Search results for "muscle cross-sectional area"

showing 3 items of 3 documents

Fitness and lean mass increases during combined training independent of loading order.

2014

Although the benefits of combined endurance (E) and strength (S) training for the development of physical fitness and health are well known, scientific examination of the effect of loading order when E and S are combined into the same training session (E+S vs S+E) is rare. This study investigated the effects of moderate frequency E+S versus S+E training on physical fitness, body composition, and blood lipids.Physically active and healthy young men performed E+S (n = 16) or S+E (n = 18) training 2-3 times a week for 24 wk. Endurance (by incremental bike test) and strength (by dynamic leg press) performance as well as body composition (by dual-energy x-ray absorptiometry), muscle cross-sectio…

AdultMalemedicine.medical_specialtyOrder effecteducationPhysical fitnessPhysical Therapy Sports Therapy and RehabilitationTriglycerides bloodQuadriceps MuscleYoung AdultAbsorptiometry PhotonThinnessmedicineAerobic exerciseHumansOrthopedics and Sports MedicineMuscle Strengthta315TriglycerideskehonkoostumusMathematicsAdiposityUltrasonographybusiness.industryCholesterol HDLTraining (meteorology)Resistance TrainingHuman physiologyCholesterol LDLmuscle cross-sectional areaaerobinen harjoitteluDiet Recordsconcurrent endurance and strength trainingPhysical FitnessLean body massPhysical therapyBody CompositionExercise TestPhysical Enduranceorder effectresistance trainingUltrasonographyhypertrophybusinessEnergy IntaketerveysPhysical Conditioning HumanMedicine and science in sports and exercise
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Effects of morning versus evening combined strength and endurance training on physical performance, muscle hypertrophy, and serum hormone concentrati…

2016

This study investigated the effects of 24 weeks of morning versus evening same-session combined strength (S) and endurance (E) training on physical performance, muscle hypertrophy, and resting serum testosterone and cortisol diurnal concentrations. Forty-two young men were matched and assigned to a morning (m) or evening (e) E + S or S + E group (mE + S, n = 9; mS + E, n = 9; eE + S, n = 12; and eS + E, n = 12). Participants were tested for dynamic leg press 1-repetition maximum (1RM) and time to exhaustion (Texh) during an incremental cycle ergometer test both in the morning and evening, cross-sectional area (CSA) of vastus lateralis and diurnal serum testosterone and cortisol concentrati…

MaleTime FactorsHydrocortisonePhysiologyEndocrinology Diabetes and MetabolismMuscle DevelopmentQuadriceps MuscleMuscle hypertrophy0302 clinical medicineTestosteroneLeg pressFatigueTestosteroneMorningNutrition and DieteticsGeneral MedicineCircadian Rhythmconcurrent trainingorder effecttime-of-dayAdultmedicine.medical_specialtyPatient DropoutsEveningWeight LiftingAthletic Performancecortisol03 medical and health sciencesEndurance trainingPhysiology (medical)Internal medicinemedicineHumansMuscle StrengthMuscle SkeletalExercisebusiness.industryResistance TrainingHypertrophy030229 sport sciencesmuscle cross-sectional areaBicyclingEndocrinologyPhysical performanceExercise TestPhysical Endurancetestosteronibusiness030217 neurology & neurosurgeryHormoneApplied Physiology, Nutrition, and Metabolism
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Muscle cross-sectional area and structural bone strength share genetic and environmental effects in older women

2009

The purpose of this study was to estimate to what extent muscle cross-sectional area of the lower leg (mCSA) and tibial structural strength are influenced by common and trait-specific genetic and environmental factors. pQCT scans were obtained from both members of 102 monozygotic (MZ) and 113 dizygotic (DZ) 63- to 76-yr-old female twin pairs to estimate the mCSA of the lower leg, structural bending strength of the tibial shaft (BSIbend), and compressive strength of the distal tibia (BSIcomp). Quantitative genetic models were used to decompose the phenotypic variances into common and trait-specific additive genetic (A), shared environmental (C), and individual environmental (E) effects. The …

naisetikääntyminenympäristötekijätagingLihaksen poikkipinta-alaluun vahvuusbone strengthgeneettiset tekijätmuscle cross-sectional area
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