Objective To investigate the pathological changes in the neuromuscular junction during ischemiareperfusion(IR) in the skeletal muscle. Methods Forty-eight healthy adult Wistar rats (24 male, 24 female) were equally randomised into the following 6 groups: Group A (control group): no ischemiareperfusion; Group B: ischemia by clamping the blood vessels of the right hindlimb for 3 hours; Group C: ischemia by clamping for 4.5 hours;Group D: ischemia by the clamping for 4.5 hours followed by reperfusion for 1.5hours; Group E: ischemia for 4.5 hours followed by reperfusion for 24 hours; and Group F: ischemia for 4.5 hours followed by reperfusion for 2 weeks. Then, the medial head of the gastrocnemius muscle flap model was applied to the right hindlimb of each rat. The medial head of the gastrocnemius muscle was isolated completely,leaving only the major vascular pedicle, nerve and tendons intact.The proximal and distal ends (tendons) were ligated while the vessel pedicle was clamped. And then, Parameters of the muscle (performance,contraction index,colour,edema,bleeding) were observed. The muscle harvested was stained with gold chloride(AuCl3) and the enzymhistochemistry assay (succinate dehydrogenase combined with acetylcholine esterase) was performed. Morphology and configuration of the neuromuscular junction were observed during the ischemiareperfusion injury by means of the AuCl-3 staining. The result of the enzymhistochemical reactions was quantitatively analyzed with the computer imageanalysis system. And then, additional 5 rats were prepared for 3 different models identical with those in Groups A, C and E separately. The specimens were harvested from each rat and were stained with HE and AuCl-3, and they were examined under the light microscope. Results During the period of ischemia, the skeletal muscle of Group B showed the colour of purple and edema.The colour and edema became worse in Group ,while dysfunction of elasticity and contraction appeared obviously with plenty of dark red hemorrhagic effusion at the same time.After reperfusion,the color and edema of muscle in Group D became improved while the elasticity and function of contraction was not improved. Hemorrhagic effusion of Group D turned clearer and less than Group C.Group E was similar to Group D in these aspects of muscle except for much less hemorrhagic effusion. Skeletal muscle in Group F showed colour of red alternating with white, adhesion,contracture of muscle, exposure of necrotic yellow tissue and almost lost all its functions. The AuCl3 staining showed that during IR, necrosis of the myocytes was followed by degeneration of their neuromuscular junctions, and finally the nerve fibers attached to these neuromuscular junctions were disrupted like the withering of leaves. The enzymhistochemistry assay showed thatthere was no significant difference in the level of acetylcholine esterase between the ischemic group (Groups B and C) and the control group (Group A) (Pgt;0.05). However, the level of acetylcholine esterase in all the reperfused groups (Groups D, E and F) decreased significantly when compared with the control group(Group A)and the ischemic groups (Groups B and C) (Plt;0.01). Conclusion The distribution of the nerve fibers and the neuromuscular junctions in the mass of the muscles is almost like the shape of a tree. The neuromuscular junction seems to be more tolerant for ischemia than the myocyte. Survival ofthe neuromuscular junction depends on its myocytes alive. Therefore, an ischemiareperfusion injury will not be controlled unless an extensive debridement of the necrotic muscle is performed.
OBJECTIVE: To investigate the effects of bone morphogenetic protein (BMP) on the proliferation and collagen synthesis of skeletal muscle satellite cells. METHODS: Skeletal muscle satellite cells were harvested and cultured in vitro. The 0 ng/ml, 50 ng/ml, 100 ng/ml, 500 ng/ml, and 1000 ng/ml BMP were used to induce skeletal muscle satellite cells for 48 hours. Cell proliferation, rate of myotube formation and collagen-1 synthesis were measured. RESULTS: BMP promoted cell proliferation and reduced the rate of myotube formation. Collagen synthesis increased when skeletal muscle satellite cells were induced with more than 500 ng/ml BMP. And the higher the concentration of BMP was, the ber this effect became. CONCLUSION: BMP can enhance the proliferation of skeletal muscle satellite cells and change their differentiation from myoblasts to osteoblasts.
OBJECTIVE: To observe the changes of heme oxygenase-1 (HO-1) expression in the skeletal muscle after ischemia-reperfusion of hind limb in rats. METHODS: A model of hind limb ischemia was made by clamping femoral artery with a microvascular clip. Soleus muscle was obtained from the animals received sham operation, 4 h ischemia without reperfusion and 2 h, 4 h, 8 h, 16 h, 24 h reperfusion after 4 h ischemia. Soleus histology and malondialdehyde (MDA) content were measured. The levels of HO-1 mRNA and protein were measured in different time by Northern blotting, Western blotting and immunohistochemistry technique. RESULTS: After ischemia-reperfusion of limb, HO-1 mRNA increased at the 2nd hour, reached a peak at the 8th hour, and returned toward baseline at the 24th hour. The change of protein level was essentially in agreement with that of mRNA. Immunohistochemical results showed that HO-1 expressed primarily in skeletal muscle cytoplasma. There were no positive signals of mRNA and protein in sham group and in ischemia group. After limb reperfusion, MDA contents in the soleus muscle increased significantly when compared with that in the sham group (P lt; 0.05). MDA content of the 8th after reperfusion decreased significantly when compared with that of the 4 h after reperfusion (P lt; 0.05). CONCLUSION: Ischemia-reperfusion can induce HO-1 expression in skeletal muscle in rats, which may provide protection for injured tissue.
OBJECTIVE: To define how to preserve the severed limbs to prolong the period of replantation. METHODS: The original articles about preservation of severed limbs in recent years were reviewed, it was suggested that the period of replantation was determined by the injury of skeletal muscle. RESULTS: When the environment of severed limbs was changed, the injures of skeletal muscle could be decreased. CONCLUSION: After the severed limbs are reasonably preserved, the period of replantation may be prolonged.
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 review researches of the role of inhibitorof differentiation 2(Id2) in skeletal muscle regeneration. Methods The latest original literature concerning Id2 and its role in skeletal muscle regeneration was extensively reviewed. Results Id2 could form heterodimers by combining with E protein to prevent myogenic regulatory factors (MRFs) forming heterodimers by combining with E protein, to inhibit the transcription activity of MRFs anddifferentiation of skeletal muscle cell. Conclusion Id2 plays an important role in skeletal muscle regeneration.
ObjectiveTo explore an optimized protocol of decellularization to fabricate an ideal scaffold derived from porcine skeletal muscle acellular matrix. MethodsSerial-step protocol of homogenating-milling-detergent method was used to fabricate decellularized porcine muscle tissue (DPMT) derived from native porcine skeletal muscle tissue from adult pig waist. Histological method was used to assess the effects of decellularization and degreasing. Sirius red staining was used to analyze collagen components. Scanning electron microscopy, BCA assay, and PicoGreen assay were used to evaluate the ultrastructure, total protein content, and DNA content in DPMT. The adipose derived stem cells (ADSCs), NIH3T3 cells, and human umbilical vein endothelial cells (HUVECs) were cultured in extraction liquor of DPMT in different concentrations for 1, 3, and 5 days, then the relative growth rate was calculated with cell counting kit 8 to assess the toxicity in vitro. Live/dead cell staining was used to evaluate the cytocompatibility by seeding HUVECs on the surface of DPMT and co-cultured in vitro for 3 days. For in vivo test, DPMT was subcutaneously implanted at dorsal site of male specific-pathogen free Sprague Dawley rats and harvested after 3, 7, 14, and 28 days. Gross obersvation was done and transverse diameter of remained DPMT in vivo was determined. HE staining and immunohistochemical staining of CD31 were used to assess inflammatory response and new capillary rings formation. ResultsDecellularization of the porcine skeletal muscle tissue by homogenating-milling-detergent serial steps protocol was effective, time-saving, and simple, which could be finished within only 1 day. The decellularizarion and degreasing effect of DPMT was complete. The main component of DPMT was collagen type I and type IV. The DNA content in DPMT was (15.902±1.392) ng/mg dry weight, the total protein content was 68.94% of DPMT dry weight, which was significantly less than those of fresh skeletal muscle tissue[(140.727±10.422) ng/mg and 93.14%] (P<0.05). The microstructure of DPMT was homogeneous and porous. The result of cytocompatibility revealed that the cytotoxicity of DPMT was 0-1 grade, and HUVECs could stably grow on DPMT. In vivo study revealed DPMT could almost maintain its structural integrity at 14 days and it degraded completely at 28 days after implantation. The inflammatory response peaked at 3 days after implantation, and reduced obviously at 7 days. Difference was significant in the number of inflammatory cells between 2 time points (P<0.05). Neovascularization was observed at 7 days after implantation and the number of new vessels increased at 14 days, showing significant difference between at 7 and 14 days (P<0.05). ConclusionThe homogenating-milling-detergent serial-steps protocol is effective, time-saving, and reproducible. The DPMT reveals to be cell and lipid free, with highly preserved protein component. DPMT has good biocompatibility both in vitro and in vivo and may also have potential in promoting neovascularization.
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 Extracellular matrix is one of the focus researches of the adi pose tissue engineering. To investigate the appropriate method to prepare the porcine skeletal muscle acellular matrix and to evaluate the biocompatibility of the matrix. Methods The fresh skeletal muscle tissues were harvested from healthy adult porcine and were sl iced into2-3 mm thick sheets, which were treated by hypotonic-detergent method to remove the cells from the tissue. The matrix was then examined by histology, immunohistochemistry, and scanning electron microscopy. The toxic effects of the matrix were tested by MTT. Human adi pose-derived stem cells (hADSCs) were isolated from adi pose tissue donated by patients with breast cancer, and identified by morphology, flow cytometry, and differentiation abil ity. Then, hADSCs of passage 3 were seeded into the skeletal muscle acellular matrix, and cultured in the medium. The cellular behavior was assessed by calcein-AM (CA) and propidium iodide (PI) staining at 1st, 3rd, 5th, and 7th days after culturing. Results Histology, immunohistochemistry, and scanning electron microscopy showed that the muscle fibers were removed completely with the basement membrane structure; a large number of collagenous matrix presented as regular network, porous-like structure. The cytotoxicity score of the matrix was grade 1, which meant that the matrix had good cytocompatibil ity. The CA and PI staining showed the seeded hADSCs had the potential of spread and prol iferation on the matrix. Conclusion Porcine skeletal muscle acellular matrix has good biocompatibility and a potential to be used as an ideal biomaterial scaffold for adi pose tissue engineering.
Objective To study whether human amniotic fluid colony derived stem cells (hAFCSCs) are involved in regeneration of injured muscles in mice and to investigate the method and feasibil ity of hAFCSCs-based cytotherapy in the treatment of injured muscles. Methods Human second-trimester amniotic fluid was collected through ultrasound-guided amniocentesis, hAFCSCs were isolated from second-trimester amniotic fluid and cultured, and the cells at 6th-8th passages were spared. The mRNA was extracted to identify the stem cell related genes by RT-PCR. The muscular injury model of bilateral tibial is anterior muscle was establ ished by cardiotoxin and X-ray irradiation in 16 Nod/Scid mice (aged 6-8 weeks, and weighing 20-24 g). The hAFCSCs (3.3 × 107/mL, 30 μL) were injected into the right injured tibial is anterior muscles as the experimental group, while the same volume of complete medium (α-MEM containing 15%FBS, 18%Chang B, 2%Chang C, 1% penicill instreptomycin, and 1% L-glutamine) was injected into the left injured tibial is anterior muscles as the control group. At 2 and 4 weeks after cell transplantation, the immunofluorescence staining of tibial is anterior muscles was performed to detect hepatocyte growth factor receptor (c-Met), myogenic regulatory factor (Myf-5), Laminin, Desmin, and human specific nuclear mitotic apparatus protein (NuMa). Results The clone formation was observed at 5-7 days of primary hAFCSCs culture; after 8-10 days, the clones with homogeneous morphology were selected for subculture. Adequate stem cells were available after 6th-8th subculture. RT-PCR analysis showed that hAFCSCs expressed mRNA of the stem cell related genes. The immunofluorescence double-staining showed that NuMa expressed in tibial is anterior muscles of the experimental group and no myogenic phenotype expressed at 2 weeks after cell transplantation, and that single cell co-expressed NuMa and c-Met or Myf-5 at 4 weeks after cell transplantation. In some myofibers, NuMa and Laminin or Desmin were also co-expressed. No NuMa positive hAFCSCs were detected in the control group at 2 and 4 weeks after cell transplantation. Conclusion hAFCSCs can participate in the regeneration of injured mouse muscle.