The effects of thyroid state on sarcomere dynamics of ventricular cells and contraction of papillary muscles in the rat heart.

Diastolic sarcomere length, amplitude of maximal sarcomere shortening, maximal rate of sarcomere shortening, maximal rate of sarcomere re-lengthening, time to peak sarcomere shortening and trans-sarcolemmal ion currents were measured in isolated ventricular cells from euthyroid, hypothyroid and hyperthyroid rats. The data were compared with the developed tension and time to peak tension of papillary muscles. The diastolic sarcomere length was not affected by the changes in thyroid state. Hypothyroidism led to an increased time to peak sarcomere shortening, an increased time to peak tension of the papillary muscle, and a depression of the maximal rates of shortening and elongation of the sarcomeres. Changes in dynamics of the sarcomere and contraction of papillary muscle did not occur in parallel under the influence of hyperthyroidism. In comparison with the euthyroid state, the time to peak tension was shortened and amplitude of shortening of the sarcomere was increased. The time to peak shortening of the sarcomere and developed tension of papillary muscle remained unaltered. In cardiac cells, hypothyroidism was associated with a decreased slow Ca2+ current and hyperthyroidism with an increased slow Ca2+ current. In contrast to euthyroid and hypothyroid cardiac cells, the hyperthyroid cardiomyocytes exhibited a trans-sarcolemmal transient inward current after repolarization. Both hypothyroidism and hyperthyroidism resulted in a depressed potentiation of sarcomere shortening and myocardial developed tension after resting.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of stimulation frequency responses and calcium dependency of functional parameters in hyperthyroid rat ventricular papillary muscles.

The effects of stimulation frequency (0.2-1.5 Hz) and extracellular calcium concentration ([Ca2+]o) (0.6-15.0 mM) on the contractile function of thin papillary muscles of euthyroid and hyperthyroid rats were studied. Hyperthyroidism led to a decrease in developed tension (DT) and time to peak tension (TPT), but it exhibited no influence on the maximal rates of contraction (+dT/dt) and relaxation (-dT/dt). Also, the mean rates of contraction were similar in euthyroid and hyperthyroid muscle groups. The increase in stimulation frequency brought about a marked decrease in DT, +dT/dt, and -dT/dt of euthyroid papillary muscles at lower frequencies in comparison to papillary muscles in the hyperthyroid group. At stimulation frequencies above 1.0 Hz, the absolute and relative levels of DT and -dT/dt of hyperthyroid myocardium were elevated over euthyroid preparations. At the same time, TPT was unchanged in any of the muscle groups. Hyperthyroidism modulated the relationships between contractile parameters and [Ca2+]o. At a [Ca2+]o of 1.0-4.0 mM, the DT of hyperthyroid papillary muscles was lower than in euthyroid muscle. At 4.0 and 8.0 mM of [Ca2+]o, the equal values of maximal DT were registered for euthyroid and hyperthyroid papillary muscles, respectively. An increase in the [Ca2+]o in the range of 1.0-15.0 mM was accompanied by an increase in TPT of both muscle groups, but to a greater extent in hyperthyroid myocardium. In conclusion, the myocardium of hyperthyroid rat appeared to exhibit decreased sensitivity to calcium as well as to the negative inotropic effect of enhanced stimulation frequency. Alterations of the processes of transsarcolemmal movement and intracellular recycling of Ca2 may be implicated.

[Characteristics of the frequency dependence of the contraction force in the hyperthyroid rat myocardium]. / Osobennosti chastotnoi zavisimosti sily sokrashcheniia gipertireoidnogo miokarda krysy.

We have studied the effect of increased contraction frequency (from 0.2 to 1.5 Hz) on developed tension (delta T) in thin papillary muscles of eu- and hyperthyroid rats. The results show that while increasing the contraction frequency, the delta T of euthyroid papillary muscles decreased at lower frequencies than in hyperthyroid group. Also, at the contraction frequencies above 1.0 Hz the absolute and relative levels of delta T of hyperthyroid myocardium were less decreased than in euthyroid preparations. In conclusion, the myocardium of hyperthyroid rat is characterized by a decreased sensitivity to negative inotropic effect of enhanced contraction frequency. In is probably due to the acceleration of the processes of intracellular Ca2+ recycling during diastole under the influence of hyperthyroidism.