Oxygen uptake and blood flow in canine skeletal muscle during moderate and severe anemia

The metabolic and cardiovascular adjustments of the whole body and skeletal muscle were studied during moderate and severe acute anemia. In 15 anesthetized dogs, venous outflow from the gastrocnemius-plantaris muscle group was isolated. Cardiac output (QT) muscle blood flow (QM), total body and muscle oxygen uptake (VO2) were determined during a control period, and at 30 and 60 min of either (i) moderate anemia (n = 8) in which the mean hematocrit (Hct) was 25% or (ii) progressive anemia (n = 7) in which the mean Hct values were 25% at 30 min and 16% at 60 min of anemia. Muscle VO2, QT, and QM were increased in both groups at 30 min of anemia. By 60 min, QT and QM declined to preanemic control values in the moderate anemia group; whole body VO2 was maintained at the control level. Arterial oxygen transport was the same in the two groups at both 30 and 60 min of anemia despite the difference in Hct at 60 min. Muscle VO2 showed a further and similar rise in both groups between 30 and 60 min of anemia. These data show that the rise in muscle VO2 during acute anemia was not directly proportional to the degree of the hematocrit reduction. Further, the findings suggest that the muscle VO2 response was related to the decrease in arterial oxygen transport.     

Adrenoceptor regulation of canine skeletal muscle blood flow during carbon monoxide hypoxia.

We questioned whether carbon monoxide hypoxia (COH) would affect peripheral blood flow by neural activation of adrenoceptors to the extent we had found in other forms of hypoxia. We studied this problem in hindlimb muscles of four groups of anesthetized dogs (untreated, alpha 1-blocked, alpha 1 + alpha 2-blocked, and beta 2-blocked). Cardiac output increased, but hindlimb blood flow (QL) and resistance (RL) remained at prehypoxic levels during COH (O2 content reduced 50%) in untreated animals. When activity in the sciatic nerve was reversibly cold blocked, QL doubled and RL decreased 50%. These changes with nerve block were the same during COH, suggesting that neural activity to hindlimb vasculature was not increased by COH. In animals treated with phenoxybenzamine (primarily alpha 1-blocked), RL dropped (approximately 50%) during COH, an indication that catecholamines played a significant role in maintaining tone to skeletal muscle. Animals with both alpha 1 + alpha 2-adrenergic blockade (phenoxybenzamine and yohimbine added) did not survive COH. RL was higher in beta 2-block than in the untreated group during COH, but nerve cooling indicated that beta 2-adrenoceptor vasodilation was accomplished primarily by humoral means. The above findings demonstrated that adrenergic receptors were important in the regulation of QL and RL during COH, but they were not activated by sympathetic nerve stimulation to the limb muscles.     

A delivery-independent blood flow effect on skeletal muscle fatigue

The hypothesis that hyperperfusion decreases muscle fatigue by increasing O2 and substrate delivery to the muscle was tested. Canine gastrocnemius-plantaris in situ preparations were stimulated at 5 Hz for 4 min during a free-flow control period and for 20 min during a pump-perfused experimental period. O2 delivery during these two periods was matched either by decreasing blood flow in animals breathing 100% O2 (high O2/low flow) [experimental-to-control ratio (E/C) = 0.97 + 0.02] or by increasing the blood flow in animals breathing 14% O2 (low O2/high flow) (E/C = 1.01 + 0.01). Plasma flow estimated from hematocrit to approximate substrate delivery was matched in the two contraction periods either by maintaining blood flow at the steady-state level (constant flow) (E/C = 0.98 + 0.10) or by increasing flow in animals with a dextran for 6% of blood volume exchange (dilute/high flow) (E/C = 1.02 + 0.02). E/C for initial developed tension was 1.00 + 0.02. Over 20 min, developed tension decreased 15.0 + 1.1% with low O2/high flow and 16.0 + 1.8% with dilute/high flow. Tension decreased by 28.0 + 3.0 and 27.8 + 1.5% with high O2/low flow and constant flow, respectively. Thus hyperperfusion decreased fatigue by a mechanism independent of increased O2 and substrate delivery.     

Regulation of canine skeletal muscle and hindlimb blood flow in acute anemia

Redistribution of blood flow away from resting skeletal muscles does not occur during anemic hypoxia even when whole body oxygen uptake is not maintained. In the present study, the effects of sympathetic nerve stimulation on both skeletal muscle and hindlimb blood flow were studied prior to and during anemia in anesthetized, paralyzed, and ventilated dogs. In one series (skeletal muscle group, n = 8) paw blood flow was excluded by placing a tourniquet around the ankle; in a second series (hindlimb group, n = 8) no tourniquet was placed at the ankle. The distal end of the transected left sciatic nerve was stimulated to produce a maximal vasoconstrictor response for 4-min intervals at normal hematocrit (Hct.) and at 30 min of anemia (Hct. = 14%). Arterial blood pressure and hindlimb or muscle blood flow were measured; resistance and vascular hindrance were calculated. Nerve stimulation decreased blood flow (p less than 0.05) in the hindlimb and muscle groups at normal Hct. Blood flow rose (p less than 0.05) during anemia and was decreased (p less than 0.05) in both groups during nerve stimulation. However, the blood flow values in both groups during nerve stimulation in anemic animals were greater (p less than 0.05) than those at normal Hct. Hindlimb and muscle vascular resistance fell significantly during anemia and nerve stimulation produced a greater increase in vascular resistance at normal Hct. Vascular hindrance in muscle, but not hindlimb, was less during nerve stimulation in anemia than at normal Hct.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolic adaptations to repeated periods of contraction with reduced blood flow in canine skeletal muscle

Background  

Patients suffering from Intermittent Claudication (IC) experience repeated periods of muscle contraction with low blood flow, throughout the day and this may contribute to the hypothesised skeletal muscle abnormalities. However, no study has evaluated the consequences of intermittent contraction with low blood flow on skeletal muscle tissue. Our aim was to generate this basic physiological data, determining the 'normal' response of healthy skeletal muscle tissue. We specifically proposed that the metabolic responses to contraction would be modified under such circumstances, revealing endogenous strategies engaged to protect the muscle adenine nucleotide pool. Utilizing a canine gracilis model (n = 9), the muscle was stimulated to contract (5 Hz) for three 10 min periods (separated by 10 min rest) under low blood flow conditions (80% reduced), followed by 1 hr recovery and then a fourth period of 10 min stimulation. Muscle biopsies were obtained prior to and following the first and fourth contraction periods. Direct arterio-venous sampling allowed for the calculation of muscle metabolite efflux and oxygen consumption.     

Muscle blood flow during isometric activity and its relation to muscle fatigue

The effect of isometric exercise on blood flow, blood pressure, intramuscular pressure as well as lactate and potassium efflux from exercising muscle was examined. The contractions performed were continuous or intermittent (5 s on, 5 s off) and varied between 5% and 50% maximal voluntary contraction (MVC). A knee-extensor and a hand-grip protocol were used. Evidence is presented that blood flow through the muscle is sufficient during low-level sustained contractions (less than 10% MVC). Despite this muscle fatigue occurs during prolonged contractions. One mechanism for this fatigue may be the disturbance of the potassium homeostasis. Such changes may also play a role in the development of fatigue during intermittent isometric contractions and even more so in the recovery from such exercise. In addition the role of impaired transport of substances within the muscle, due to long-lasting daily oedema formation, is discussed in relation to fatigue in highly repetitive, monotonous jobs.     

A theory of blood flow in skeletal muscle

A theoretical analysis of blood flow in the microcirculation of skeletal muscle is provided. The flow in the microvessels of this organ is quasi steady and has a very low Reynolds number. The blood is non-Newtonian and the blood vessels are distensible with viscoelastic properties. A formulation of the problem is provided using a viscoelastic model for the vessel wall which was recently derived from measurements in the rat spinotrapezius muscle (Skalak and Schmid-Sch?nbein, 1986b). Closed form solutions are derived for several physiologically important cases, such as perfusion at steady state, transient and oscillatory flows. The results show that resting skeletal muscle has, over a wide range of perfusion pressures an almost linear pressure-flow curve. At low flow it exhibits nonlinearities. Vessel distensibility and the non-Newtonian properties of blood both have a strong influence on the shape of the pressure-flow curve. During oscillatory flow the muscle exhibits hysteresis. The theoretical results are in qualitative agreement with experimental observations.     

Regional intramuscular pressure development and fatigue in the canine gastrocnemius muscle in situ

Ameredes, Bill T., and Mark A. Provenzano. Regionalintramuscular pressure development and fatigue in the caninegastrocnemius muscle in situ. J. Appl.Physiol. 83(6): 1867-1876, 1997.Intramuscular pressure (P_IM) was measuredsimultaneously in zones of the medial head of thegastrocnemius-plantaris muscle group (zone I, popliteal origin; zoneII, central; zone III, near calcaneus tendon) to determine regionalmuscle mechanics during isometric tetanic contractions. PeakP_IM averages were 586, 1,676, and993 mmHg deep in zones I, II, and III and 170, 371, and 351 mmHgsuperficially in zones I, II, and III, respectively. During fatigue,loss of P_IM across zones wasgreatest in zone III (81%) and least in zone I (60%) when whole muscle tension loss was 49%. Recovery ofP_IM was greatest in zone III andleast in zone II, achieving 86% and 67% of initial P_IM, respectively, when tensionrecovered to 89%. These data demonstrate that1) regional mechanical performancecan be measured as P_IM within awhole muscle, 2)P_IM is nonuniform within thecanine gastrocnemius-plantaris muscle, being greatest in the deepcentral zone, and 3) fatigue andrecovery of P_IM are dissimilaracross regions. These differences suggest distinct local effects that integrate to determine whole muscle mechanical capacity during andafter intense exercise.

     

Hindlimb skeletal muscle blood flow during sympathetic nerve block before and during acute anemia

The role of sympathetic innervation in the regulation of hindlimb skeletal muscle blood flow (QL) and metabolism was studied prior to and during acute anemia in anesthetized, paralyzed, and ventilated dogs (n = 8). Neural activity in the sciatic nerve was reversibly cold blocked for a 15-min period at control hematocrit (Hct., 51%) and again at 30 min of anemia (Hct., 14%). At the end of each experiment the sciatic nerve was transected and maximally stimulated (frequency, 10 Hz; duration, 2.0 ms). Arterial blood pressure and QL were measured continuously; skeletal muscle vascular hindrance (ZL) and oxygen uptake (VO2) were calculated. When the sciatic nerve was cold blocked prior to and during anemia, ZL decreased to the same absolute value and VO2 remained unchanged. Prior to anemia the mean QL increased (p less than 0.05) from 99 to a peak value of 165 mL.kg-1.min-1 during cold block; QL had returned to control by 10 min of cooling. During anemia, QL increased (p less than 0.05) from 160 to 307 mL.kg-1.min-1 during sympathetic cold block, while maximal sympathetic stimulation decreased QL to 87 mL.kg-1.min-1. QL remained above (p less than 0.05) the anemia control value (160 mL.kg-1.min-1) at 10 min of cooling. Hindrance increased from 0.30 to 0.38 peripheral resistance units/centipoise following the induction of anemia and this was shown to be sympathetically mediated because hindrance was decreased to the same level during cold block prior to and during anemia.     

Alpha-adrenergic receptor-mediated restraint of skeletal muscle blood flow during prolonged exercise.

Sympathetic nervous system restraint of skeletal muscle blood flow during dynamic exercise has been well documented. However, whether sympathetic restraint of muscle blood flow persists and is constant throughout prolonged exercise has not been established. We hypothesized that both alpha1- and alpha2-adrenergic receptors would restrain skeletal muscle blood flow throughout prolonged constant-load exercise and that the restraint would increase as a function of exercise duration. Mongrel dogs were instrumented chronically with transit-time flow probes on the external iliac arteries and an indwelling catheter in a branch of the femoral artery. Flow-adjusted doses of selective alpha1- (prazosin) and alpha2-adrenergic receptor (rauwolscine) antagonists were infused after 5, 30, and 50 min of treadmill exercise at 3 and 6 miles/h. During mild-intensity exercise (3 miles/h), prazosin infusion resulted in a greater (P < 0.05) increase in vascular conductance (VC) after 5 [42% (SD 6)], compared with 30 [28% (SD 6)] and 50 [28% (SD 8)] min of running. In contrast, prazosin resulted in a similar increase in VC after 5 [29% (SD 10)], 30 [24% (SD 9)], and 50 [22% (SD 9)] min of moderate-intensity (6 miles/h) exercise. Rauwolscine infusion resulted in a greater (P < 0.05) increase in VC after 5 [39% (SD 14)] compared with 30 [26% (SD 9)] and 50 [22% (SD 4)] min of exercise at 3 miles/h. Rauwolscine infusion produced a similar increase in VC after 5 [19% (SD 3)], 30 [15% (SD 6)], and 50 [16% (SD 2)] min of exercise at 6 miles/h. These results suggest that the ability of alpha1- and alpha2-adrenergic receptors to produce vasoconstriction and restrain blood flow to active muscles may be influenced by both the intensity and duration of exercise.     

低氧习服大鼠骨骼肌毛细血管密度和血流供应的变化特点

目的：观察大鼠在低氧习服过程中,骨骼肌毛细血管密度和血流供应的变化规律。方法：大鼠在模拟海拔5000m低氧5、15和30d后,用肌球蛋白ATP酶（mATPase)组织化学方法显示骨骼肌Ⅰ、Ⅱ型纤维和毛细血管并进行图像分析;用放射性微球法测定骨骼肌血流量。结果：低氧5d组大鼠骨骼肌纤维即出现明显萎缩,15d和30d组大鼠毛细血管密度显著增高,但单位面积内毛细血管数/肌纤维数（C/F）的比值无明显变化。在所观测的时间内,各组大鼠骨骼肌血流量未见明显变化。结论：大鼠在低氧习服过程中,毛细血管并未发生真正的增生,而由于骨骼肌纤维出现萎缩,使毛细敌国管数目相对增多。     

Fatigue of mammalian skeletal muscle in situ during repetitive contractions

When the gastrocnemius-plantaris muscle group of the dog is stimulated to contract repetitively for 30 min at frequencies high enough to generate VO2 levels at or near VO2 max, VO2 and mechanical performance decline with time. This decline with time is fatigue, and it occurs during twitch and tetanic contractions that are isometric or isotonic. There is oxidation of the mitochondrial electron transport system, and net lactic acid output is transient, ending after 20 min of contractions. Energy and substrate stores and intracellular pH are only moderately changed and do not appear to be well correlated with the development of fatigue. Blood flow through the muscle is well correlated with the development of fatigue and decreases as fatigue develops in a manner that keeps the blood arteriovenous O2 difference nearly constant. Changing the blood flow alters the rate of development of fatigue as an inverse relation, and this response does not appear to be related to changes in the availability of O2 in the mitochondria. Nerve-muscle transmission of excitation does not seem to be involved in the development of fatigue. Excitation-contraction coupling is well accepted to be at least part of the genesis of the development of fatigue. Metabolic limitations and control may affect excitation-contraction coupling by one or more changes in the internal environment. Blood flow affects this system by an unknown mechanism. The role of blood flow in fatigue deserves further consideration.