ABSTRACT
Muscle mass is the major deposit of protein molecules with dynamic turnover between net protein synthesis and degradation. In human subjects, invasive and non-invasive techniques have been applied to determine their skeletal muscle catabolism of amino acids at rest, during and after different forms of physical exercise and training. The aim of this review is to analyse the turnover flux and the relative oxidation rate of different types of muscle proteins after one bout of exercise as well as after resistance and endurance condition of training. Protein feeding in athletes appears to be a crucial nutrition necessity to promote the maintenance of muscle mass and its adaptation to the need imposed by the imposed technical requirements. In resting human individuals, there commended protein daily allowance is about 0.8 g (dry weight) kg−body weight per 24 h knowing that humans are unable to accumulate protein stores in muscle tissues. Nevertheless, practical feeding recommendations related to regular exercise practice are proposed to athletes by different bodies in order to foster their skills and performance. This review will examine the results obtained under endurance and resistance type of exercise while consuming single or repeated doses of various ingestions of protein products (full meat, essential amino acids, specific amino acids and derivatives, vegetarian food). From the scientific literature, it appears that healthy athletes(and heavy workers) should have a common diet of 1.25 g kg−24 h to compensate the exercise training muscle protein degradation and their resyn thesis within the following hours. A nitrogen-balance assay would berecommended to avoid any excessive intake of protein. Eventually, a daily equilibrated food intake would beof primer importance versus inadequate absorption of some specific by-products.
Subject(s)
Humans , Male , Female , Child , Adolescent , Adult , Amino Acids/biosynthesis , Amino Acids/metabolism , Exercise , Muscle ProteinsABSTRACT
Different fuels are available to generate ATP for muscle activities during sport events. Glycogen from striated muscles and liver stores may be converted to lactic acid or almost completely oxidized to carbon dioxide (CO2), triacylglycerol within the muscle itself and fatty acids from adipose tissue could be converted to CO2 in acting muscles, some free amino acids can be released within the muscle itself and from intestinal stores to sustain the amount of ATP generation indispensable for muscle contraction. All single biochemical reactions, but one, need one or several enzymes to activate the conversion of a substrate into a product. The energy transformation in biochemical reactions is led by application of so-called free energy. Reversible and non-reversible reactions within a metabolic pathway are dependent on specific enzymes near or far from equilibrium. Allosteric enzymes are regulatory enzymes that provide the direction in the pathway. A regulatory enzyme is either activated or inhibited by small regulators (ligands). A reversible substrate cycle between A and B is catalyzed by two enzymes with different fluxes. The need of ATP production for muscle contraction is under the leadership of regulatory enzymes and available substrate stores. The improvement of adapted metabolic reactions under sport training depends on the appropriate increase of regulatory enzymes within the glycolytic and oxidative pathways. The amount of some specific enzymes is increased by training in order to improve the maximum activity of the metabolic pathway. Unfortunately, several publications do not precisely implicate the appropriate enzyme(s) to explain or reject the adaptation induced by the training schedule. A few examples will illustrate the factual interpretation and the inadequate allegation...
Subject(s)
Humans , Adenosine Triphosphate , Enzymes , Glycogen , Resistance TrainingABSTRACT
Objetivos. El trasplante celular para la regeneración del miocardio está limitado por la escasa viabilidad del injerto y la baja retención celular. En la miocardiopatía isquémica la matriz extracelular está profundamente alterada, por consiguiente, sería importante asociar un procedimiento para regenerar las células miocárdicas y restaurar la función de la matriz extracelular. En este estudio clínico, fue evaluada la terapia celular intrainfarto asociada a una matriz de colágeno sembrada con células e implantada sobre ventrículos infartados.Métodos. En 15 pacientes (54,2±3,8 años de edad) que presentaban cicatrices miocárdicas postisquémicas en el ventrículo izquierdo (VI) y con indicación de cirugía de revascularización miocárdica, se implantaron, durante la operación, células de la médula ósea mononucleares autólogas (CMO) en la cicatriz. Se agregó sobre esa zona infartada una matriz de colágeno tipo I con el mismo número de CMO
Resultados. No hubo mortalidad ni eventos adversos relacionados (seguimiento 15±4,2 meses). La clase funcional según la New York Heart Association (NYHA) mejoró de 2,3±0,5 a 1,4±0,3 (p=0,005). El volumen de fin de diástole del VI evolucionó de 142±24 a 117±21 mL (p=0,03), el tiempo de desaceleración del llenado del VI mejoró aumentando de 162±7 mseg a 196±8 mseg (p=0,01). El espesor del área cicatrizada progresó de 6±1,4 a 9±1,5 mm (p=0,005). La fracción de eyección (FE) mejoró de 25±7 a 33±5% (p=0,04).Conclusiones. La inyección intramiocárdica de células de médula ósea y la fijación simultánea de una matriz sembrada con progenitores celulares (stem cells) sobre el epicardio fue simple y sin complicaciones. La matriz de colágeno aumento el espesor de la zona del infarto con nuevos tejidos viables, limitando la dilatación ventricular y mejorando la función diastólica. Estos resultados positivos no pueden ser absolutamente relacionados a las células y la matriz, pues se asociaron puentes de revascularización coronaria. En conclusión, la ingeniería de tejidos puede extender las indicaciones y beneficios de la terapia con células madre en cardiología, convirtiéndose en un camino prometedor para la creación de un miocardio bioartificial
Objectives. Stem cell therapy for myocardial regeneration is limited by poor graft viability and low cell retention. In ischemic cardiomyopathy the extracellular matrix is pathologically modified, therefore it could be important to associate a procedure aiming at regenerating both, myocardial cells and the extracellular matrix. We evaluated intrainfarct cell therapy associated with a cell-seeded collagen scaffold grafted onto infarcted hearts.Methods. In 15 patients (aged 54.2±3.8 years) presenting LV postischemic myocardial scars and with indication for a single off-pump-CABG, autologous mononuclear bone marrow cells (BMC) were implanted during surgery in the scar. A 3D collagen type I matrix seeded with the same number of BMC was grafted onto the infarction zone.Results. There was no mortality and any related adverse events (follow-up 15±4.2 months). NYHA FC improved from 2.3±0.5 to 1.4±0.3 (p=0.005). LV end-diastolic volume evolved from 142±24 to 117±21 mL (p=0.03), LV filling deceleration time improved from 162±7 ms to 196±8 ms (p=0.01). Scar area thickness progress from 6±1.4 to 9±1.5mm (p=0.005). EF improved from 25±7 to 33±5% (p=0.04).Conclusions. Simultaneous intramyocardial injection of mononuclear bone marrow cells and fixation of a BMC-seeded matrix onto the epicardium is feasible and safe. The cell seeded collagen matrix seems to increase the thickness of the infarct scar with viable tissues and help to normalize cardiac wall stress in injured regions, thus limiting ventricular remodelling and improving diastolic function. Patients improvements can not be conclusively related to the cells and matrix due to the association of CABG. Cardiac tissue engineering should extend the indications and benefits of stem cell therapy in cardiology, becoming a promising way for the creation of a bioartificial myocardium