[Radioprotective properties of isothiourea derivatives with NO-inhibitory mechanism of action].

The study of the radioprotective activity of S-[2-alkyl (aryl) sulfonyl]-S-ethyl derivatives of (vinyl)-isothiourea in (he model of the survival of mice exposed to gamma-radiation at a dose of 10 Gy has shown that the incorporation of additional sulfur-containing groups does not increase the radioprotective properties of compounds. In contrast to aminoalkil thiols, the effectiveness of the radiation protection action of the isothiourea (ITU) derivatives studied clearly correlates with the NO-inhibitory activity. This fact allowed us to assume that the radioprotective effect of S-substituted ITU caused inhibition of the endogenous synthesis of NO, which promotes the development of circulatory hypoxia, and that a further search for the radioprotective agents in this class of chemicals should be considered as the search for effective inhibitors of NO-synthase (NOS).

[Protective effect of 2,3-butanedione monooxime on ischemic myocardium of rats].

Effects of 2,3-butanedione monoxime (BDM), an ATPase inhibitor, on ischemia-reperfusion myocardial injury were examined in isolated working rat hearts perfused in vitro. Following cardiac arrest induced by cardioplegic solution, global ischemia was produced for 30 min. In untreated hearts, reperfusion for 45 min resulted in an incomplete recovery of cardiac pump function.

[Contractile properties and creatine kinase activity of myofilaments after ischemia and reperfusion of the rat heart].

The state of myofibril creatinkinase and contractile properties of chemically skinned myocardial fibers of rat after 70-90 min ischemia and 15-30 min reperfusion was studied. In spite of sharp fall in the total creatinkinase activity in the tissue, the enzyme activity in myofibrils does not change greatly. Ischemia does not change the functional abilities of myofibril creatinkinase as well as characteristics of Ca-activated contraction of skinned fibers.

[Fractionation of fragments of skeletal muscle sarcoplasmic reticulum according to their sensitivity to caffeine].

Sarcoplasmic reticulum fragments were fractionated according to the ability of caffeine to selectively block Ca2+ uptake in the population of caffeine-sensitive membranes. The membrane suspension was loaded with calcium in the presence of oxalate, Mg-ATP and caffeine, after which the Ca2+-loaded caffeine-sensitive fragments were separated by sucrose density gradient centrifugation. In Ca2+-unloaded fragments of the supernatant, the sensitivity to caffeine estimated by its ability to diminish the rate of Ca2+ uptake, Ca/ATP ratio and Ca-oxalate capacity amounted to 91-93%.