muscles, and the neurotrophism of extracts of muscles was tested with culture of dorsal root ganglions at the 1st, 3rd, 7th and 14th days after injury. RESULTS: The amount of NGF in denervated gastrocnemius and soleus decreased, especially in soleus. The neruotrophism of the extracts of the two kinds of denervated muscles did not decrease; on the contrary, it increased after a week after injury. CONCLUSION: The injury of peripheral nerves causes the amount of NGF in the target tissues to increase, but the change is different between the denervated muscles; the neurotrophism of the extracts of musclesis determined by all kinds of neurotrophic factors, and can not be explained by a single factor.
ObjectiveTo investigate the expression of miRNA-1 in denervated skeletal muscle at different periods, and to explore effects of passive movement on the expression of miRNA-1 and differentiation of myoblasts in denervation-induced skeletal muscle atrophy in rats. MethodsTwenty-seven Sprague Dawley rats, weighing (200±10) g, were randomly divided into sham-operated group (group A, n=3), denervated group (group B, n=12), and passive movement group (group C, n=12). After the right sciatic nerve was exposed and dissociated, the sciatic nerve of 1 cm in length was removed in groups B and C; resection was not performed in group A. At 1 day after operation, passive flexion and extension movement was performed on the right hind limb in group C. At 6 hours in group A and at 3, 7, 14, and 28 days in groups B and C, 3 rats were sacrificed to measure the wet weight ratio of gastrocnemius muscle, to observe the diameter of the gastrocnemius muscle cell and evaluate the muscle atrophy by HE staining; RT-PCR was used to detect the mRNA expression of miRNA-1 and myocyte differentiation factor (MyoD), and immunohistochemistry to determine the protein expression of MyoD. ResultsAtrophy in various degrees was observed in denervated gastrocnemius muscle of groups B and C. The muscle fiber arranged in disorder and the diameter of the muscle cells decreased gradually with the time, without normal structure and morphology. The wet weight ratio and the cell diameter of the gastrocnemius in groups B and C were significantly less than those in group A (P<0.05); the wet weight ratio at 7, 14, 28 days and the cell diameter at 7, 14 days of group B were significantly greater than those of group A (P<0.05). The expressions of miRNA-1 and MyoD mRNA gradually increased with time in groups B and C, but were significantly less than those of group A at each time point (P<0.05). At 7, 14, and 28 days after operation, the expressions of miRNA-1 and MyoD mRNA in group C were significantly higher than those in group B (P<0.05). Immunohistochemical staining showed positive expression of MyoD in groups A, B, and C at each time point, but higher expression was observed in groups B and C than group A; the expression increased with time in groups B and C, and it was significantly higher in group C than group B. The correlation analysis results showed that the overall change trend of miRNA-1 and MyoD had no relation with the gastrocnemius wet weight ratio at 3 and 7 days (P>0.05), and had positive correlation at 14 and 28 days (P<0.05); positive correlation was found between the relative expression of MyoD and miRNA-1 mRNA (P<0.05). ConclusionPassive movement can prevent amyotrophy by increasing the expression of miRNA-1 and promoting the differentiation of myoblasts.
Objective To investigate the effect of the neuromuscular pedicle transplantation in prevention against atrophy in the denervated muscle. Methods Fortyeight SD rats were used to establish the right side tibialis anterior muscle denervation model. The long peroneal muscle neuromuscular pedicle was made as a treatment in 12 rats (Group A); the nerve shaft embedding was used in 12 rats (Group B); no treatment was used in 12 rats(Group C); the remaining 12 rats were used as normal controls (Group D). The gait analysis, electromyogram,muscle wet weight, and muscle fiber crosssectional area were used to determine and compare the effect of the operation at 6 and 12 weeks postoperatively. ResultsAt 6 weeks postoperatively, the parameters tested in Group A about the gait analysis (peroneal function index, PFI, -47.20±12.30), electromyogram, muscle wet weight (0.384 0±0.024 6 g)and muscle fiber cross-sectional area (1 040.98±120.54 μm2) were significantly better than those in Group C (PFI, -114.40±14.84; muscle wet weight, 0.173 0±0.019 1 g; muscle fiber cross-sectional area, 585.08±182.93 μm2,Plt;0.05), and the final two parameters were significantly better than those in Group B (0.294 0±0.056 4 g,763.92±82.68 μm2,Plt;0.05). At 12 weeks postoperatively, the musclefiber crosssectional area in Group A(1 360.10±261.45 μm2) had no significant difference from that in Group D (1 544.57±266.92 μm2,Pgt;0.05),and most of the parameters tested in Group A were better than those in Groups B and C. Conclusion Neuromuscular pedicle transplantation has an excellent effect in prevention against atrophy in the denervated muscle, and the effect of neuromuscular pedicle transplantation is better than that of the nerve shaft embedding.
Objective To investigate the influence of clenbuterol on the expression of nerve growth factor (NGF) in denervated red and white muscles and the neurotrophism of the denervated muscles.Methods Sixty-four Wister rats, weighed 200-250 g, were divided into 8 groups(8 rats per group), including 4 experimental groups and 4 control groups. The denervated model was made in rats by dissection of sciatic nerves. Clenbuterol was given at a dose of 200 μg/kg per day in the experimental group, saline in the control group. The expression of NGF was measured with immunohistochemistry after 1, 3, 7 and 14 days of injury. The culture methods of dorsal root ganglions of the chick embryos were used to measure the neurotrophism of extracts of the muscles. Results Compared with the control groups, the NGF content of gastrocnemious(GAS) increased on the 1st day (Plt;0.05) and the NGF content of soleus(SOL) increased greatly on the 1st, 3rd and 7th dayafter injury in the experimental groups (Plt;0.01). In the experimental groups, the NGF amount of GAS reached the highest value on the 1st day after injury(Plt;0.01) and then decreased gradually. And the NGF amount of SOL had slight difference between different time. The NGF content of the SOL was higher than that of GASon the 7th day (Plt;0.05). The sensory neurotrophism of the extracts was similar between SOL and GAS.Conclusion Clenbuterol can change the expression of NGF in denervated muscles, but the change was different in SOL and GAS. The sensory neurotrophism of the denervated muscles were determined by all of the neurotrophic factors in them.
In order to explore the effects of clenbuterol on intramuscular collagen metabolism in denervated skeletal muscles, a randomized, double-masked and placebo-controlled group were studied. Seventy-one patients with complete function loss in muscularcutaneous nerve resulted from brachial plexus injury were administered clenbuterol or placebo 60 micrograms Bid for more than 3 months. Biopsies of the biceps brachia muscle were performed at the beginning and end of this study. The biopsied muscles were processed with anti-collagen I and IV immunohistochemical stains and image analysis as well. The result showed that the collagen proliferation of both type I and IV was much reducible in the clenbuterol-treated group than that of the placebo-treated group (P lt; 0.05). It was concluded that clenbuterol could inhibit partially the proliferation of intramuscular collagens in denervated skeletal muscle.
Objective To investigate the effect of Ligustrazine on the expressions of FoXO3a, MAFbx, and MuRF1 indenervated skeletal muscle atrophy rats. Methods Fifty-four 8-week-old female Sprague Dawley rats were randomly dividedinto 3 groups: normal control group (group A, n=6), denervated control group (group B, n=24), and Ligustrazine interventiongroup (group C, n=24). After the denervated gastrocnemius models were established in the rats of groups B and C, sal ine andLigustrazine [80 mg/(kg·d)] were given every day by intraperitoneal injection, respectively. However, no treatment was donein group A. At 2, 7, 14, and 28 days after denervation, the wet weight of gastrocnemius was measured to calculate the ratio ofwet weight. The mRNA and protein expression levels of FoXO3a, MAFbx, and MuRF1 were detected by RT-PCR and Westernblot. Results The ratio of gastrocnemius wet weight decreased with time after denervation in groups B and C, showingsignificant differences when compared with that of group A (P lt; 0.05), and group C were significantly higher than that of groupB at 7, 14, and 28 days (P lt; 0.05). The mRNA and protein expressions of FoXO3a, MAFbx, and MuRF1 in groups B and Cwere significantly higher than those in group C at 7, 14, and 28 days (P lt; 0.05), and group C was significantly lower than groupB (P lt; 0.05). Conclusion Ligustrazine may postpone denervated skeletal muscle atrophy by reducing mRNA and proteinexpressions of FoXO3a, MAFbx, and MuRF1.
Objective To study the effect of the competitive inhibitor of nitric oxide synthase NG-nitro-L-arginine methyl ester (LNAME) on thedenervated muscle atrophy. Methods A model of the denervated gastrocnemius atthe right lower limb was established in 36 SD adult rats. The rats were randomly divided into two groups: the L-NAMEgroup (Group A) and the control group(Group B). L-NAME 10 mg/ kg daily was injected into the denervated gastrocnemius inGroup A, and normal saline was injected into the denervated gastrocnemius in Group B. At 2, 4 and 8 weeks after operation, the rate of the muscle wet weight preservation, the cross section area of the myocyte, the protein amount, and the percentage of the apoptotic muscle cells were measured respectively and the ultramicrostructure of the myocyte was observed. Results At 2 and 4 weeks after operation, the rate of the muscle wet weight preservation, the cross section area of themyocyte, and the protein amount were significantly greater in Group A than in Group B; however, the percentage of the apoptotic muscle cells was significantly smaller in Group A than in Group B. The observation of the ultramicrostructure of themyocyte showed that an injection of L-NAME could protect the ultramicrostructure of themyocyte. At 8 weeks after operation, there was no significant difference between the two groups in the abovementioned parameters. Conclusion The nitric oxide synthase inhibition can delay the denervated muscle atrophy.
ObjectiveTo understand research progress of animal model of esophageal achalasia and discuss its pathogenesis briefly.Method Literatures about research progress of animal model of esophageal achalasia were reviewed. ResultsThe models of esophageal achalasia could been made in several ways, such as the obstruction model, the classic denervation model, and the increasingly popular gene model. These models were all based on the theory of the corresponding causes, with the processing of different factors, then completed the preparation of animal model. Conclusionsanimal model of esophageal achalasia goes through three stages: obstruction model, denervation model, and gene model. gene model of esophageal achalasia based on congenital theory could help us understand this disease better and make an ideal animal model, which could provide a reliable evidence for etiology study.