Muscle size and strength are increased following walk training with restricted venous blood flow from the leg muscle, Kaatsu-walk training.
about
Morphological and functional relationships with ultrasound measured muscle thickness of the lower extremity: a brief reviewThe molecular basis for load-induced skeletal muscle hypertrophyLow intensity resistance exercise training with blood flow restriction: insight into cardiovascular function, and skeletal muscle hypertrophy in humansLow-load high volume resistance exercise stimulates muscle protein synthesis more than high-load low volume resistance exercise in young men.Optimizing the benefits of exercise on physical function in older adults.Designing pharmaceutical trials for sarcopenia in frail older adults: EU/US Task Force recommendations.Effects of leg blood flow restriction during walking on cardiovascular function.Activation of mTORC1 signaling and protein synthesis in human muscle following blood flow restriction exercise is inhibited by rapamycin.Effects of handgrip training with venous restriction on brachial artery vasodilation.Effects of high-intensity blood flow restriction exercise on muscle fatigue.Early detection of atrophy of foot muscles in Chinese patients of type 2 diabetes mellitus by high-frequency ultrasonography.Relationship between muscle mass and muscle strength, and the impact of comorbidities: a population-based, cross-sectional study of older adults in the United StatesMyogenic and proteolytic mRNA expression following blood flow restricted exerciseEfficacy of blood flow-restricted, low-load resistance training in women with risk factors for symptomatic knee osteoarthritis.Sarcopenia: An emphasis on occlusion training and dietary protein.Effect of nordic walking and water aerobics training on body composition and the blood flow in lower extremities in elderly womenExercise, amino acids, and aging in the control of human muscle protein synthesis.Reactive hyperemia is not responsible for stimulating muscle protein synthesis following blood flow restriction exercise.Neighborhood Integration and Connectivity Predict Cognitive Performance and DeclineBlood flow restricted exercise and vascular function.Effectiveness of blood flow restricted exercise compared with standard exercise in patients with recurrent low back pain: study protocol for a randomized controlled trial.Possibility of leg muscle hypertrophy by ambulation in older adults: a brief review.The Effects of Vascular Occlusion Training on Respiratory Exchange Ratio and Energy Expenditure When Coupled With Cardiovascular TrainingBlood flow-restricted exercise in space.The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restrictionEffects of Low-Intensity Cycle Training with Restricted Leg Blood Flow on Thigh Muscle Volume and VO2MAX in Young MenMetabolic and cardiovascular responses to upright cycle exercise with leg blood flow reduction.Legs and trunk muscle hypertrophy following walk training with restricted leg muscle blood flowHuman muscle gene expression following resistance exercise and blood flow restriction.Physiologic and molecular bases of muscle hypertrophy and atrophy: impact of resistance exercise on human skeletal muscle (protein and exercise dose effects).Hormone responses to an acute bout of low intensity blood flow restricted resistance exercise in college-aged females.Hemodynamic responses are reduced with aerobic compared with resistance blood flow restriction exercise."Slow walking with turns" increases quadriceps and erector spinae muscle activity.Restricted Blood Flow Exercise in Sedentary, Overweight African-American Females May Increase Muscle Strength and Decrease Endothelial Function and Vascular Autoregulation.Effects of strength training with blood flow restriction on torque, muscle activation and local muscular endurance in healthy subjects.Anabolic processes in human skeletal muscle: restoring the identities of growth hormone and testosterone.Potential safety issues with blood flow restriction training.Unilateral lower limb suspension: integrative physiological knowledge from the past 20 years (1991-2011).Exercise intensity and muscle hypertrophy in blood flow-restricted limbs and non-restricted muscles: a brief review.Potential mechanisms for a role of metabolic stress in hypertrophic adaptations to resistance training.
P2860
Q26738990-21FFF034-81BE-464F-9276-8CA857D81843Q26829477-671A30F1-4D69-4116-AF9E-8EAD4751901CQ28080560-783E09D5-5C8E-4B45-B262-28458692C60EQ33658994-C6B20D21-EF15-48B2-A93D-25E305FD3FC4Q33779905-22E7B047-FE72-4F30-A2D2-01CF9510D385Q33828935-FF190940-C941-4F41-A993-013CAAC44726Q33926356-1AB0E85A-ABD1-48F1-A775-B41813DE7B6DQ33976384-59569D0E-2B89-4D8E-B3AF-9821D71E519EQ33990373-7F28C567-9E64-4496-94CF-0D56A90A2AFBQ33996548-E37917F1-59EA-4047-A55D-EEA674AAE27BQ34073266-6D329F70-07EE-4427-A1EE-D689F39F7F7BQ34832463-CA908058-92A8-4421-8368-D4DD9E48DD4FQ34985057-6A9EF6FC-B14A-43F9-BD89-987C68DD9F7DQ35272357-D68B0659-E14D-4B01-8542-CF31DCF25E67Q35532443-D2452535-6BE8-4365-B9CA-1B6E56CEB021Q35557787-9CA00DFF-2538-48AC-B72D-398632AAA211Q35787793-3908C0EC-D80F-4D3E-9704-53850F57433DQ35994715-8575D408-7DF6-4E5E-B6F5-4B0782258A19Q36200844-33438C95-1F67-47E3-9BFA-59B19B14AC20Q36362563-9406222E-B0D8-4D6D-B11C-372751339D90Q36574761-A570469B-C6C5-4F63-A200-24714F8F32E2Q36749733-ACEEAB39-3DB9-48AE-8A2B-F10F3F2CB2DFQ36798531-1B972CE4-297D-4BF5-9A16-8D6C31C27116Q37008627-A501C970-303B-41AB-A2EC-2D0A8DB2D1EBQ37014382-7BEFA109-41D2-47A2-9508-CADDFFCC7155Q37143823-727F83AB-7417-415A-A1CC-48A284174103Q37143847-34D56F89-9B11-451F-A58E-D95F53C63713Q37144303-0BC45D82-02C7-45A5-9539-2AAD1C8A2858Q37383677-C0767F0E-D1EB-4DD5-8241-F156053F331FQ37486029-3DC2757F-3B12-4F4F-966E-F23BC1D201FAQ37570563-8F475931-873E-4FE8-B7D1-CC0FAE3D01FCQ37642429-85AB0967-E67B-4F99-AAB4-F20C3B6243DAQ37714753-D8343C8B-5EF7-42FB-A628-4D3DDB9761D9Q37731202-F971B11E-D76C-4689-97CF-A1FD26F79FCFQ37735080-8B43DDC2-9B2E-40D2-9FF4-D48FD868624FQ37801533-2BD2B16D-A9C4-4EB0-ADA6-205083C9B6A6Q37853590-20EF0B4F-AF04-4367-9068-FABF58278CD2Q37870816-9E092F68-95DC-44AE-9E8C-580B501FFF5DQ38017323-2DBEA024-52C2-4DD1-BBAD-049C496BB6D1Q38075849-B1123BD4-87C3-43A5-ABF8-A545480EFFFB
P2860
Muscle size and strength are increased following walk training with restricted venous blood flow from the leg muscle, Kaatsu-walk training.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
Muscle size and strength are i ...... muscle, Kaatsu-walk training.
@en
Muscle size and strength are i ...... muscle, Kaatsu-walk training.
@nl
type
label
Muscle size and strength are i ...... muscle, Kaatsu-walk training.
@en
Muscle size and strength are i ...... muscle, Kaatsu-walk training.
@nl
prefLabel
Muscle size and strength are i ...... muscle, Kaatsu-walk training.
@en
Muscle size and strength are i ...... muscle, Kaatsu-walk training.
@nl
P2093
P1476
Muscle size and strength are i ...... muscle, Kaatsu-walk training.
@en
P2093
Charles F Kearns
Takashi Abe
Yoshiaki Sato
P304
P356
10.1152/JAPPLPHYSIOL.01267.2005
P407
P577
2005-12-08T00:00:00Z