Arthur F. Grimm scite author profile

Many mammalian muscles have a complex internal architecture. This type of structure could allow a single muscle to produce a variety of force vectors through selective regional contractions. This hypothesis was tested electromyographically in the multipinnate pig masseter by recording simultaneously from several intramuscular sites. It was found that the activity in different portions of the masseter varied systematically during the various phases of mastication. anatomical correlates of the differential activity included fasciculus orientation and length, sarcomere length in specific jaw positions, and histochemical fiber type. The usual assumptions made about muscles for biomechanical analysis, such as uniform contraction and constant line of action, are inappropriate for complex muscles such as the pig masseter.

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Regulation of sarcomere number in skeletal muscle: A comparison of hypotheses

Herring

Grimm

1984

Muscle and Nerve

136

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Sarcomere lengths from 16 locations in the muscles of mastication were measured from pigs fixed in maximum excursion (wide jaw opening) and in postural position (near occlusion). These data, plus published data on sarcomere lengths in rabbit jaw muscles, were used to evaluate conflicting hypotheses about the factors which regulate serial sarcomere number in striated muscles. According to the most successful hypothesis, sarcomere number is adjusted so as to achieve an optimum sarcomere length when the muscle is experiencing a high level of tension. Most often, this occurs at jaw positions where the muscle is electrically active.

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Left ventricular free wall and intraventricular pressure-sarcomere length distributions

Grimm¹,

Lin²,

Grimm³

1980

American Journal of Physiology-Heart and Circulatory Physiology

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Sarcomere lengths were measured after pentobarbital anesthesia at five sites through the wall of the formaldehyde solution-fixed cadmium-arrested closed-chest rat left ventricle. Sections (250 micron) were cut from endocardium to epicardium with a freezing microtome. Selected sections were sonified, mixed with a gelatin-water solution, and placed on a glass slide. Sarcomere lengths were measured with an optical microscope at five sites through the wall. Sarcomere lengths progressively increased from section I (endocardium site) to section III (middle site) and IV. Sarcomere lengths were again shorter in section V (epicardium site). There was a progressive increase in sarcomere lengths with increasing intraventricular pressures. Sarcomere lengths did not significantly exceed optimum length.

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Finite-Element Model for the Mechanical Behavior of the Left Ventricle

Janz

Grimm

1972

Circulation Research

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A finite-element model is used to analyze the mechanical behavior of the left ventricle. The ventricle is treated as a heterogeneous, linearly elastic, thickwalled solid of revolution. The inner third of the ventricular wall is assumed to be transversely isotropic with a longitudinal Young's modulus, transverse modulus, and shear modulus of 60 g/cm 2 , 30 g/cm 2 , and 15.5 g/cm 2 , respectively. In the outer two-thirds of the ventricular wall the myocardium is assumed to be isotropic with a Young's modulus of 60 g/cm 2 . Polsson's ratio is assumed to be equal to 0.45 throughout the ventricular wall. The valvular ring at the base of the ventricle is simulated by a homogeneous layer cf collagen. The model appears to predict gross free-wall deformation in the left ventricle of the potassium-arrested rat heart fixed in situ. The presence of a relatively compliant transversely isotropic region near the endocardial surface results in significantly lower axial and circumferential stresses in this region than are present in a homogeneous, isotropic model. The presence of a simulated valvular ring results in a concentration ofrelatively large stresses near the base of the ventricle.

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Properties of Myocardium in Cardiomegaly

Grimm

Kubota

Whitehorn

1963

Circulation Research

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The adult rat's ventricular myocardium is able to increase its mass markedly while maintaining its unit quality. It does so by maintaining constant the design of the sarcomeres: an increase in length is accomplished by the addition of sarcomeres in series; an increase in tension production is accomplished by the addition of more cross-sectional area of a uniform quality. This was shown by the almost constant concentration of the contractile protein, actomyosin, as well as by the histologic evidence of the constancy in the sarcomere lengths. Functional support was obtained by the finding of an identity in the parameters of the length-tension curves; the curves differed only in the absolute magnitude of the tensions, a difference that completely disappeared when suitable corrections were made for the size of the muscle. The electrical parameters also indicated a lack of change in the quality of the excitatory membrane phenomena. However, some data were presented that suggest that the myocardium may show altered properties dependent on the age of the animal. No evidence was found in support of the concept of detrimental consequences at least with this degree of cardiomegaly. It is rather concluded that this degree of cardiomegaly is accomplished without change in the basic architecture, properties, or concentration of the contractile mechanism.

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Arthur F. Grimm

Functional heterogeneity in a multipinnate muscle

Regulation of sarcomere number in skeletal muscle: A comparison of hypotheses

Left ventricular free wall and intraventricular pressure-sarcomere length distributions

Finite-Element Model for the Mechanical Behavior of the Left Ventricle

Properties of Myocardium in Cardiomegaly

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