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Macroscopic Ca2+ -Na+ and K+ currents in single heart and aortic cells (1989)

Bkaily, G. ; Peyrow, M. ; Yamamoto, T. ; [et al.]

Springer

Molecular and cellular biochemistry 80 (1989), S. 59-72

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ISSN: 1573-4919

Keywords: heart cells ; aortic cells ; Ca2- current ; K+ current ; slow Na+ current ; Angiotensin II ; calcium blockers ; potassium blockers ; patch clamp

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology , Medicine

Notes: Summary The whole-cell voltage clamp technique was used to study the slow inward currents and K+ outward currents in single heart cells of embryonic chick and in rabbit aortic cells. In single heart cells of 3-day-old chick embryo three types of slow inward Na+ currents were found. The kinetics and the pharmacology of the slow INa, were different from those of the slow Ica in older embryos. Two types of slow inward currents were found in aortic single cells of rabbit; angiotensin 11 increased the sustained type and d-cAMP and d-cGMP decreased the slow transient component. Two types of outward K+ currents were found in both aortic and heart cells. Single channel analysis demonstrated the presence of a high single K+ channel conductance in aortic cells. In cardiac and vascular smooth muscles, slow inward currents do share some pharmacological properties, although the regulation of these channels by cyclic nucleotides and several drugs seems to be different.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00231004

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Dependence of biomechanical impedance upon living body structure (1987)

Oka, H. ; Yamamoto, T.

Springer

Medical & biological engineering & computing 25 (1987), S. 631-637

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ISSN: 1741-0444

Keywords: Biomechanical impedance ; Biomechanical properties ; Impedance ; Living body structure

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology , Medicine

Notes: Abstract A physical model for biomechanical impedance has already been proposed. This model is characterised by three impedance spectra: soft, intermediate and hard pattern. An impedance spectrum of the body surface represents mostly the soft pattern, The formative mechanisms of all three patterns have been unsolved until now. Because the physical model is expressed by experimental equations, its theoretical background is not apparent. In the paper a simulating material (simulator) is used, whose tactility is not unlike human skin, and the formative mechanism of biomechanical impedance is revealed through experiments on the simulator under various measuring conditions. The influences of the measuring circumstances, living body structure and physical constants of the body tissues on the experimental equations of the physical model are fully discussed. The formative mechanism of biomechanical impedance which represents the physical model is explained in terms of an equivalent mass, a dynamic equivalent stiffness, a dynamic viscosity and a composite characteristic. The dependence between body parts from which the measurements are taken and soft, intermediate and hard patterns are demonstrated.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF02447330

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Impact response of periodontal tissues (1988)

Oka, H. ; Yamamoto, T. ; Kawazoe, T. ; [et al.]

Springer

Medical & biological engineering & computing 26 (1988), S. 260-266

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ISSN: 1741-0444

Keywords: Acceleration response ; Impact response ; Mechanical impedance ; Periodontal tissues ; Single degree-of-freedom model ; Tooth mobility

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology , Medicine

Notes: Abstract A new impact response method using a fracture of a pencil-lead to produce an excitation pulse is proposed. Impact excitations (rectangular pulse, triangular pulse and half-sine pulse) are strictly given in physical and mathematical definitions and complete solutions to the impact excitations are provided for Noyes' model of the human tooth. When a relatively long triangular pulse is applied to Noyes' model, which can express the physical characteristic of periodontal tissues, a sinusoidal damped vibration of a single degree-of-freedom model is approximately obtained. The acceleration response is characterised by the physical parameters (T, δ and Ao) and mechanical elements (m1, c1 and k) of which a single degree-of-freedom model is composed. By means of this method, the values of the parameters and elements in the cases of healthy maxillary, healthy mandibular and pathological mandibular incisors are obtained. The single degree-of-freedom model can express the high-frequency spectra of Noyes' model. The pathological tooth is characterised by a longer damped time constant and a larger acceleration maximum. This impact response method can effectively be applied to clinical diagnosis in view of the physical parameters and mechanical elements which have been derived.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF02447078

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Experimental modelling of biomechanical impedance characteristics (1986)

Yamamoto, T. ; Oka, H.

Springer

Medical & biological engineering & computing 24 (1986), S. 493-498

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ISSN: 1741-0444

Keywords: Biomechanical impedance ; Biomechanical properties ; Impedance ; Modelling of human body

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology , Medicine

Notes: Abstract New experimental modelling of biomechanical impedance is proposed. The parameters which express the impedance characteristics are simply determined by impedance measurement. Audiofrequencies below about 1000 Hz and comparatively lower preloads (below about 6370 kg m−2) are chosen as the research domain. This model, however, can express wide range of body surface impedance not only in soft but also in stiff and intermediate tissues. It will never introduce the impracticably ideal conditions found in the mathematcial models proposed to date. Furthermore the parameters which express the model cannot be determined by impedance measurement alone. The impedance Z(jw) is expressed in two parts: the impedance Z1 (jw) at a higher frequency including a complex mass and the impedance Z2(jw) at a lower frequency including a complex compliance of Cole-Cole’s type. Z1(jw) is the property of body fluid and Z2(jw) is that of a viscoelastic body.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF02443965

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