肌肉收缩及自发振动的动力学理论

改变实验条件,肌纤维可发生从收缩到自发振动的相变。为了研究这一现象,引进了描述肌纤维内部弹性成分拉伸长度与张力关系的表达式,利用肌肉态方程并考虑肌纤维的特殊结构,给出了描述肌纤维收缩及自发振动的统一动力学方程。从动力学方程出发,肌纤维自发振动的发生条件得到了自然解释,所给出的振动周期和振动曲线同实验结果相符,并给出了一些新的理论结果。这一工作的意义在于,完成了从肌球蛋白单分子性质、肌纤维组织结构到肌纤维功能的信息整合。     

The static load component in muscle work

By citing examples from actual work situations and discussing the concept of muscular endurance and fatigue this paper is intended to provide an account of past and current research on the "static" component of muscular load during work. By amplitude probability distribution analysis of electromyographic signals it is possible to estimate the "static level" of muscular load during work. Electromyographic studies of job rotation between different assembly tasks in electronic industries often show that there are quantitatively and qualitatively only small differences in muscular load between different tasks.     

Muscular dystrophy of mink: a new animal model.

Muscular dystrophies comprise an important group of inherited disorders of man. Although the disease has been studied extensively, little is known about the underlying primary pathomechanisms. Consequently, treatment of patients is difficult and prognosis is poor. An animal model of muscular dystrophy is a useful research tool for approaching the basic problems of pathogenesis in muscle diseases. An inherited progressive muscular dystrophy of mink which resembles the amyotonic forms of human muscular dystrophy is currently under study. Clinically, the earliest sign is progressive muscular weakness and atrophy. Muscle enzyme activities in serum are usually elevated to pathologic levels. Urinary creatine/creatinine ratio is elevated. Pathologic changes are limited to skeletal muscle and are typical of those seen in amyotonic forms of human muscular dystrophy. These changes include variation in diameter size of muscle fibers, centralized nuclei, floccular and hyaline degeneration of scattered muscle fibers, increase in connective tissue in endomysial and perimysial areas, and regenerative attempts. Both type I and type II muscle fibers are involved in the disease process. Genetic studies indicate an autosomal recessive mode of inheritance. Although the primary defect in muscular dystrophy is traditionally thought to reside in skeletal muscle, recent studies have produced theories of primary involvement of other tissues and organ systems. These theories are presented and relationships to the traditional theory are discussed.     

Oxidative muscular injury and its relevance to hyperthyroidism

In experimental hyperthyroidism, acceleration of lipid peroxidation occurs in heart and slow-oxidative muscles, suggesting the contribution of reactive oxygen species to the muscular injury caused by thyroid hormones. This article reviews various models of oxidative muscular injury and considers the relevance of the accompanying metabolic derangements to thyrotoxic myopathy and cardiomyopathy, which are the major complications of hyperthyroidism. The muscular injury models in which reactive oxygen species are supposed to play a role are ischemia/reperfusion syndrome, exercise-induced myopathy, heart and skeletal muscle diseases related to the nutritional deficiency of selenium and vitamin E and related disorders, and genetic muscular dystrophies. These models provide evidence that mitochondrial function and the glutathione-dependent antioxidant system are important for the maintenance of the structural and functional integrity of muscular tissues. Thyroid hormones have a profound effect on mitochondrial oxidative activity, synthesis and degradation of proteins and vitamin E, the sensitivity of the tissues to catecholamine, the differentiation of muscle fibers, and the levels of antioxidant enzymes. The large volume of circumstantial evidence presented here indicates that hyperthyroid muscular tissues undergo several biochemical changes that predispose them to free radical-mediated injury.     

Aberrant glycosylation of alpha-dystroglycan causes defective binding of laminin in the muscle of chicken muscular dystrophy

Dystroglycan is a central component of dystrophin-glycoprotein complex that links extracellular matrix and cytoskeleton in skeletal muscle. Although dystrophic chicken is well established as an animal model of human muscular dystrophy, the pathomechanism leading to muscular degeneration remains unknown. We show here that glycosylation and laminin-binding activity of alpha-dystroglycan (alpha-DG) are defective in dystrophic chicken. Extensive glycan structural analysis reveals that Galbeta1-3GalNAc and GalNAc residues are increased while Siaalpha2-3Gal structure is reduced in alpha-DG of dystrophic chicken. These results implicate aberrant glycosylation of alpha-DG in the pathogenesis of muscular degeneration in this model animal of muscular dystrophy.     

Genetic modifiers of muscular dystrophy: implications for therapy

The genetic understanding of the muscular dystrophies has advanced considerably in the last two decades. Over 25 different individual genes are now known to produce muscular dystrophy, and many different "private" mutations have been described for each individual muscular dystrophy gene. For the more common forms of muscular dystrophy, phenotypic variability can be explained by precise mutations. However, for many genetic mutations, the presence of the identical mutation is associated with marked phenotypic range that affects muscle function as well as cardiac function. The explanation for phenotype variability in the muscular dystrophies is only now being explored. The availability of genetically engineered animal models has allowed the generation of single mutations on the background of highly inbred strain. Phenotypic variation that is altered by genetic background argues for the presence of genetic modifier loci that can ameliorate or enhance aspects of the dystrophic phenotype. A number of individual genes have been implicated as modifiers of muscular dystrophy by studies in genetically engineered mouse models of muscular dystrophy. The value of these genes and products is that the pathways identified through these experiments may be exploited for therapy.     

A model of ovum transport

A theoretical fluid dynamical model of ovum transport in the oviduct incorporating transport mechanisms due to ciliary activity, muscular activity and an applied pressure drop across the oviduct is developed. Theory suggests that the cilia provide the steady component of ovum transport whereas muscular activity results in highly oscillatory motion. If muscular activity is to provide transport in a pro-uterine direction, a coordinated sequence of muscular activity with a strong pro-uterine bias is needed. Changes in pressure are highest in the narrowest sections. The highly convoluted rugae may allow "leakback" around the ovum so relieving the pressure drop across the ovum in narrower sections of the oviduct.     

Muscular tunic of the dog ureter in the normal state and in ureterohydronephrosis (data of scanning electron microscopy)

By means of scanning electron microscopy and macro- microscopical methods in 16 mongrel dogs the ureters have been studied, normal and at ureterohydronephrosis. The ureteral muscles are spirally shaped. The external muscular layer is oriented along the spiral, its step approximately corresponds to the length of the peristaltic wave. The spiral-shaped course of the muscular fasciculi in the middle layer is of opposite direction, the spiral step corresponds to the ureter diameter. The internal muscular layer is formed as a result of changes in the spiralization angle of the middle muscular layer from outside into inside. Fibrills of the connective tissue framework possess predominantly longitudinal orientation. At ureterohydronephrosis, together with increasing diameter of the ureter, the step of the muscular spiral decreases, the connective tissue fibrillar framework acquires a net-like structure.     

Calpains and muscular dystrophies

Calpains are a ubiquitous, well-conserved family of calcium-dependent, cysteine proteases. Their function in muscle has received increased interest because of the discoveries that the activation and concentration of the ubiquitous calpains increase in the mouse model of Duchenne muscular dystrophy (DMD), but null mutations of muscle specific calpain causes limb girdle muscular dystrophy 2A (LGMD2A). These findings indicate that modulation of calpain activity contributes to muscular dystrophies by disrupting normal regulatory mechanisms influenced by calpains, rather than through a general, nonspecific increase in proteolysis. Thus, modulation of calpain activity or expression through pharmacological or molecular genetic approaches may provide therapies for some muscular dystrophies.     

Ultrastructure of the striated muscle tissue of the iris of birds]

Heteromorphism of the contractile elements of the iris muscular tissue in chick embryos and in chickens has been studied by means of electron microscopical investigation. The leading contractile tissue of the iris is the striated muscular tissue, which is formed as a cellular-simplastic system with its own cambium-myosatellitocytes. Some cells, containing myofilaments in their cytoplasm, are related to myofibroblastic and smooth muscle differons, which functions remain to be studied. A hypothesis is proposed on existence of two sources for development of the iris muscular elements. The first-stem cells for the striated muscular tissue; at early stages of embryonal development they are included into composition of ectomesenchyme of the neural crest and migrate into the area of the muscle anlages. The second-cells migrating from the ocular cup margins and developing into the smooth myocytes of the iris.     

Effect of metaproterenol on ketone body metabolism of the forearm in healthy and diabetic subjects.

Muscular ketone body metabolism was studied by the registration of arterial-deepvenous concentration differences of glycerol, beta-hydroxybutyrate and acetoacetate, and of muscular blood flow in 53 healthy volunteers and 23 juvenile diabetics. In six subjects of each group substrate metabolism was also investigated during the intrabrachial arterial infusion of metaproterenol (0.4 microgram/min). Identical rates of muscular glycerol release and ketone's fractional extraction were obtained in healthy and diabetic subjects during the basal period. A significant correlation between muscular ketone extraction and arterial ketone concentration was calculated in both groups. During the infusion of metaproterenol the diabetics, unlike the controls, revealed enhanced muscular glycerol output and reduced fractional extraction of beta-hydroxybutyrate. These findings are in line with the present view that the impairment of muscular ketone body utilisation in diabetic ketoacidosis may at least partly be due to enhanced muscular lipolysis.     

Late-Onset Muscle Dystrophy: Oculopharyngoesophageal Variety

Oculopharyngeal muscular dystrophy is a localized or restricted variety of muscular dystrophy, characterized by bilateral ptosis, myopathic facies, external ophthalmoplegia and dysphagia. A patient with this unusual myopathy is described and detailed esophageal motility studies are presented that provide conclusive evidence of both striated and smooth muscle involvement.Because these unusual localized forms of muscular dystrophy exist and may be of late onset, previous rigid concepts concerning the dystrophies should be discarded.     

Muskeldystrophien Duchenne und Becker

Duchenne muscular dystrophy (DMD) is the most frequent muscular disorder in infancy. The inheritance is X-linked recessive with mutations in the dystrophin gene (about 65% deletions, about 7% duplications, about 26% point mutations, and about 2% unknown mutations). The genetic model is complex. The sex ratio of the mutations is unequal. Point mutations and duplications arise in spermatogenesis, whereas deletions arise in oogenesis. About 33% of all patients are new mutations; however, most new mutations are germline mosaic. Becker muscular dystrophy is allelic to DMD.     

Molecular biology of distal muscular dystrophies—Sarcomeric proteins on top

During the last 10 years several muscular dystrophies within the group of distal myopathies have been clarified as to the molecular genetic cause of the disease. Currently, the next steps are carried out to identify the molecular pathogenesis downstream of the gene defects. Some early ideas on what is going on in the muscle cells based on the defect proteins are emerging. However, in no single distal muscular dystrophy these efforts have yet reached the point where direct trials for therapy would have been launched, and in many distal dystrophies the causative gene is still lacking. When comparing the gene defects in the distal dystrophies with the more common proximal muscular dystrophies such as dystrophinopathies or limb-girdle muscular dystrophies, there is a striking difference: the genes for distal dystrophies encode sarcomere proteins whereas the genes for proximal dystrophies more often encode sarcolemmal proteins.     

Duchenne muscular dystrophy (DMD) in a female with an X/autosomal translocation: Further evidence that the DMD locus is at Xp21

An isolated case of Duchenne muscular dystrophy in a female who has a de novo t(X;5)(p21;q35) translocation is described. The similarities between this patient and four previously reported females with Duchenne muscular dystrophy are discussed. It is concluded that the locus for Duchenne muscular dystrophy is at Xp21 and, furthermore, that this site may be particularly susceptible both to chromosome breakage and exchange and to gene mutation.     

Cross‐sectional serum metabolomic study of multiple forms of muscular dystrophy

Muscular dystrophies are characterized by a progressive loss of muscle tissue and/or muscle function. While metabolic alterations have been described in patients’‐derived muscle biopsies, non‐invasive readouts able to describe these alterations are needed in order to objectively monitor muscle condition and response to treatment targeting metabolic abnormalities. We used a metabolomic approach to study metabolites concentration in serum of patients affected by multiple forms of muscular dystrophy such as Duchenne and Becker muscular dystrophies, limb‐girdle muscular dystrophies type 2A and 2B, myotonic dystrophy type 1 and facioscapulohumeral muscular dystrophy. We show that 15 metabolites involved in energy production, amino acid metabolism, testosterone metabolism and response to treatment with glucocorticoids were differentially expressed between healthy controls and Duchenne patients. Five metabolites were also able to discriminate other forms of muscular dystrophy. In particular, creatinine and the creatine/creatinine ratio were significantly associated with Duchenne patients performance as assessed by the 6‐minute walk test and north star ambulatory assessment. The obtained results provide evidence that metabolomics analysis of serum samples can provide useful information regarding muscle condition and response to treatment, such as to glucocorticoids treatment.     

Molecular biology of distal muscular dystrophies--sarcomeric proteins on top

During the last 10 years several muscular dystrophies within the group of distal myopathies have been clarified as to the molecular genetic cause of the disease. Currently, the next steps are carried out to identify the molecular pathogenesis downstream of the gene defects. Some early ideas on what is going on in the muscle cells based on the defect proteins are emerging. However, in no single distal muscular dystrophy these efforts have yet reached the point where direct trials for therapy would have been launched, and in many distal dystrophies the causative gene is still lacking. When comparing the gene defects in the distal dystrophies with the more common proximal muscular dystrophies such as dystrophinopathies or limb-girdle muscular dystrophies, there is a striking difference: the genes for distal dystrophies encode sarcomere proteins whereas the genes for proximal dystrophies more often encode sarcolemmal proteins.     

Expression profiling of muscles from Fukuyama-type congenital muscular dystrophy and laminin-alpha 2 deficient congenital muscular dystrophy; is congenital muscular dystrophy a primary fibrotic disease?

Fukuyama-type congenital muscular dystrophy (FCMD) and laminin-alpha2 deficient congenital muscular dystrophy (MDC1A) are congenital muscular dystrophies (CMDs) and they both are categorized into the same clinical entity of muscular dystrophy as Duchenne muscular dystrophy (DMD). All three disorders share a common etiologic defect in the dystrophin-glycoprotein complex, which connects muscle structural proteins with the extracellular basement membrane. To investigate the pathophysiology of these CMDs, we generated microarray gene expression profiles of skeletal muscle from patients in various clinical stages. Despite diverse pathological changes, the correlation coefficient of overall gene expression among these samples was considerably high. We performed a multi-dimensional statistical analysis, the Distillation, to extract determinant genes that distinguish CMD muscle from normal controls. Up-regulated genes were primarily extracellular matrix (ECM) components, whereas down-regulated genes included structural components of mature muscle. These observations reflect active interstitial fibrosis with less active regeneration of muscle cell components in the CMDs, characteristics that are clearly distinct from those of DMD. Although the severity of fibrosis varied among the specimens tested, ECM gene expression was consistently high without substantial changes through the clinical course. Further, in situ hybridization showed more prominent ECM gene expression on muscle cells than on interstitial tissue cells, suggesting that ECM components are induced by regeneration process rather than by 'dystrophy.' These data imply that the etiology of FCMD and MDC1A differs from that of the chronic phase of classical muscular dystrophy, and the major pathophysiologic change in CMDs might instead result from primary active fibrosis.     

Emery-Dreifuss muscular dystrophy

The muscular dystrophies are a group of disorders, genetically determined, with progressive degeneration of muscle(s), without central nervous nor peripheral nerve abnormalities. The Emery-Dreifuss muscular dystrophy is one of these. We report a case with typical features.