家兔腓肠肌肌构筑及肌纤维型的实验研究

根据家兔（Ｏｒｙｃｔｏｌａｇｕｓｃｕｎｉｃｕｌｕｓｄｏｍｅｓｔｉｃａ）腓肠肌的肌构筑和神经供应特征,将该肌外侧头分为内侧、中间、外侧３个亚体,内侧头无肌亚体。用家兔８例１６侧腓肠肌,按上述３个亚体及内侧头分别取材,做冰冻横切片,肌动球朊ＡＴＰ酶染色,将肌纤维分为ＳＯ型、ＦＯＧ型和ＦＧ型。检测各亚体的肌纤维型构成比率,并以图象分析仪测量３型肌纤维的直径和横切面积。结果发现：ＳＯ型纤维在内侧头占１６．７％,在外侧头由内侧亚体的１１．３％向外侧亚体的２０．８％依次递增;ＦＯＧ型纤维由内侧亚体的２３．２％向外侧亚体的３０．９％递增。ＦＧ型纤维则从内侧亚体的６５．５％向外侧亚体的４８．３％逐渐递减。３型肌纤维成点缀式镶嵌型分布。各亚体中ＳＯ型纤维最细（５７．４—５８．２μｍ）,ＦＯＧ型纤维稍粗（６０．１—６１．１μｍ）,ＦＧ型纤维最粗（６３．６—６４．５μｍ）。     

家兔与大鼠腓肠肌的生后发育比较

研究分析了家兔、大鼠腓肠肌在生后各年龄阶段的内侧头、外侧头的内侧亚体、中间亚体或外侧浅亚体、外侧亚体或外侧深亚体内快慢肌纤维的发育情况，应用大体解剖结合组织化学方法确定了其肌亚体，并进行琥珀酸脱氢酶染色、图像分析两型肌纤维的直径特征，以及肌构筑学与肌诱发电位的测量。结果表明：家兔在生后1个月时，内侧亚体从其深面凸现于内侧头与外侧亚体之间，中间亚体居于内侧亚体远端；大鼠内侧头未能区分肌亚体，其外侧头分为内侧亚体、外侧浅亚体，而外侧深亚体居于外侧浅亚体的深面呈重叠状：生后2、3天均未能分出Ⅰ、Ⅱ型肌纤维，也未见有原始肌束；Ⅰ、Ⅱ型肌纤维比例随年龄增长而变化，内侧亚体的Ⅱ型肌纤维比例在家兔与大鼠的生后发育中始终占优，而在其它各肌亚体内，Ⅱ型肌纤维的比例在发育中不恒定，直至成年后Ⅱ型肌纤维才趋于稳定并占优。在生长发育过程中，各肌亚体内Ⅱ型肌纤维的直径在各年龄段均大于Ⅰ型肌纤维。生后6个月家兔外侧头内侧亚体(FL／CSA)比值越大，倾向于速度型构筑；内侧头、中间亚体和外侧亚体(CSA／MW)比值越大，倾向于力量型构筑。大鼠腓肠肌外侧头内侧亚体乙酰胆碱酯酶染色显示葡萄状运动神经末梢支配慢肌纤维，斑点状运动终板位于快肌纤维。     

抽样计数肌横切面内肌纤维数量的研究

在５例家兔胫骨前肌的前、后亚体肌横切面内,应用直接计数和抽样计数方法计算Ｉ型、Ⅱ型肌纤维的构成比例和肌纤维总数。结果明显,方法切实易行。     

大鼠与家兔生后各年龄阶段跖肌纤维的比较

应用建立在肌球蛋白重链异构体基础上的标准肌动球蛋白ATP酶和琥珀酸脱氢酶组织化学方法,分析大鼠和家兔出生后发育各年龄阶段跖肌纤维型分布。在生后2周至24周龄的大鼠和家兔Ⅰ、ⅡX型肌纤维百分比例减少,而ⅡA、ⅡB型纤维则增加。进行大量单肌纤维的组织化学特征的比较和相关性探讨。结果显示动物平均体重与跖肌的平均湿重随生后发育逐渐增加,Ⅰ、ⅡX、ⅡA及ⅡB型纤维均在生后各年龄组的全部肌肉内被发现,但出生后2日龄组是个例外。在生后发育期间,雄性大鼠和家兔ⅡB型纤维的平均肌纤维型构成要大于雌性大鼠和家兔,而雄性大鼠和家兔Ⅰ、ⅡX、ⅡA型三种氧化组织化学分类的肌纤维型构成均小于雌性大鼠和家兔。大鼠Ⅰ、ⅡX、ⅡA和ⅡB型纤维的平均横切面积显然要比家兔的同类型肌纤维要小。在大鼠和家兔可见明显的性别差异。大鼠和家兔的ⅡX型纤维横切面积是最小的,Ⅰ、ⅡA型纤维呈中等大小,ⅡB型纤维最大。该重要的测试有助于我们深入研究啮齿类动物快肌纤维生理特征的适应。     

大鼠和家兔生后发育各阶段比目鱼肌纤维的比较

为研究大鼠与家兔骨骼肌各类型肌纤维的数量和二维分布以及生后发育对其影响,取生后2d和2、4、6、8、10周龄(体重10g和32、95、190、280、320g)大鼠及生后2d和2、4、8、12、16、20、24周龄(体重100g和220、400、750、1200、1600、2100、2500g)家兔的比目鱼肌做琥珀酸脱氢酶染色。实验结果表明,大鼠和家兔比目鱼肌纤维被分成Ⅰ型(SO),ⅡX型(FO)和ⅡA型(FOG)3型。使用图像分析系统分析每型肌纤维在生后发育各阶段的相关变化,大鼠和家兔比目鱼肌中：Ⅰ型纤维分布于整块肌肉,其数量随着生后发育而增加。幼体ⅡX型纤维分布在整块肌肉中,其数量随生后发育而减少;ⅡA型分布在肌肉中深层,数量几乎无变化;至成体时只有少量的ⅡX和ⅡA分布在肌表层。整个发育期间未见ⅡB型纤维。ⅡA型纤维直径最大,Ⅰ型中等,而ⅡX型最小。家兔3型肌纤维的平均横切面积比大鼠的大。这些结果表明大鼠和家兔后肢肌各种类型肌纤维的数量比例和分布随生长过程发生改变。     

慢性缺氧大鼠膈肌纤维类型适应性变化

采用肌球蛋白ＡＴＰ酶（ｍＡＴＰ酶）组化将肌纤维分为Ⅰ、ⅡＡ和ⅡＢ三种类型,通过慢性常压和减压间断缺氧大鼠模型,观察慢性缺氧（分别缺氧１个月和３个月）大鼠膈肌纤维类型的适应性变化,并与肢体肌肉进行比较。结果表明,慢性缺氧大鼠膈肌纤维由酵解型向氧化型转化,主要表现为ⅡＡ纤维比例上升（Ｐ＜０．０５）和ⅡＢ（Ｐ＜０．０５－０．０１）下降,肋膈肌变化大于脚膈肌和肢体肌肉。肌肉间适应性变化的差异可能与其功能要求不同有关。     

家兔腓肠肌构筑及肌纤维型的实验研究

根据家兔（Ｏｒｙｃｔｏｌａｇｕｓｃｕｎｉｃｕｌｕｓｄｏｍｅｓｔｉｃａ）腓肠 肌构筑和神经代价 应特征,将该肌外侧头分为内侧,中间,外侧业体,内侧头无肌亚体。用家兔８例１６例腓肠肌,按上述３个亚体及内侧头分别取材,做冰冻横切片,肌动球朊ＡＴＰ酶染色,将肌纤维分为ＳＯ型、ＦＯＧ型和ＦＧ型。     

尾部悬吊对达乌尔黄鼠比目鱼肌形态及 mATP 酶活性的影响

采用尾部悬吊法建立后肢骨骼肌废用的动物模型,以肌球蛋白ATP酶(mATPase)法测定比目鱼肌的mATPase活性,依据mATPase染色结果进行肌纤维分型,并测量肌纤维横截面积(Cross-section area,CSA),首次观察了尾部悬吊对达乌尔黄鼠比目鱼肌湿重、CSA和梭外肌、梭内肌纤维mATPase活性的影响,并与尾部悬吊大鼠进行了比较。旨在探讨冬眠动物骨骼肌在废用状态下的变化。结果显示,尾部悬吊14d可使大鼠比目鱼肌湿重体重比下降35.52%(P<0.001),Ⅰ型肌纤维CSA和Ⅱ型肌纤维CSA分别下降18.91%和20.68%(P<0.05);肌纤维平均CSA减少20.45%(P<0.01)。比目鱼肌中Ⅰ型肌纤维的构成比由对照组的80.61%降低为66.83%,Ⅱ型肌纤维的构成比由19.39%增加到33.17%(P<0.001);梭内肌纤维mATPase活性增强,核袋1纤维的mATPase染色由阴性(-)转变为强阳性( ),核袋2纤维和核链纤维由阳性( )转变为强阳性( )。而达乌尔黄鼠在尾部悬吊14d后,比目鱼肌湿重仅比对照组下降0.05%,Ⅰ、Ⅱ型肌纤维CSA与平均CSA分别比对照组减少0.84%、0.63%和0.37%,均无明显差异(P>0.05);与对照组相比,比目鱼肌中Ⅰ型肌纤维的构成比从82.55%减少到77.30%,Ⅱ型肌纤维的构成比由17.45%增加到22.70%(P<0.05);梭内肌纤维mATPase活性亦明显升高,核袋1纤维的mATPase染色由对照组的阴性(-)转化为强阳性( ),核袋2纤维及核链纤维则由对照组的阳性( )转化为核袋2纤维呈阳性( ),核链纤维则呈弱阳性( )。结果表明:尾部悬吊可致大鼠比目鱼肌明显萎缩;达乌尔黄鼠比目鱼肌则无明显萎缩;两者比目鱼肌梭内、外肌mATPase活性均明显升高。     

跖肌肌球蛋白腺苷三磷酸酶与琥珀酸脱氢酶染色的相关性探讨

研究大鼠、家兔和人跖肌的肌纤维型构成比例与分布。应用肌球蛋白腺苷三磷酸酶(ATP酶)和琥珀酸脱氢酶(SDH酶)染色法,观察比较各型肌纤维的组织化学特性。结果表明：肌球蛋白ATP酶染色,大鼠、家兔和人跖肌的肌纤维可分成I型、ⅡA型、ⅡB型肌纤维,横切面呈多边形或椭圆形,分别约占25％、35％和40％;琥珀酸脱氢酶染色,肌纤维呈蔚蓝色,以镶嵌交叉排列,可分为中染S0、深染FOG和浅染FG三型,分别约占25％、30％和45％,种系间无显著性差异。ATP酶活性反应肌纤维收缩的生理特性,而SDH活性反应肌纤维的代谢特征,两种分型的方法有所差异。     

举重训练对男子肌比力、肌纤维的影响

安排9名有一定训练的青少年运动员参加10周举重训练。每周6次,每次8小时。训练前后用电子计算机—X线断层扫描技术(CT)测量大腿肌肉横断面积,股外肌针刺活检取样测定Ⅰ、Ⅱ型肌纤维％和面积。测定大腿伸膝肌最大随意等长力量。将结果(实验前、后)与对照组(13名无训练者)和优秀举重运动员(健将3人、一级4人)进行比较。结果表明,有训练人(实验前、后和优秀)与没有训练人(对照)在肌比力上存有差别。短、长期举重训练后,肌比力与Ⅱ型肌纤维％呈正相关。短、长期举重训练不曾改变肌纤维类型分布。举重训练对Ⅱ型肌纤维有选择性作用,且这个作用不受年龄的影响。结果还提示,肌比力的变化及肌比力与肌纤维之间的关系都会受运动项目专项特点的影响。     

Influence of electrical stimulation on the morphological and metabolic properties of paralyzed muscle.

Selected morphological and metabolic properties of single fibers were studied in biopsy samples from the tibialis anterior of normal control and spinal cord-injured (SCI) subjects. In the SCI subjects, one muscle was electrically stimulated progressively over 24 wk, in 6-wk blocks for less than or equal to 8 h/day, while the contralateral muscle remained untreated. The percentage of fibers classified as type I [qualitative alkaline preincubation myofibrillar adenosinetriphosphatase (ATPase)] was significantly less in the unstimulated paralyzed muscles than in the muscles of normal control subjects. Electrical stimulation increased the proportion of type I fibers in the SCI subjects. For both type I and type II fibers, the cross-sectional area, activities of myofibrillar ATPase and succinate dehydrogenase, and the capillary-to-fiber ratio were also significantly less in the paralyzed muscles than in the normal control muscles. Electrical stimulation increased only the activity of succinate dehydrogenase in both fiber types of the SCI subjects. These data are discussed in relation to the electromechanical properties of the respective muscles described in an accompanying paper (J. Appl. Physiol. 72: 1393-1400, 1992). In general, the electrical stimulation protocol used in this study enhanced the oxidative capacity and endurance properties of the paralyzed muscles but had no effect on fiber size and strength.     

Distribution of sarcoplasmic reticulum Ca-ATPase and of calsequestrin in rabbit and rat skeletal muscle fibers

Muscle fibers in rabbit extensor digitorum longus (EDL), tibialis anterior (TA) and soleus, and rat soleus, were examined immunohistochemically for two proteins of the sarcoplasmic reticulum. Ca-ATPase and calsequestrin (CaS). Fibers were typed with the histochemical reaction for actomyosin ATPase. In the rabbit EDL and TA, type I fibers clearly reacted less for Ca-ATPase and CaS than type II fibers, but the difference was less with CaS than with Ca-ATPase. Although the differences were relatively small, IIB fibers consistently presented greater amounts of Ca-ATPase than IIA fibers. No type II subgroups could be recognized after incubation with anti-CaS. These findings confirm results from previous immunochemical measurements on whole muscles containing different proportions of IIA and IIB fibers (Leberer and Pette 1986). Type IIA and IIC in the rabbit and rat soleus reacted stronger for Ca-ATPase and for CaS than type I fibers. Small differences in Ca-ATPase, but not in CaS, were recognized within the type I fiber population. Therefore, type I fibers in the rabbit and rat soleus are not a homogeneous population.     

Rostrocaudal variation of fiber type composition in rat intercostal muscles.

We used the histochemical stain for ATPase to compare the fiber-type composition of rat internal and external intercostal muscles from thoracic (T) segments 2-5, 8, and 11. At each level, type II fibers were more numerous than type I fibers, type II B fibers were more numerous than II A fibers, and type I fibers were more numerous in external than in internal intercostals. However, fiber type composition varied from segment to segment. For example, the proportion of type II A fibers increased in a rostrocaudal gradient in internal but not external intercostals, and type I fibers were more prevalent at rostral and caudal than at intermediate levels in both internal and external intercostals. These results provide a basis for interpreting previous physiological and molecular studies which have compared intercostal muscles from different segmental levels.     

Myosin heavy chain composition in human masticatory muscles by immunohistochemistry and gel electrophoresis.

In this study we compared the immunohistochemically quantified fiber type area with the myosin heavy chain (MyHC) contents of a bundle of fibers from a human masticatory muscle. The total cross-sectional areas were determined immunohistochemically for the three major fiber types (I, IIA, and IIX) in bundles of fibers (n=42) taken from the anterior and posterior belly of the human digastric muscle (n=7). The relative MyHC contents of the same fiber bundles were determined electrophoretically (MyHC-I, -IIA, and -IIX; anterior, 32%, 35%, and 33%; posterior, 39%, 42%, and 19%) and compared with the immunohistochemical data (MyHC-I, -IIA, and -IIX; anterior, 32%, 31%, and 37%; posterior, 39%, 45%, and 15%). No significant differences were seen in the mean fiber type distribution between the two techniques; the correlation coefficient ranged from 0.71 to 0.96. The correlation coefficient was higher for MyHC type I and MyHC type IIX than for MyHC type IIA. The MyHC contents of single fibers taken from the posterior belly indicated that many fibers in this belly co-express MyHC-IIA and MyHC-IIX. Despite the presence of these hybrid fibers, the correspondence between both methods was relatively large.     

Regional differences in intramyocellular lipids in humans observed by in vivo 1H-MR spectroscopic imaging.

Regional differences in the content of intramyocellular lipids (IMCL), extramyocellular lipids, and total creatine (TCr) were quantified in soleus (S), tibialis posterior (TP), and tibialis anterior (TA) muscles in humans using in vivo 1H proton spectroscopic imaging at 4 T. Improved spatial resolution (0.25-ml nominal voxel resolution) made it feasible to measure IMCL in S, TP, and TA simultaneously in vivo. The most significant regional difference was found in the content of IMCL compared with extramyocellular lipids or TCr. The concentrations of TCr were found to be 29-32 mmol/kg, with little regional variation. IMCL content was measured to be 4.8 +/- 1.6 mmol/kg tissue wt in S, 2.8 +/- 1.3 mmol/kg tissue wt in TP, and 1.6 +/- 0.9 mmol/kg tissue wt in TA in the order of S > TP > TA (P < 0.05). It is likely that these IMCL values are consistent with the known fiber types of these muscles, with S having the greatest fraction of type I (slow-twitch, oxidative) fibers and TA having a large fraction of type IIb (fast-twitch, glycolytic) fibers.     

Fiber types and some contractile properties of extensor digitorum longus and soleus muscles in different animal species

We studied the fiber types and contractile properties of the extensor digitorum longus (EDL) and soleus (SOL) muscles from young adult mice, rats and guinea pigs, and the correlation between these two parameters. Individual fibers in both muscles were classified as fast-twitch glycolytic (FG), fast-twitch oxidative glycolytic (FOG) or slow-twitch oxidative (SO) fibers according to Peter et al., and type II B, II A, or I fibers according to Brooke & Kaiser. Contractile properties were measured in situ at 37 degrees C. The isometric twitch contraction time (CT) and one-half relaxation time (1/2 RT) tended to be shortened in proportion to the area occupied by type II fibers, and type II B fibers. However, the differences between CT and fiber types were not always uniform among the three species. The CT of the rat EDL, in spite of its higher proportion of type II B fibers about 10% was the same as that of the guinea-pig EDL. The SOL of the mouse, composed of about 50% type I (SO) fibers, had a CT about as short as that of the EDL. In the case of the classification by Peter et al., the relationship between the percentage of subgroups of fast-twitch fibers and the CT or 1/2 RT, but not the resistance to fatigue, was not obvious. The resistance to fatigue tended to be enhanced in proportion to the area occupied by FOG in the EDL and by SO (type I) in the SOL. These results suggest that the contractile properties of individual fibers identified histochemically are distinct among animal species, producing interspecies differences in fiber types along with different contractile properties. However, it may be possible to compare the difference between fiber types and CT or 1/2 RT in the classification based on the pH lability of myosin ATPase, and also the difference between fiber types and resistance to fatigue in the classification based on the oxidative enzyme.     

Proteomic analysis of rat soleus and tibialis anterior muscle following immobilization

A proteomic analysis was performed comparing normal slow twitch type fiber rat soleus muscle and normal fast twitch type fiber tibialis anterior muscle to immobilized soleus and tibialis anterior muscles at 0.5, 1, 2, 4, 6, 8 and 10 days post immobilization. Muscle mass measurements demonstrate mass changes throughout the period of immobilization. Proteomic analysis of normal and atrophied soleus muscle demonstrated statistically significant changes in the relative levels of 17 proteins. Proteomic analysis of normal and atrophied tibialis anterior muscle demonstrated statistically significant changes in the relative levels of 45 proteins. Protein identification using mass spectrometry was attempted for all differentially regulated proteins from both soleus and tibialis anterior muscles. Four differentially regulated soleus proteins and six differentially regulated tibialis anterior proteins were identified. The identified proteins can be grouped according to function as metabolic proteins, chaperone proteins, and contractile apparatus proteins. Together these data demonstrate that coordinated temporally regulated changes in the proteome occur during immobilization-induced atrophy in both slow twitch and fast twitch fiber type skeletal muscle.     

Distribution of sarcoplasmic reticulum Ca-ATPase and of calsequestrin in rabbit and rat skeletal muscle fibers

Summary Muscle fibers in rabbit extensor digitorum longus (EDL), tibialis anterior (TA) and soleus, and rat soleus, were examined immunohistochemically for two proteins of the sarcoplasmic reticulum, Ca-ATPase and calsequestrin (CaS). Fibers were typed with the histochemical reaction for actomyosin ATPase. In the rabbit EDL and TA, type I fibers clearly reacted less for Ca-ATPase and CaS than type II fibers, but the difference was less with CaS than with Ca-ATPase. Although the differences were relatively small, HB fibers consistently presented greater amounts of Ca-ATPase than IIA fibers. No types II subgroups could be recognized after incubation with anti-CaS. These findings confirm results from previous immunochemical measurements on whole muscles containing different proportions of IIA and IIB fibers (Leberer and Pette 1986). Type IIA and IIC in the rabbit and rat soleus reacted stronger for Ca-ATPase and for CaS than type I fibers. Small differences in Ca-ATPase, but not in CaS, were recognized within the type I fiber population. Therefore, type I fibers in the rabbit and rat soleus are not a homogeneous population.     

Myofibrillar ATPase histochemistry of rat skeletal muscles: a "two-dimensional" quantitative approach

In histochemical investigations of skeletal muscle, the fibers are commonly classified into three types according to their staining for myofibrillar ATPase (mATPase). In serial sections of skeletal muscles from normal Wistar rats, we compared two common staining methods for mATPase: (a) an ac-ATPase technique, with pre-incubation at pH 4.7, and (b) a fixed alk-ATPase technique, using treatment with 5% paraformaldehyde followed by pre-incubation at pH 10.4. In addition, the same fibers were stained in subsequent serial sections for succinate dehydrogenase (SDH) activity. Staining intensities were objectively evaluated by microphotometric measurements of optical density. Combining both mATPase methods in consecutive serial sections ("two-dimensional approach") led to the identification of four distinct clusters of fibers: Types I, IIA, and two subgroups of Type IIB, as separated by their staining densities for fixed alk-ATPase (IIBd dark, IIBm moderate). The mean intensity of SDH staining per fiber type, as measured in the central core of the fibers, was ranked such that IIA greater than I greater than IIBd greater than IIBm. The analyzed muscles (tibialis anterior, biceps brachii) were markedly heterogeneous with respect to the topographic distribution of different fiber types. In comparison to other muscle portions, the regions containing Type I fibers ("red" portions) showed a higher IIBd vs IIBm ratio and more intense SDH staining for either subtype of the IIB fibers. The IIBd fibers probably correspond to the Type 2X fibers of Schiaffino et al.     

Rostrocaudal variation of fiber type composition in rat intercostal muscles

Summary We used the histochemical stain for ATPase to compare the fiber-type composition of rat internal and external intercostal muscles from thoracic (T) segments 2–5, 8, and 11. At each level, type II fibers were more numerous than type I fibers, type II B fibers were more numerous than II A fibers, and type I fibers were more numerous in external than in internal intercostals. However, fiber type composition varied from segment to segment. For example, the proportion of type II A fibers increased in a rostrocaudal gradient in internal but not external intercostals, and type I fibers were more prevalent at rostral and caudal than at intermediate levels in both internal and external intercostals. These results provide a basis for interpreting previous physiological and molecular studies which have compared intercostal muscles from different segmental levels.