肌酸对游泳大鼠乳酸、糖原含量和乳酸脱氢酶活性的影响

为探讨肌酸对提高大鼠运动能力的作用 ,观察了肌酸对游泳大鼠血清、心肌和骨骼肌乳酸、糖原含量和乳酸脱氢酶 (LDH)活性的影响。实验用雄性wistar大鼠 2 4只 ,随机分为正常组、游泳对照组和游泳补充肌酸组。两个游泳组每天游泳训练 1h,9天后 ,游泳 4h ,测定血清、心肌和骨骼肌乳酸水平 ,测定血清和骨骼肌乳酸脱氢酶活性以及心肌与骨骼肌糖原含量。结果显示 :肌酸可抑制游泳运动后大鼠血清、心肌和骨骼肌乳酸浓度以及血清LDH活性的升高幅度 ,抑制心肌和骨骼肌糖原含量及骨骼肌LDH活力的下降。以上结果表明 ,肌酸可改善运动后机体乳酸和糖原的代谢 ,降低运动性疲劳 ,提高大鼠的运动能力     

牛磺酸的生物学效应与运动能力的研究进展

牛磺酸是人和动物的重要营养素,具有多种生物学作用,能清除自由基、对抗脂质过氧化、调节渗透压、维持体液平衡和胞内钙离子稳态、参与糖和氨基酸的代谢。在体育运动中,牛磺酸能显著提高运动能力。本文对牛磺酸在人体内的分布和代谢进行介绍,并对牛磺酸在人体内的功能及其与运动能力的关系进行概述。     

脑型肌酸激酶促进胶质瘤干细胞增殖

目的 探讨脑型肌酸激酶（brain-type creatine kinase, CKB）对胶质瘤干细胞（glioma stem cells, GSCs）代谢和增殖能力的影响。方法 应用代谢组学数据分析CKB的代谢底物肌酸在胶质瘤静脉与足背静脉血液样本中的含量差异;结合胶质母细胞瘤单细胞转录组测序数据分析、Western blot、qRT-PCR和免疫荧光染色等技术检测CKB在GSCs与非干性肿瘤细胞（non-stem tumor cells, NSTCs）中的表达差异;通过CCK-8实验检测敲低CKB或抑制剂环肌酸处理后GSCs和NSTCs的细胞增殖能力及磷酸肌酸对CKB敲低GSCs的细胞活力挽救能力。结果 肌酸在胶质瘤静脉较足背静脉血液样本中的含量上升;在GSCs中CKB表达显著高于NSTCs;CKB敲低或环肌酸处理显著抑制GSCs的增殖能力,而对NSTCs影响较小;磷酸肌酸能在一定程度上挽救CKB敲低导致的GSCs活力下降。结论 CKB在GSCs中表达上调,通过肌酸激酶/磷酸肌酸系统促进GSCs的增殖。     

运动训练对心肌梗死后心脏的保护作用

运动训练是心肌梗死后康复训练的重要方式之一。现有研究表明,适宜的运动训练不仅可以提高心肌梗死后心脏的舒缩功能,而且可以减轻梗死后的心室重塑。运动训练对心肌梗死后心脏的保护机制主要涉及改善冠脉循环、缓解线粒体代谢紊乱、提高细胞的抗氧化应激能力、降低心脏交感神经兴奋性、降低自噬小体的数量和维持心肌细胞钙稳态等方面。本文介绍运动训练对心肌梗死后心脏的保护作用及其机制的研究进展。     

微生态调节剂对大负荷运动下肠道微生物群调节作用的研究进展

大负荷运动不仅会使运动系统如骨骼、骨骼肌等受到影响，还可导致消化系统出现功能障碍，包括肠道微生物群失调、微生物多样性降低、肠屏障功能损伤等问题。而益生菌、益生元等微生态调节剂则可以对肠屏障功能、肠道微生物群等起到积极的调节作用，降低大负荷运动所引起的不良影响，提高恢复能力，进而提高运动表现。这提示微生态调节剂作为营养补剂在运动营养领域中具有重要的应用前景。该文对大负荷运动影响肠道微生物群及其作用机制进行介绍，并梳理益生菌、益生元等微生态调节剂对肠道微生物群的调节作用。     

应用振动训练可修复小鼠肌肉疲劳损伤

为探讨不同强度全身振动训练对于生物体运动表现、运动疲劳以及生理生化反应的影响。本研究使用4周大雄性C57BL/6J小鼠为模型,随机分作3组,每组8只动物:无振动训练对照组(sedentary control,SC);相对较低强度振动训练组(5.6 Hz/0.13 g; relative low-intensity vibration, LV);相对较高强度振动训练组(13 Hz/0.68 g; relative high-intensity vibration, HV)。振动训练以每天振动15 min,每周5次,为期4周,随后进行各项测试包括:前肢抓力、衰竭性耐力运动测验、疲劳生化指标分析、临床血液生化检测以及病理组织切片观察。数据以单因素方差进行分析,并以Duncan's test检验不同的组间是否存在显著差异。两组接受振动训练介入的小鼠比对照组,具有显著提升肌力和衰竭性耐力运动的时间。在疲劳与肌肉损伤相关生化指标部分,振动训练具有明显降低单次运动测试后血氨与血乳酸浓度以及肌酸激酶活性上升的作用。在临床血液生化方面,4周振动训练显著降低草醋酸转胺酶、麸丙酮酸转胺酶与肌酸激酶活性,以及尿素氮浓度。本研究证实振动训练4周的连续介入下,具有提升运动表现与抗疲劳的作用,而且不会造成健康小鼠在生理生化以及病理上的副作用。在提供一般健康成人的运动训练指导上,全身振动训练具有健康促进的应用性。     

慢性疲劳综合征中学生运动前后尿液差异代谢物的比较

目的：探讨慢性疲劳综合征（CFS）中学生运动前后尿液的差异代谢物及其代谢通路特征,阐述慢性疲劳综合征的代谢机制。方法：依据美国疾病预防控制中心关于CFS的筛选标准,选取8名17~19岁男性CFS中学生作为受试对象,同时选择来自同一学校的8名同龄、同性别健康中学生作为对照组。受试者进行一次改良的哈佛台阶运动（上下台阶30次/min,持续3 min）,采集运动前后的尿液,以液相-质谱联用（LC-MS）法检测其差异代谢物;采用多维统计法对所检测到的代谢物进行主成分分析（PAC）和正交偏最小二乘判别分析（OPLS-DA）;通过MetPA数据库分析与差异代谢物相关的代谢通路。结果：与对照组相比较,运动前CFS组筛选出肌酸、吲哚乙醛、植物鞘氨醇和焦谷氨酸4个差异代谢物,其含量均显著下降（P<0.05或P<0.01）;运动后CFS组检测出11个差异代谢物,依次是壬二酸、甲基腺苷、乙酰肉碱、癸酸、皮质酮、肌酸、左炔诺孕酮、泛酸、焦谷氨酸、黄嘌呤核苷和黄尿酸,其中除甲基腺苷和肌酸比对照组显著升高（P<0.05）外,其他9个差异代谢物均较对照组显著降低（P<0.05或P<0.01）。将上述15个差异代谢物分别输入MetPA数据库进行代谢通路权重得分分析,结果显示,运动前CFS组只检测出精氨酸-脯氨酸代谢通路紊乱,标记代谢物为肌酸;而运动后检测出精氨酸-脯氨酸代谢、泛酸与辅酶A生物合成、类固醇激素生物合成3条代谢通路存在障碍,标记代谢物依次是：肌酸、泛酸和皮质酮。结论：运动干预前,CFS中学生的精氨酸-脯氨酸代谢通路紊乱被检出;施加运动后,又检测出其类固醇激素生物合成代谢通路与泛酸和辅酶A代谢通路也存在代谢紊乱情况。     

视知觉学习对于识别动态随机点立体图深度运动方向的作用

立体视觉不仅指对静态深度信息的感知,也包括对物体在三维空间中的运动方向的判断。本研究记录了人眼对于动态随机点图运动方向的辨别能力以及视觉训练在提高对动态信息分辨能力的作用。实验结果表明,对于没有任何相关经验的视力正常的受试者,很难分辨出动态随机点的深度运动方向,而视觉训练可以大大提高人眼对物体深度运动方向判断的敏感度。此外,这种视觉训练所达到的效果具有较长时间的持续性（至少6个月）。这种通过视觉训练提高受试者对立体运动信息的敏感度的方式为立体视觉相关的实验和研究提供了新的视角。     

视知觉学习对于识别动态随机点立体图深度运动方向的作用（英文）

立体视觉不仅指对静态深度信息的感知,也包括对物体在三维空间中的运动方向的判断.本研究记录了人眼对于动态随机点图运动方向的辨别能力以及视觉训练在提高对动态信息分辨能力的作用.实验结果表明,对于没有任何相关经验的视力正常的受试者,很难分辨出动态随机点的深度运动方向,而视觉训练可以大大提高人眼对物体深度运动方向判断的敏感度.此外,这种视觉训练所达到的效果具有较长时间的持续性(至少6个月).这种通过视觉训练提高受试者对立体运动信息敏感度的方式,为立体视觉相关的实验和研究提供了新的视角.     

运动想象的脑机制及其在运动功能康复中应用的研究进展

运动想象对大脑相关功能有明显的改善作用,目前正在大量应用于运动训练和康复治疗领域.近年来随着诸如功能磁共振等成像工具的出现,神经成像的复杂程度得到了不断提高,从而推动了人们对运动想象的脑机制尤其是涉及多脑区之间的协同作用机制的认识逐步深入.针对运动想象的多脑区之间相互协作机制及运动想象在运动功能康复中的应用作了详细介绍.     

最大等速离心运动诱发肌肉损伤程度与肌酸激酶水平的关系

为探讨人体进行最大等速离心运动(ECC)诱发血液肌酸激酶(CK)水平变化、血清肌酸激酶水平与肌肉损伤(EIMD)的关系,本研究筛选出150名"缺乏运动"的健康大学生为受试者,进行血样采集,进行前测包括血清肌酸激酶(CK)、最大等长肌力(MVC)、肘关节活动角度(ROM)、上臂围(CIR)、肌肉感受(VAS)。受试者进行5组×12次最大等速离心运动,运动后恢复期,将全部受试者血清肌酸激酶值进行排序:血清肌酸激酶值最高和最低20%样本,高肌酸激酶水平组(HCK组)和低肌酸激酶水平组(low LCK组),利用SPSS18.0统计学软件,以方差分析和多元回归分析进行统计分析。本研究发现全部受试者、高肌酸激酶水平组、低肌酸激酶水平组在最大等速离心运动后各评估指标均显著高于比前测结果,p<0.05。全部受试者、高肌酸激酶水平组受试者在最大等速离心运动后各指标变化皆明显大于低肌酸激酶水平组受试者,p<0.05。受试者血清肌酸激酶峰值与最大等长肌力、肘关节活动角度、上臂围、肌肉感受最大变化值有相关,p<0.05。本研究认为肌肉损伤程度与肌酸激酶水平具有显著相关,尤其高血清肌酸激酶水平者肌酸激酶水平较大程度反映肌肉损伤程度趋势。本研究表明,肘关节活动角度、上臂围具有预测肌酸激酶峰值的效果。     

Creatine supplementation does not reduce muscle damage or enhance recovery from resistance exercise

Previous studies have shown that creatine supplementation reduces muscle damage and inflammation following running but not following high-force, eccentric exercise. Although the mechanical strain placed on muscle fibers during high-force, eccentric exercise may be too overwhelming for creatine to exert any protective effect, creatine supplementation may protect skeletal muscle stressed by a resistance training challenge that is more hypoxic in nature. The purpose of this study was to examine the effects of short-term creatine supplementation on markers of muscle damage (i.e., strength, range of motion, muscle soreness, muscle serum protein activity, C-reactive protein) to determine whether creatine supplementation offers protective effects on skeletal muscle following a hypoxic resistance exercise test. Twenty-two healthy, weight-trained men (19-27 years) ingested either creatine or a placebo for 10 days. Following 5 days of supplementation, subjects performed a squat exercise protocol (5 sets of 15-20 repetitions at 50% of 1 repetition maximum [1RM]). Assessments of creatine kinase (CK) and lactate dehydrogenase activity, high-sensitivity C-reactive protein, maximal strength, range of motion (ROM), and muscle soreness (SOR) with movement and palpation were conducted pre-exercise and during a 5-day follow up. Following the exercise test, maximal strength and ROM decreased, whereas SOR and CK increased. Creatine and placebo-supplemented subjects experienced significant decreases in maximal strength (creatine: 13.4 kg, placebo: 17.5 kg) and ROM (creatine: 2.4 degrees , placebo: 3.0 degrees ) immediately postexercise, with no difference between groups. Following the exercise test, there were significant increases in SOR with movement and palpation (p < 0.05 at 24, 48, and 72 hours postexercise), and CK activity (p < 0.05 at 24 and 48 hours postexercise), with no differences between groups at any time. These data suggest that oral creatine supplementation does not reduce skeletal muscle damage or enhance recovery following a hypoxic resistance exercise challenge.     

Muscle metabolism during exercise in dogs after 8-week confinement

Several indicators of muscle metabolism were measured in dogs during exercise following 8 weeks of confinement in cages. Muscle tissue samples were studied at rest and following exercise for adenine nucleotides, creatine phosphate, creatine, glycogen, pyruvate, and lactate. Results indicate that confinement results in less efficient metabolic responses to exercise, decreased muscle glycogen at rest, and changes in the equilibrium between ATP breakdown and resynthesis during exercise.     

Creatine supplementation reduces oxidative stress biomarkers after acute exercise in rats

The objective of this study was to evaluate the effect of creatine supplementation on muscle and plasma markers of oxidative stress after acute aerobic exercise. A total of 64 Wistar rats were divided into two groups: control group (n = 32) and creatine-supplemented group (n = 32). Creatine supplementation consisted of the addition of 2% creatine monohydrate to the diet. After 28 days, the rats performed an acute moderate aerobic exercise bout (1-h swimming with 4% of total body weight load). The animals were killed before (pre) and at 0, 2 and 6 h (n = 8) after acute exercise. As expected, plasma and total muscle creatine concentrations were significantly higher (P < 0.05) in the creatine-supplemented group compared to control. Acute exercise increased plasma thiobarbituric acid reactive species (TBARS) and total lipid hydroperoxide. The same was observed in the soleus and gastrocnemius muscles. Creatine supplementation decreased these markers in plasma (TBARS: pre 6%, 0 h 25%, 2 h 27% and 6 h 20%; plasma total lipid hydroperoxide: pre 38%, 0 h 24%, 2 h 12% and 6 h 20%, % decrease). Also, acute exercise decreased the GSH/GSSG ratio in soleus muscle, which was prevented by creatine supplementation (soleus: pre 8%, 0 h 29%, 2 h 30% and 6 h 44%, % prevention). The results show that creatine supplementation inhibits increased oxidative stress markers in plasma and muscle induced by acute exercise.     

Biochemical variables in plasma and urine before and after prolonged physical exercise

Nine normal young male students were studied during 2 days of relative rest, during 2 days of physical training and again during the succeeding 2 days of relative rest. 24-hour urine collections showed that the creatinine, creatine, uric acid, urea, calcium and magnesium excretion were similar during the resting and exercise days. The 24-hour urinary excretion of sodium and potassium was decreased during the exercise days, while the aldosterone excretion was increased. The hemoglobin concentration, hematocrit and red cell counts were decreased 14, as well as 42 h after exercise. The serum uric acid, creatine phosphokinase-MM (skeletal muscles) subfraction, glutamic oxalacetic transaminase and myoglobin levels were increased 14 h after exercise, but returned to baseline 42 h after this type of exercise. The mechanisms of these alterations were discussed and the data show that one should take into account previous exercise when interpreting the results of certain of these tests.     

Effects of creatine supplementation on performance and training adaptations

Creatine has become a popular nutritional supplement among athletes. Recent research has also suggested that there may be a number of potential therapeutic uses of creatine. This paper reviews the available research that has examined the potential ergogenic value of creatine supplementation on exercise performance and training adaptations. Review of the literature indicates that over 500 research studies have evaluated the effects of creatine supplementation on muscle physiology and/or exercise capacity in healthy, trained, and various diseased populations. Short-term creatine supplementation (e.g. 20 g/day for 5–7 days) has typically been reported to increase total creatine content by 10–30% and phosphocreatine stores by 10–40%. Of the approximately 300 studies that have evaluated the potential ergogenic value of creatine supplementation, about 70% of these studies report statistically significant results while remaining studies generally report non-significant gains in performance. No study reports a statistically significant ergolytic effect. For example, short-term creatine supplementation has been reported to improve maximal power/strength (5–15%), work performed during sets of maximal effort muscle contractions (5–15%), single-effort sprint performance (1–5%), and work performed during repetitive sprint performance (5–15%). Moreover, creatine supplementation during training has been reported to promote significantly greater gains in strength, fat free mass, and performance primarily of high intensity exercise tasks. Although not all studies report significant results, the preponderance of scientific evidence indicates that creatine supplementation appears to be a generally effective nutritional ergogenic aid for a variety of exercise tasks in a number of athletic and clinical populations.     

Functional coupling of adenine nucleotide translocase and mitochondrial creatine kinase is enhanced after exercise training in lung transplant skeletal muscle

Mechanisms responsible for limitation of exercise capacity in lung transplant recipients (LR) and benefits gained by exercise training were studied. Mitochondrial respiration parameters, energy transfer, and cell structure were assessed in vastus lateralis biopsies using the permeabilized fiber technique with histochemical and morphometric measurements. Twelve male controls (C) and 12 LR performed exercise training over 12 wk. Before exercise training, there were strong correlations between exercise capacity (maximal O(2) consumption and endurance time at 70% maximal power output) and cellular events, as assessed by percentage of type I fibers and apparent K(m) for exogenous ADP. Anticalcineurins were not involved in LR exercise limitation, since there were no differences in maximal mitochondrial rate of respiration before exercise training and no abnormalities in respiratory chain complexes compared with C. Training resulted in a significant increase in physiological parameters both at the cellular (apparent K(m) for exogenous ADP and stimulating effect of creatine) and integrated (maximal O(2) consumption, power output at ventilatory threshold, maximal power output, and endurance time at 70% maximal power output) levels in LR and C. After the training period, improvements in maximal O(2) consumption and in maximal mitochondrial rate of respiration were noted, as well as changes in endurance time and percentage of type I fibers. Because there were no changes in diameters and fiber types, baseline alteration of apparent K(m) for exogenous ADP and its improvement after training might be related to changes within the intracellular energetic units. After the training period, intracellular energetic units exhibited a higher control of mitochondrial respiration by creatine linked to a more efficient functional coupling adenine nucleotide translocase-mitochondrial creatine kinase, resulting in better exercise performances in C and LR.     

Effects of creatine supplementation on the energy cost of muscle contraction: a 31P-MRS study.

Five women and 3 men (29.8 +/- 1.4 yr) performed dynamic knee-extension exercise inside a magnetic resonance system (means +/- SE). Two trials were performed 7-14 days apart, consisting of a 4- to 5-min exhaustive exercise bout. To determine quadriceps cost of contraction, brief static and dynamic contractions were performed pre- and postexercise. (31)P spectra were used to determine pH and relative concentrations of P(i), phosphocreatine (PCr), and betaATP. Subjects consumed 0.3 g. kg(-1). day(-1) of a placebo (trial 1) or creatine (trial 2) for 5 days before each trial. After creatine supplementation, resting DeltaPCr increased from 40.7 +/- 1.8 to 46. 6 +/- 1.1 mmol/kg (P = 0.04) and PCr during exercise declined from -29.6 +/- 2.4 to -34.1 +/- 2.8 mmol/kg (P = 0.02). Muscle static (DeltaATP/N) and dynamic (DeltaATP/J) costs of contraction were unaffected by creatine supplementation as well as were ATP, P(i), pH, PCr resynthesis rate, and muscle strength and endurance. DeltaATP/J and DeltaATP/N were greatest at the onset of the exercise protocol (P < 0.01). In summary, creatine supplementation increased muscle PCr concentration, which did not affect muscle ATP cost of contraction.     

Muscle metabolism during prolonged physical exercise in dogs

In order to provide reference data, adenine nucleotide, creatine phosphate, glycogen, glycolytic intermediates and lactate muscle contents were measured in 49 dogs under resting conditions and during prolonged physical exercise of moderate intensity performed until exhaustion. Both the resting and exercise values of the measured variables were remarkably similar to those described in human subjects, except muscle lactate content which achieved higher values during submaximal exercise in dogs than in men.