The lipophilic cationic radiotracer 99m Tc-sestamibi, known to be concentrated within mitochondria, is widely used for myocardial perfusion and to a lesser extent for muscle metabolism imaging. However, the exact distribution pattern in skeletal muscle has not been yet studied in detail. The present study aims to investigate the 99m Tc-sestamibi uptake in rat skeletal muscle and myocardium in relation to their metabolic characteristics. 99m Tc-sestamibi was i.v. administered in twenty adult male Wistar rats and uptake, as percent of injected dose per tissue gram (%ID/g), in the myocardium, soleus, extensor digitorum longus and gastrocnemius muscles was assessed 2 h after the injection. Muscle uptake was also correlated with myocardial uptake, muscle weight and body weight. Skeletal muscle 99m Tc-sestamibi uptake was a small (9-16 %) fraction of that found in myocardium (1.71 ± 0.63 %ID/g). Among the three hindlimb muscles considered, the slow-oxidative soleus muscle showed the highest uptake (0.28 ± 0.16 %ID/g). Metabolically diverse parts of the gastrocnemius muscle showed different uptake. Skeletal muscle uptake was positively correlated with myocardial uptake and both were negatively correlated with tissue and body weight. Skeletal muscle and myocardium 99m Tc-sestamibi uptake is related to their metabolic profile. Myocardium, with an exceptional rich mitochondrial concentration, shows much higher 99m Tc-sestamibi uptake compared to skeletal muscles. Among muscles, uptake is dependent on their mitochondrial content. Evidence of matching exists between myocardial and muscle uptake, and both are size-dependent., G. Arsos ... [et al.]., and Obsahuje seznam literatury
Beta-hydroxy-beta-metylbutyrát (HMB) je metabolitem leucinu, jenž vykazuje antikatabolické účinky a příznivě ovlivňuje imunitní systém. Mechanismus účinku nebyl dosud zcela objasněn. HMB může sloužit jako zdroj pro syntézu cholesterolu, zřejmě zasahuje také do ubikvitin-proteazomového proteolytického systému. HMB je užíván jako potravinový doplněk při silovém tréninku, zejména pro nárůst síly a množství netukové tkáně. V posledních letech se také testuje jako součást terapie kachexie různé etiologie (např. nádory, AIDS)., Beta-hydroxy-beta-methylbutyrate (HMB) is the leucine metabolite, which shows anti-catabolic effect and beneficially affects the immune system. The mechanism of action is still not fully understood. HMB may serve as the source for cholesterol synthesis and it probably affects the ubiquitin-proteasome proteolytic system. HMB is used as a dietary supplement during resistance-training, especially for increase of power and non-fat body mass. It has been also tested in recent years as a part of cachexia treatment (cancer, AIDS, etc.)., Miroslav Kovařík, Tomáš Muthný, Milan Holeček, and Lit.: 33
Derivative of 6-methyluracil, selective cholinesterase inhibitor C-547 potentiates miniature endplate currents (MEPCs) in rat external intercostal muscles (external ICM) more effectively than in internal intercostal muscles (internal ICM). Effect of the C-547 on intercostal muscles was compared with those on extensor digitorum longus (EDL) and diaphragm muscles. Half-effective concentrations for τ of MEPC decay arranged in increasing order were as follows: EDL, locomotor muscle, most sensitive = 1.3 nM, external ICM, inspiration muscle = 6.8 nM, diaphragm, main inspiration muscle = 28 nM, internal ICM, expiration muscle = 71 nM. External ICM might therefore be inhibited, similarly as the limb muscles, by nanomolar concentrations of the drug and do not participate in inspiration in the presence of the C-547. Moreover, internal ICM inhibition can hinder the expiration during exercise-induced fast breathing of C-547-treated experimental animals., K. Petrov ... [et al.]., and Obsahuje seznam literatury
Kardiovaskulární komplikace obezity jsou tradičně pokládány za významnou komplikaci obezity. Obezita sama ale není pravděpodobně přímo příčinou rozvoje aterosklerózy ani ischemické choroby srdeční. Ta vzniká především nepřímo vlivem metabolických komplikací obezity, zejména diabetu a metabolického syndromu. Nepochybný je však i trombogenní potenciál obezity, který se může podílet jak na embolizacích, tak na rozvoji aterosklerózy. S kardiologií je naopak spojován fenomén paradoxu obezity, situace, v níž mají obézní lepší prognózu než štíhlí. To se týká selhávání srdce i některých dalších kardiovaskulárních onemocnění. Nová je koncepce hormonů svalové tkáně – myokinů, které mají rozsáhlé protektivní vlivy na organizmus a pravděpodobně i na srdce. Zda je srdce rovněž zdrojem myokinů, je zatím nejisté. Nepochybný význam má však epikardiální a perikardiální tuk. U epikardiálního tuku převládají pravděpodobně spíše vlivy pro myokard protektivní. I tento tuk může podléhat zánětu a produkovat i faktory myokard poškozující. Vztah zejména množství epikardiálního tuku k postižení koronárních tepen a srdce je spíše patogenní. Dnes rozhodně platí, že obezita přináší více komplikace metabolické a onkologické než kardiovaskulární a přesné rozdělení jak patogenně či ochranně může v kardiologii působit tuková tkáň, vyžadují ještě další výzkum. Rozhodně však lze uzavřít, že tuk, jak celkový, tak v okolí srdce, může za určitých okolností srdci i prospívat., Cardiovascular complications of obesity are traditionally considered an important complication of obesity. Obesity itself is probably not direct cause of atherosclerosis or coronary heart disease. This may occur indirectly in metabolic complications of obesity, especially diabetes and metabolic syndrome. However, thrombogenicity potential of obesity contributes to embolism and atherosclerosis development. In cardiology is well-known a phenomenon of obesity paradox when obese patients have better prognosis than thin. This is the case of heart failure and some other cardiovascular diseases. Recently, a new concept has emerged of myokines – hormones from muscle tissue that have extensive protective effects on organism and probably on heart. Whether heart is a source of myokines is uncertain. However, undoubted importance has epicardial and pericardial fatty tissue. The epicardial fatty tissue has mainly protective effects on myocardium. This fatty tissue may produce factors of inflammation affecting the myocardium. Relationship between amount of epicardial fatty tissue and coronary heart disease is rather pathogenic. Currently, it is certain that obesity brings more metabolic and cancer complications than cardiovascular and accurate contribution to pathogenic or protective character of fatty tissue in cardiology requires further research. Nevertheless, the conclusion is that adipose tissue of organism and around the heart may be in some circumstances beneficial., and Štěpán Svačina
Antiorthostatic hindlimb suspension (unloading) decreased the resting membrane potential (RMP) of skeletal muscle fibers in fast extensor digitorum longus (EDL) and slow soleus (SOL) muscle of the rat by about 10 % within 7 days and more. Inactivation of the membrane Na+,K+-pump by ouabain brought about similar depolarization as unloading. The increased sodium permeability of the membrane was excluded as the major cause of this depolarization by experiments in which TRIS was substituted for Na+ in the medium. On the other hand, the decrease in the electrogenic participation of the Na+,K+-pump is apparently one of the causes of RMP decrease during hypogravity, in EDL muscle in particular., O. Tyapkina ... [et al.]., and Obsahuje seznam literatury