Altitude training and haemoglobin mass from the optimised carbon monoxide rebreathing method determined by a meta-analysis
about
Position statement--altitude training for improving team-sport players' performance: current knowledge and unresolved issues.Physiological Adaptations to Hypoxic vs. Normoxic Training during Intermittent Living HighTraining Diaries during Altitude Training Camp in Two Olympic Champions: An Observational Case Study.Rhodiola crenulata- and Cordyceps sinensis-based supplement boosts aerobic exercise performance after short-term high altitude training.AltitudeOmics: rapid hemoglobin mass alterations with early acclimatization to and de-acclimatization from 5260 m in healthy humans.The effects of hypobaric hypoxia on erythropoiesis, maximal oxygen uptake and energy cost of exercise under normoxia in elite biathletes.Comparison of "Live High-Train Low" in normobaric versus hypobaric hypoxiaAltitude Exposure at 1800 m Increases Haemoglobin Mass in Distance Runners.Pre-Altitude Serum Ferritin Levels and Daily Oral Iron Supplement Dose Mediate Iron Parameter and Hemoglobin Mass Responses to Altitude Exposure.Bayesian Estimation of Small Effects in Exercise and Sports ScienceThe effects of altitude/hypoxic training on oxygen delivery capacity of the blood and aerobic exercise capacity in elite athletes - a meta-analysis.Increased Hypoxic Dose After Training at Low Altitude with 9h Per Night at 3000m Normobaric Hypoxia.Same Performance Changes after Live High-Train Low in Normobaric vs. Hypobaric Hypoxia.Haemoglobin mass alterations in healthy humans following four-day head-down tilt bed restYin and yang, or peas in a pod? Individual-sport versus team-sport athletes and altitude training.Application of 'live low-train high' for enhancing normoxic exercise performance in team sport athletes.Iron Supplementation and Altitude: Decision Making Using a Regression Tree.Does 'altitude training' increase exercise performance in elite athletes?Effects of Altitude/Hypoxia on Single- and Multiple-Sprint Performance: A Comprehensive Review.Regulation of blood volume in lowlanders exposed to high altitude.Graded hypoxia and blood oxidative stress during exercise recovery.The Effect of 4 Weeks Fixed and Mixed Intermittent Hypoxic Training (IHT) on Respiratory Metabolic and Acid-base Response of Capillary Blood During Submaximal Bicycle Exercise in Male Elite Taekwondo Players.Improving team-sport player's physical performance with altitude training: from beliefs to scientific evidence.Stage racing at altitude induces hemodilution despite an increase in hemoglobin mass.Hemolysis during and after 21 days of head-down-tilt bed rest.The athlete's hematological response to hypoxia: A meta-analysis on the influence of altitude exposure on key biomarkers of erythropoiesis.Do male athletes with already high initial haemoglobin mass benefit from 'live high-train low' altitude training?The Effect of Natural or Simulated Altitude Training on High-Intensity Intermittent Running Performance in Team-Sport Athletes: A Meta-Analysis.Live high-train low guided by daily heart rate variability in elite Nordic-skiers.Influence of combined iron supplementation and simulated hypoxia on the haematological module of the athlete biological passport.Endurance, aerobic high-intensity, and repeated sprint cycling performance is unaffected by normobaric "Live High-Train Low": a double-blind placebo-controlled cross-over study.Individual hemoglobin mass response to normobaric and hypobaric "live high-train low": A one-year crossover study.Altitude training causes haematological fluctuations with relevance for the Athlete Biological Passport.High altitude, prolonged exercise, and the athlete biological passport.Heat acclimation attenuates physiological strain and the HSP72, but not HSP90α, mRNA response to acute normobaric hypoxia.Oxygen delivery is not a limiting factor during post-exercise recovery in healthy young adults.Live high, train low - influence on resting and post-exercise hepcidin levels.The Effects of Altitude Training on Erythropoietic Response and Hematological Variables in Adult Athletes: A Narrative Review.Determination of hemoglobin mass in humans by measurement of CO uptake during inhalation of a CO-air mixture: a proof of concept studyReplicating measurements of total hemoglobin mass (tHb-mass) within a single day: precision of measurement; feasibility and safety of using oxygen to expedite carbon monoxide clearance
P2860
Q33460125-09DB6E24-2C0A-44E9-92A8-67D3C81A3BF3Q33741372-C7138E67-DEC2-476A-909B-4B36C32EF755Q34019518-4C813D5C-F456-4D2E-99D1-D3B3E2E9CACBQ34240805-B56A171E-10AF-421A-98B8-02EA8F626CB4Q34278320-16D46C2C-BF5E-456B-A5BE-036A63772FE8Q34528912-0BAF26CE-505A-4158-9636-D0039CFFA170Q34724191-D39545F9-2874-4CC1-BF8E-1B090C3A0F0BQ35583670-C9EEFD46-7165-4E6E-8D1E-24ED29D940B7Q35742843-2744ECD3-B8ED-4779-ACB2-19F5FDB02935Q35988271-4DB071FE-185B-4F0F-A25B-21DE583E37C9Q36051435-54D34885-A091-4369-BA6C-FBB8B2CDFF5DQ36311117-93261749-9D2E-4903-B3F7-6B8DBF5CC3F7Q36809290-C8BF1228-A40F-48F5-B4AA-4A055F0C19A3Q36853220-408AAE02-C6A8-4249-AA3E-9B62ADDB1BDCQ37345881-E01AE1FC-C70B-45C4-BE90-5273A0370D92Q38213586-327696AE-A985-4B7F-897E-4AFC48477D4AQ38598459-2F7FC852-50F9-4948-8E41-5B28D08BCB88Q38833175-EC0EA3D9-F63E-4E68-A178-C09134ADD7D1Q39268859-8938F852-8594-444C-AB02-CF5C36DB379AQ39345054-24CBFDF7-FEA7-4584-AC00-CC8DA3613B48Q41076482-E084D6D7-DDCF-4CBB-836D-D5FA29446CC7Q41265600-33507F44-776A-4D3B-9348-DD252A095F63Q42733637-371395AC-EC3C-44D8-9EAA-FB5A3C6B8CABQ44752821-0A2CCC81-9C03-4A52-870B-0C421153B436Q47098012-AD99E003-6BB3-49CD-BA7F-155FC6F84055Q47652370-1BEF6F4C-AFB6-4D94-B6ED-31BEEADE380DQ47812088-579E7F27-A266-4031-BF4A-BD7D7B04A8DFQ48320260-7DDB770E-1392-4267-940A-0B4C17E32D85Q49788938-D26D31F9-38FB-4F9E-8104-2A2A88122140Q50000124-B186D0F3-8862-4F6D-848E-EDBEE143C63DQ50780820-2768634E-1F36-4CE3-93B5-B4482DBE5BD3Q50863682-44184E7B-61E9-4B4E-B22D-E79E3F328706Q50989017-99B20AEF-D134-47A9-82A7-56E74B5C4050Q51033595-E662CFBC-FB27-423A-91AD-298EB7E7F082Q51610356-988BEF17-730E-4780-BFE3-E79275B4F504Q51763057-81D1BEE5-D714-433E-83F2-7ED5B7EE0A70Q53164836-79F85DB8-7F4B-49D3-9477-7C6F6528B442Q55403566-FCDD1FD5-3B36-4E51-B8BD-598A076329BAQ57165921-ED733CF8-4D8B-40B0-89EA-D5F451D38110Q58752623-82A197A3-F1A7-4C11-920A-78E077DBBFBC
P2860
Altitude training and haemoglobin mass from the optimised carbon monoxide rebreathing method determined by a meta-analysis
description
2013 nî lūn-bûn
@nan
2013 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
Altitude training and haemoglo ...... determined by a meta-analysis
@ast
Altitude training and haemoglo ...... determined by a meta-analysis
@en
Altitude training and haemoglo ...... determined by a meta-analysis
@nl
type
label
Altitude training and haemoglo ...... determined by a meta-analysis
@ast
Altitude training and haemoglo ...... determined by a meta-analysis
@en
Altitude training and haemoglo ...... determined by a meta-analysis
@nl
prefLabel
Altitude training and haemoglo ...... determined by a meta-analysis
@ast
Altitude training and haemoglo ...... determined by a meta-analysis
@en
Altitude training and haemoglo ...... determined by a meta-analysis
@nl
P2093
P2860
P31
P921
P3181
P1476
Altitude training and haemoglo ...... determined by a meta-analysis
@en
P2093
Birgit Friedmann-Bette
Blake D McLean
Christopher J Gore
Clare E Humberstone
Eileen Y Robertson
Ken Sharpe
Laura A Garvican-Lewis
Mitsuo Neya
Nadine B Wachsmuth
Philo U Saunders
P2860
P3181
P356
10.1136/BJSPORTS-2013-092840
P407
P478
47 Suppl 1
P577
2013-12-01T00:00:00Z