Effects of hypothermia on the development of ischemic lesions of skeletal muscles in rats]

The influence of hypothermia on the development of the ischemic disorders was studied using allotransplantation of the rat skeletal muscle (m. lumbricalis) to the anterior chamber of the eye after different period of ischemia. The morphological and immunohistochemical (monoclonal antibodies to heavy chain of the fast myosin, PAP-method) data were found confirming that hypothermia (2-4 degrees C) prolongs the period of the ischemic disorders first appearance by 5 h (from 6 to 11 h) if compared with development of ischemia in the muscle at 21-23 degrees C.     

Quantitative histoenzymological characteristics of changes in the red and white fibers of skeletal muscle tissue of the extremities in temporary ischemia and postischemic recirculation

Histoenzymological study of red and white fibers of limb skeletal muscles was performed in dogs with experimental acute occlusion of aorta trifurcation during ischemic and postischemic periods. A dramatic fall in the activity of aerobic enzymes was recorded in all observation periods (3, 6, 9 and 12 h). LDH activity rose considerably during short-term and descended slowly in prolonged ischemia. Red muscle fibers showed more substantial disorders in metabolism than white fibers. Recirculation after 6, 9 and 12 h of ischemia led to an appreciable decrease in the metabolic rate in muscle tissue. Irreversibility of metabolic alterations in acute ischemia lasting over 6 h may attest to the failure of the compensatory-adaptive mechanisms.     

Ischemia reperfusion injury of the skeletal muscle after selective deafferentation

The present study analyzes the effect of selective deafferentation on the reperfusion injury of the skeletal muscle when nociceptive sensory fibers of the left sciatic nerve are selectively damaged by capsaicin pretreatment in a rat model following tourniquet ischemia (ISC) applied for 30 min, 1 h, and 2 h on the left hind limb. The isometric tetanic contractile force of the extensor digitorum longus (EDL) muscle was measured after 1 h, and 1, 3, or 7 days of reperfusion. Contractile force of the damaged muscle was compared to the intact contralateral muscle. In another group, ISC was used without capsaicin pre-treatment. After 30 min of ISC, there was no difference between deafferented and non-pretreated groups. Following 1 h ISC, with the exception of 1 h reperfusion, the non-pretreated group produced stronger contractions than the deafferented group. After 2 h ISC, the contractile force of the deafferented muscle was significantly stronger compared to the non-deafferented muscle force at all reperfusion times. In conclusions, it was found that the absence of peptidergic sensory fibers after long-lasting (2 h) ischemia is beneficial in reperfusion injury, whereas the absence of vasodilator peptides has unfavorable effects if tissue damage is milder (after 1 h ischemia).     

Morphological characteristics of the changes in the skeletal muscle tissue in acute experimental ischemia of the extremities

A comprehensive morphological study of the ischemic skeletal muscles of the limbs was performed in experiments on dogs. Ischemia of the muscle tissue was induced by artificial embolic occlusion of the terminal part of the aorta. A quantitative functional and morphological study revealed serious disturbances in metabolism of the skeletal muscle that was subjected to a 6-hour ischemia. Depression of aerobic metabolism, ineffectiveness of anaerobic glycolysis (a spare pathway of the synthesis of macroergic substances), a dramatic lowering of ATPase activity, and activation of acid phosphatase in experiments of such a duration are important signs of a probably compromised adaptation process and irreversibility of the lesions in the tissue. The data should be taken into consideration in determining the optimal periods of the blood flow recovery in the limbs. Morphological changes in muscle fibers under ischemia progress with an increase in the experiment duration (up to 9 and 12 h). An important morphological sign of ischemia is a disturbed typification of muscle fibers.     

Capillary and fiber size interrelationships in regenerating rat soleus muscle after ischemia: a quantitative study.

The present study examines the influence of ischemia on the muscle fibers and capillarization in rats. Muscle ischemia was achieved by a pneumatic tourniquet at a pressure of 300 mm Hg for 2, 4 and 6 h (groups I, II and III, respectively) to the right hindlimb above the knee. Numerous regenerative fibers were seen at 4 and, especially, 8 and 12 days after ischemia in groups II and III. The quantitative data revealed a significant decrease in the size of muscle fibers (regenerative fibers) in ischemic skeletal muscle, with a concomitant increase in fiber density. The capillary to fiber ratio shows a decrease at 4, 8 and 12 days after ischemia in the three experimental groups: in group I because of a decrease in capillary density; in groups II and III because of an increase in fiber density with respect to capillary density.     

Changes in the acid phosphatase activity in skeletal muscles in temporary acute ischemia of the extremities and in early postischemic recirculation

Acid phosphatase (APh) activity has been experimentally studied on 69 dogs in the musculus soleus during ischemic and postischemic periods. Absence of an essential APh activation demonstrates a complete adaptation and stabilization of the intracellular mechanisms of homeostasis under an acute 3 hours' ischemia. Under a prolonged (6, 9, 12 h) ischemia APh activity in sarcoplasm of the muscle fibers increases considerably. This is, probably, one of the signs demonstrating structural-metabolic disadaptation and beginning of irreversible lesions. The data obtained make it possible to conclude that it is necessary to perform operative restoration of the blood stream in the extremities at early stages of ischemia.     

Morphological characteristics of changes in the skeletal muscle tissue of the extremities after experimental post-ischemic recirculation

The canine ischemic muscle tissue was subjected to a comprehensive morphological study after the recovery of the blood flow in the limbs for 2 hours. The effectiveness of of the recovery of the blood flow after the 3-hour ischemia was supported in acute experimental occlusion of the artery. The blood flow recovery after 6 hours of ischemia was associated with appreciable structural and metabolic abnormalities in the skeletal muscle fibers. These abnormalities were more demonstrable during recirculation after 9 and 12 hours of ischemia. No morphological criteria that might indicate whether the ischemic damage to the skeletal muscle is reversible or irreversible were defined. A comprehensive morphological study with an assay of structural and metabolic alterations is required instead.     

The fine structural localization of acetylcholinesterase in the muscle spindle of the rat

Summary Muscle spindles from lumbricalis muscles of the rat were incubated for acetylcholinesterase with a modified thiocholine-method of Lewis and Shute and examined by light and electron microscopy.All types of motor nerve ending showed heavy deposits of reaction product in the synaptic cleft. The underlying sarcoplasmic reticulum, transverse tubular system, and, when present, the envelope of sole plate nuclei were also stained.In the sensory region, the reaction was negative in the interface between the plasma membranes of the primary sensory terminal and muscle. One of two secondary sensory endings identified showed distinct reaction product in the cleft; the other secondary sensory ending showed no such reaction.Precipitates were present on the sarcolemma of the intrafusal muscle fibers in the polar and adjacent myotube regions, but not at the spindle equator. Extrafusal and intrafusal myelinated -nerve fibers and preterminal motor axons showed staining of the axolemma. Fibers with thick myelin sheaths and preterminal sensory axons were free of acetylcholinesterase activity, as were the unmyelinated nerve fibers.We wish to thank Mrs. D. Schilling and Mrs. Ch. Beyer for technical assistanc     

Morpho-functional changes in the muscles of the limbs and their microcirculatory bed in acute ischemia

On 26 mature dogs in a chronic experiment the character of compensatory-adaptive changes in muscles and their blood capillaries have been studied in dynamics of an acute ischemia of the extremity and at some stages of recirculation. After strangulation for two hours, thanks to joining in the compensatory-adaptive mechanisms, certain morphofunctional changes in the extremity tissues are revealed. As the duration of hypoxia increases (6-9 h), the destructive changes in the tissues become more severe. They are inherent in an acute hypoxia and accompanied with disaggregation and hydratation of cell membranes of endotheliocytes, with formation of vesicles and spherules, with increasing microclasmatosis, formation of myelin-like bodies, with destructive changes of organelles, with destruction of sarcoplasmic reticulum, with focal discoid necrosis, myocytolysis and sequestration of autolysis altered groups of muscle fibers. The data obtained serves as a base for elaboration of a pathogenically adequate surgical treatment of severe forms of an acute ischemia of extremities.     

Is transferrin a neurotrophic factor controlling myosin composition of the skeletal muscle?]

After transferrin injection to the slow m. soleus of guinea pig no immunohistochemical changes in myosin composition with monoclonal antibodies (AB) against fast myosin heavy chain (HCf) have been found. All muscles fibers in intact and experimental animals were identified as slow ones (type I of muscle fibers). After colchicine treatment of nerve trunk innervating slow muscle, some muscle fibers reacting with monoclonal AB against myosin HCf have been found. However, after colchicine treatment of nerve trunk and transferrin injection also some muscle fibers in slow muscle reacting with monoclonal AB against myosin HCf have been found. In appears that transferrin probably can not be the factor of neurotrophic control for myosin composition in skeletal muscle.     

Dependence of skeletal muscle fatigue on the membrane polarization of the different types of muscle fibers in tourniquet shock

Fatigue, polarization level and excitability of striated muscle fibers from ischemia zone were studied on experimental rats under the tourniquet shock. It was established that violation-mediated contraction and fatigue of skeletal muscle was associated with a decrease in a number of muscle fibers with high level of MPP. The article discussed the mechanisms of fatigue and depolarization of muscle fibres in tourniquet shock.     

Effects of acute ischemia,early extrabeats and propafenone on complex activation patterns in intact and ischemic canine hearts

Although, sodium channel blockers have the ability to suppress nonsustained ventricular arrhythmias, an excessive drug-associated arrhythmic death rate has been reported in patients with coronary heart disease (CHD). Sodium channel blockers should prevent initiation of reentry activation by reducing directional differences in cardiac conduction (anisotropy). However, in vitro data demonstrated, that reduction of membrane excitability, e.g. by lowering the inward Na+ current, increases the risk for conduction failure and associated reentry arrhythmias. In 11 dogs the effects of myocardial ischemia, premature epicardial stimulation (PES) and propafenone on anisotropic conduction properties were tested using three-dimensional mapping techniques. The epicardial (longitudinal and transverse to fiber orientation) and transmural (oblique and straight) spread of activation was reconstructed during constant and PES. At baseline, conduction velocities (CV) were higher along (1.20 +/- 0.41 m/s) than across (0.91 +/- 0.19 m/s; p < 0.05) epicardial muscle fibers as well as along oblique (1.77 +/- 0.75 m/s) compared to straight (0.39 +/- 0.09 m/s, p < 0.05) transmural pathways. Acute ischemia did not significantly reduce tissue anisotropy. PES and additional administration of propafenone epicardially eliminated and transmurally profoundly reduced tissue anisotropy (longitudinal 0.58 +/- 0.09 m/s, transverse 0.69 +/- 0.08 m/s, oblique 0.69 +/- 0.28 m/s, straight 0.27 +/- 0.07 m/s). However, reduced anisotropy was associated with a higher probability for conduction block along myocardial fibers in the epicardium and along oblique transmural pathways. Our data show, that propafenone exhibits both potential pro- and antiarrhythmic effects in dogs with acute myocardial ischemia. These results possibly provide more insights in mechanisms underlying the excessive drug-associated arrhythmic death rate in patients with CHD.     

Cardiac and skeletal muscle adaptations to voluntary wheel running in the mouse.

In this paper, we describe the effects of voluntary cage wheel exercise on mouse cardiac and skeletal muscle. Inbred male C57/Bl6 mice (age 6-8 wk; n = 12) [corrected] ran an average of 4.3 h/24 h, for an average distance of 6.8 km/24 h, and at an average speed of 26.4 m/min. A significant increase in the ratio of heart mass to body mass (mg/g) was evident after 2 wk of voluntary exercise, and cardiac atrial natriuretic factor and brain natriuretic peptide mRNA levels were significantly increased in the ventricles after 4 wk of voluntary exercise. A significant increase in the percentage of fibers expressing myosin heavy chain (MHC) IIa was observed in both the gastrocnemius and the tibialis anterior (TA) by 2 wk, and a significant decrease in the percentage of fibers expressing IIb MHC was evident in both muscles after 4 wk of voluntary exercise. The TA muscle showed a greater increase in the percentage of IIa MHC-expressing fibers than did the gastrocnemius muscle (40 and 20%, respectively, compared with 10% for nonexercised). Finally, the number of oxidative fibers as revealed by NADH-tetrazolium reductase histochemical staining was increased in the TA but not the gastrocnemius after 4 wk of voluntary exercise. All results are relative to age-matched mice housed without access to running wheels. Together these data demonstrate that voluntary exercise in mice results in cardiac and skeletal muscle adaptations consistent with endurance exercise.     

Exercise alters the profile of phospholipid molecular species in rat skeletal muscle.

We have determined the effect of two exercise-training intensities on the phospholipid profile of both glycolytic and oxidative muscle fibers of female Sprague-Dawley rats using electrospray-ionization mass spectrometry. Animals were randomly divided into three training groups: control, which performed no exercise training; low-intensity (8 m/min) treadmill running; or high-intensity (28 m/min) treadmill running. All exercise-trained rats ran 1,000 m/session for 4 days/wk for 4 wk and were killed 48 h after the last training bout. Exercise training was found to produce no novel phospholipid species but was associated with significant alterations in the relative abundance of a number of phospholipid molecular species. These changes were more prominent in glycolytic (white vastus lateralis) than in oxidative (red vastus lateralis) muscle fibers. The largest observed change was a decrease of approximately 20% in the abundance of 1-stearoyl-2-docosahexaenoyl-phosphatidylethanolamine [PE(18:0/22:6); P < 0.001] ions in both the low- and high-intensity training regimes in glycolytic fibers. Increases in the abundance of 1-oleoyl-2-linoleoyl phopshatidic acid [PA(18:1/18:2); P < 0.001] and 1-alkenylpalmitoyl-2-linoleoyl phosphatidylethanolamine [plasmenyl PE (16:0/18:2); P < 0.005] ions were also observed for both training regimes in glycolytic fibers. We conclude that exercise training results in a remodeling of phospholipids in rat skeletal muscle. Even though little is known about the physiological or pathophysiological role of specific phospholipid molecular species in skeletal muscle, it is likely that this remodeling will have an impact on a range of cellular functions.     

Denervated muscle fibers explain the deficit in specific force following reinnervation of the rat extensor digitorum longus muscle

The authors tested the hypothesis that, after denervation and reinnervation of skeletal muscle, observed deficits in specific force can be completely attributed to the presence of denervated muscle fibers. The peroneal nerve innervating the extensor digitorum longus muscle in rats was sectioned and the distal stump was coapted to the proximal stump, allowing either a large number of motor axons (nonreduced, n = 12) or a drastically reduced number of axons access to the distal nerve stump (drastically reduced, n = 18). A control group of rats underwent exposure of the peroneal nerve, without transection, followed by wound closure (control, n = 9). Four months after the operation, the maximum tetanic isometric force (Fo) of the extensor digitorum longus muscle was measured in situ and the specific force (sFo) was calculated. Cross-sections of the muscles were labeled for neural cell adhesion molecule (NCAM) protein to distinguish between innervated and denervated muscle fibers. Compared with extensor digitorum longus muscles from rats in the control (295 +/- 11 kN/m2) and nonreduced (276 +/- 12 kN/m2) groups, sFo of the extensor digitorum longus muscles from animals in the drastically reduced group was decreased (227 +/- 15 kN/m2, p < 0.05). The percentage of denervated muscle fibers in the extensor digitorum longus muscles from animals in the drastically reduced group (18 +/- 3 percent) was significantly higher than in the control (3 +/- 1 percent) group, but not compared with the nonreduced (9 +/- 2 percent) group. After exclusion of the denervated fibers, sFo did not differ between extensor digitorum longus muscles from animals in the drastically reduced (270 +/- 20 kN/m2), nonreduced (301 +/- 13 kN/m2), or control (303 +/- 10 kN/m2) groups. The authors conclude that, under circumstances of denervation and rapid reinnervation, the decrease in sFo of muscle can be attributed to the presence of denervated muscle fibers.     

In vitro formation of neuromuscular junctions between adult Rana muscle fibres and embryonic Xenopus neurons

Adult muscle fibres of the frog Rana temporaria were cultured with neurons from embryos of the frog Xenopus laevis. Electron microscopical and electro-physiological examination of the cultures showed that hetero-specific (Xenopus-Rana) neuromuscular junctions were formed in vitro. Nerve processes, without any Schwann cell covering, made contacts anywhere along a muscle fibre, and the junctions resembled those seen during early regeneration of neuromuscular synapses in situ. Functional contacts, as inferred by the presence of spontaneous miniature endplate potentials, or currents, were more common if the muscle fibres were denervated prior to culturing with neurons. Miniature endplate currents (m.e.p.cs) had a skewed amplitude distribution, with many small events lost in the recording noise, and their mean amplitude was much smaller than that of m.e.p.cs in the original lumbricalis muscle. The time constant of decay of m.e.p.cs in the hetero-specific junctions formed in vitro was several times longer than the decay of m.e.p.cs in the original muscle. Analysis of membrane current noise elicited by ionophoretically applied acetylcholine (ACh) suggests that the slower decay of m.e.p.cs in the junctions formed in vitro is due to a prolonged lifetime of the channels opened by ACh and to repetitive activation of ACh-receptors, which becomes possible because of a comparative lack of cholinesterase in the junctions.     

Ultrastructural characteristics of rat neuromuscular junctions after physical load

It is interesting to ascertain the adaptive reaction of rat neuromuscular junctions (NMJ) of muscle fibers of different types to a chronic physical load. We examined ultrastructural changes in NMJ following both static load (pre- and postnatal ontogenesis of Wistar rats till a 2 month age took place under a constant rotation on the centrifuge at hypergravity conditions 2G), and after three kinds of dynamic loads (1/run on treadmill with a speed 35 m/min for 6 wks, 10-60 min/day; 2/swimmings, each 10 hrs/day for 10 days; 3/strength exercises on a vertical treadmill with load for 6 wks). Differences in NMJ reaction of muscle fibers of the same type to various loads were established. A low secretory activity of axonal terminals of type I muscle fibers of m. soleus was shown after the static load. The dynamic load (run) is accompanied with a high secretory activity of axonal terminals in m. soleus type I muscle fibers and of some axonal terminals of m. quadriceps femoris IIB type muscle fibers after strength exercises; the secretory activity of axonal terminals of m. quadriceps femoris IIA and IIB types muscle fibers is expressed in a lesser degree after swimming. The NMJ ultrastructure remodelling (terminal renewal) of type I muscle fibers of the 2 month old control rats increases after static and dynamic (run) loads. Some correlations between different kinds of physical load, muscle fiber type and the degree of NMJ ultrastructure transformation have been shown.     

大鼠肢体缺血/再灌注后多器官水肿及丹参的预防作用

目的:探讨大鼠肢体缺血/再灌注(LI/R)导致的多器官水肿及丹参的防治作用。方法:Wistar大鼠24只随机分为3组(n=8):对照组(C组)、缺血/再灌注组(I/R组)和丹参预处理组(SM组)。以止血带法制作大鼠肢体缺血/再灌注模型,SM组在再灌注前30 min经尾静脉推注丹参注射液5 ml/kg。准确留取每只动物的心、肝、肾、肺、脑、肠及骨骼肌组织各1 g,恒温烘干后称其干重并计算各组织的湿干重比值(W/D)。采用ELISA法测定血清白细胞介素1(IL-1)、白细胞介素6(IL-6)、肿瘤坏死因子α(TNFα-)含量;采用生物化学方法测定超氧化物歧化酶(SOD)活性及丙二醛(MDA)含量。光镜下观察骨骼肌组织的形态学变化。结果:LI/R后各组织W/D均增加(P<0.05,P<0.01),血浆SOD活性降低而MDA含量增加(P<0.05,P<0.01),血清IL-1、IL-6、TNFα-水平均升高(P<0.05,P<0.01),骨骼肌组织镜下可见炎细胞浸润、肌纤维间隙增宽等病理改变。而SM组与单纯再灌注组比较,血清炎症因子水平下降,氧化损伤程度减轻,镜下组织形态学变化有所改善。结论:大鼠肢体缺血/再灌注可导致多器官水肿,丹参可通过抑制炎症反应、抗氧化等途径在一定程度上预防肢体缺血/再灌注后多器官的水肿。     

Can angiogenesis induced by chronic electrical stimulation enhance latissimus dorsi muscle flap survival for application in cardiomyoplasty?

In cardiomyoplasty, the latissimus dorsi muscle is lifted on its primary neurovascular pedicle and wrapped around a failing heart. After 2 weeks, it is trained for 6 weeks using chronic electrical stimulation, which transforms the latissimus dorsi muscle into a fatigue-resistant muscle that can contract in synchrony with the beating heart without tiring. In over 600 cardiomyoplasty procedures performed clinically to date, the outcomes have varied. Given the data obtained in animal experiments, the authors believe these variable outcomes are attributable to distal latissimus dorsi muscle flap necrosis. The aim of the present study was to investigate whether the chronic electrical stimulation training used to transform the latissimus dorsi muscle into fatigue-resistant muscle could also be used to induce angiogenesis, increase perfusion, and thus protect the latissimus dorsi muscle flap from distal necrosis. After 14 days of chronic electrical stimulation (10 Hz, 330 microsec, 4 to 6 V continuous, 8 hours/day) of the right or left latissimus dorsi muscle (randomly selected) in 11 rats, both latissimus dorsi muscles were lifted on their thoracodorsal pedicles and returned to their anatomical beds. Four days later, the resulting amount of distal flap necrosis was measured. Also, at predetermined time intervals throughout the experiment, muscle surface blood perfusion was measured using scanning laser Doppler flowmetry. Finally, latissimus dorsi muscles were excised in four additional stimulated rats, to measure angiogenesis (capillary-to-fiber ratio), fiber type (oxidative or glycolytic), and fiber size using histologic specimens. The authors found that chronic electrical stimulation (1) significantly (p < 0.05) increased angiogenesis (mean capillary-to-fiber ratio) by 82 percent and blood perfusion by 36 percent; (2) did not reduce the amount of distal flap necrosis compared with nonchronic electrical stimulation controls (29 +/- 5.3 percent versus 26.6 +/- 5.1 percent); (3) completely transformed the normally mixed (oxidative and glycolytic) fiber type distribution into all oxidative fibers; and (4) reduced fiber size in the proximal and middle but not in the distal segments of the flap. Despite the significant increase in angiogenesis and blood perfusion, distal latissimus dorsi muscle flap necrosis did not decrease. This might be because of three reasons: first, the change in muscle metabolism from anaerobic to aerobic may have rendered the muscle fibers more susceptible to ischemia. Second, because of the larger diameter of the distal fibers in normal and stimulated latissimus dorsi muscle, the diffusion distance for oxygen to the center of the distal fibers is increased, making fiber survival more difficult. Third, even though angiogenesis was significantly increased in the flap, cutting all but the single vascular pedicle resulted in the newly formed capillaries not receiving enough blood to provide nourishment to the distal latissimus dorsi muscle. The authors' findings indicate that chronic electrical stimulation as tested in these experiments could not be used to prevent distal latissimus dorsi muscle flap ischemia and necrosis in cardiomyoplasty.     

Fiber composition of the distal accessory flexor muscle in several decapod crustaceans

The fiber composition of the distal accessory flexor muscle (DAFM) and the branching pattern of its excitor axon were compared in several species of crabs, in the lobster and the crayfish. The muscle is composed exclusively of long sarcomere (> 6 μm) fibers and therefore of the slow type. In all the crab species, except one, there is a distal to proximal gradient of fibers with increasing sarcomere lengths; this gradient is reverse in lobsters and crayfish. A proximal to distal gradient of increasing fiber diameters occurs in the DAFM of all crab species but not in the lobster and crayfish, in which all the fibers are approximately equal in diameter. The single excitatory axon traverses the width of the DAFM and gives off primary branches on either side in the lobster and crayfish but on only one side in crabs. The hypothesis that the axonal branching pattern may govern the regional distribution of fibers with differing sarcomere lengths in proposed.