• 생명과학회지
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• 제17권9호통권89호
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• pp.1255-1259
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• 2007

The purpose of this study was to elucidate incidence of $VO_2$ plateau by comparing data derived from different time averaging intervals during incremental cycling exercise to $VO_2max$. Seventeen subjects (age: $23.5{\pm}3.3$ years and $VO_2max$: $3.65{\pm}0.73$ L/min, respectively) completed $VO_2max$ tests on cycle ergometer which breath by breath gas ex-change data were obtained. These data were time-averaged into 11-breath, 15, 30 and 60 s sampling intervals. The incidence of plateau were 100, 35, 24 and 6% for the 11 breath, 15 s, 30 s and 60 s averaging, respectively. No correlation was between ${\Delta}$ $VO-2$ at $VO_2max$ and $VO_2max$ (r=0.008). 53% (maximal HR within 10 b/min) and 100% $(RER{\geq}1.15)$ of subjects met the criteria for attainment of $VO_2max$. This data indicate that shorter sampling intervals (11 breath) is the most suitable for de-tection of the $VO_2$ plateau and RER can be used for the criteria for attainment of $VO_2max$ but not maximal HR. Also, the incidence of a plateau is not related to training status or physical fitness of subjects.

• 한국생명과학회:학술대회논문집
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• 한국생명과학회 2007년도 제48회 학술심포지움 및 추계국제학술대회
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• pp.25.2-25.2
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• 2007

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• 한국생명과학회:학술대회논문집
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• 한국생명과학회 2007년도 제48회 학술심포지움 및 추계국제학술대회
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• pp.82.2-82.2
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• 2007

See Full Text

• 생명과학회지
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• 제19권12호
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• pp.1712-1717
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• 2009

이 연구의 목적은 자전거 에르고미터 점증 부하 운동 검사를 통하여 4가지 다른 운동 검사시간 프로토콜(protocol)이 최대 산소 섭취량($VO_2$max)과 산소 섭취량 정체($VO_2$plateau)에 어떠한 영향을 미치는지를 비교 분석하는 것이다. 연구를 위하여 설정된 운동 시간 프로토콜은 5, 8, 12 그리고 16분이다. 평균 이상의 자전거 운동 능력을 지닌 20명의 자발적 피 실험자들이 연구에 참여하였다. 8분 프로토콜의 평균 최대 산소 섭취량($3.66{\pm}0.88\;l/min$)은 통계적으로(p<0.05) 12분($3.49{\pm}0.76\;l/min$)과 16분 프로토콜의($3.45{\pm}0.73\;l/min$) 최대 산소 섭취량보다 높게 제시되었다. 5분 프로토콜의 평균 최대 산소 섭취량은 두 번째로 높은 수치를 나타냈으나, 통계적으로 12분과 16분 프로토콜의 최대 산소 섭취량과는 다르지 않았다(p>0.05). 평균 최대 운동 강도(average maximal power output)는 운동 검사시간들이 영향을 미치는 것으로 나타났다. 5분 프로토콜의 평균 최대 운동 강도가 8분 프로토콜 보다 12%, 12분 프로토콜 보다 24%, 그리고 16분 프로토콜 보다 35% 높게 나타났다. 산소 섭취량 정체($VO_2$plateau)는 5분 프로토콜에서 12.5%, 8분 프로토콜에서 56.25%, 12분 프로토콜에서 37.5%, 그리고 16분 프로토콜에서 56.25%의 빈도를 보였다. 이 연구는 평균 이상의 운동 능력을 지닌 피 실험자에게는 6분에서 10분 사이의 검사시간이 적합하다고 제안하고 있다.

• Tuberculosis and Respiratory Diseases
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• 제47권1호
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• pp.26-34
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• 1999

연구배경: 최대 산소 섭취량 ($VO_2$ max) 은 답차 운동시 자전거시 보다 높게 측정이 되는데, Hassen과 Wasserman 등에 의하면 답차 시 약 1.11배 정도 높게 측정된다고 하였다. $VO_2$ max는 나이, 성별, 키, 체중 등 뿐만 아니라 인종, 사회문화적 배경 및 운동 습관에 따라서도 영향을 받을 수 있음이 알려져 있다. 본 연구에서는 한국 대학생 연령의 성인을 대상으로 답차와 자전거 운동시 $VO_2$ max와 무산소 역치에서의 산소 섭취량 (AT)을 측정, 비교하였다. 방법: 1998 년 6월부터 9월까지 연세대학교 의과대학에 재학중인 남학생 44명을 대상 으로 하였다. 이들을 무작위로 2군으로 나누어 24명은 답차를 우선 시행 후 1주일 후 자전거로 운동을 시행하였고 20명은 자전거를 우선 시행 후 답차를 시행하였다. 증상 제한적 최대 운동 시행토록 하였으며, 최소한 호흡 교환비(RER) 가 1.1을 초과한 경우, 최대 산소 섭취량이 30초 이상 평점을 이룬 경우, 최대 운동시 심박 예비율이 15% 미만이거나 또는 호흡 예비율이 30% 미만일 경우를 최대 운동으로 정의하였고 이들 중 한가지라도 충족시키지 못한 경우에는 최대운동을 하지 않은 것으로 (submaximal exercise) 간주하여 연구에서 제외하였다. AT는 V-slope method로 구하였다. 결과: 답차 운동시의 $VO_2$ max와 AT 의 값은 각각 $45.1{\pm}6.66 m\ell$/kg/min, $26.0{\pm}6.78 m\ell$/kg/min 이었으며, 자전거 운동시에는 각각 $34.9{\pm}5.89 m\ell$/kg/min, $19.5{\pm}4.77 m\ell$/kg/min 이었다. 측정-$VO_2$ max/예측 $VO_2$ max 의 값은 답차 운동시 $98.8{\pm}13.24 %$ 이었으며, 자전거 운동시 $84.4{\pm}13.42 %$ 이었다. 자전거의 결과로 답차 운동시 $VO_2$ max 의 예측치를 구할 때 쓰이는 Hassen등의 공식을 이용하여 이를 실제 답차 운동시 얻어진 $VO_2$ max값과 비교해 보았을 때 두 값 사이의 차이는 통계적으로 유의하였다 (p<0.01). 최대 운동시 심박 예비율, 산소/맥, 호흡 예비율, $V_E$/MVV, $V_E/VCO_2$는 (답차 운동과 자전거 운동사이에 차이가 있었다 ). 그러나 $V_E/VO_2$, Vd/Vt, Ti/Ttot는 차이가 없었다. AT에서는 산소/맥, 호흡 예비율, $V_E$/MVV, Ti/Ttot값은 차이가 있었으나 나머지 값들은 그렇지 못하였다. 결론: 본 연구에서 보았듯이 답차와 자전거 사이의 차이가 크므로 결과의 해석에 이용시 유의해야 할 것이며, 향후 한국인에서 적용할 수 있는 참고치를 구하려는 노력이 필요할 것으로 여겨진다.

• Animal Bioscience
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• 제36권1호
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• pp.75-83
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• 2023

Objective: The objective of this study was to describe a methodological procedure to quantify the heat production (HP) partitioning in basal metabolism or fasting heat production (FHP), heat production due to physical activity (HPA), and the thermic effect of feeding (TEF) in roosters. Methods: Eighteen 54-wk-old Hy Line Brown roosters (2.916±0.15 kg) were allocated in an open-circuit chamber of respirometry for O₂ consumption (VO₂), CO₂ production (VCO₂), and physical activity (PA) measurements, under environmental comfort conditions, following the protocol: adaptation (3 d), ad libitum feeding (1 d), and fasting conditions (1 d). The Brouwer equation was used to calculate the HP from VO₂ and VCO₂. The plateau-FHP (parameter L) was estimated through the broken line model: HP = U×(R-t)×I+L; I = 1 if t<R or I = 0 if t>R; Where the broken-point (R) was assigned as the time (t) that defined the difference between a short and long fasting period, I is conditional, and U is the decreasing rate after the feed was withdrawn. The HP components description was characterized by three events: ad libitum feeding and short and long fasting periods. Linear regression was adjusted between physical activity (PA) and HP to determine the HPA and to estimate the standardized FHP (st-FHP) as the intercept of PA = 0. Results: The time when plateau-FHP was reached at 11.7 h after withdrawal feed, with a mean value of 386 kJ/kg^0.75/d, differing in 32 kJ from st-FHP (354 kJ/kg^0.75/d). The slope of HP per unit of PA was 4.52 kJ/mV. The total HP in roosters partitioned into the st-FHP, termal effect of feeding (TEF), and HPA was 56.6%, 25.7%, and 17.7%, respectively. Conclusion: The FHP represents the largest fraction of energy expenditure in roosters, followed by the TEF. Furthermore, the PA increased the variation of HP measurements.

• 한국전문물리치료학회지
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• 제7권2호
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• pp.20-34
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• 2000

The purpose of this study was to establish modified physiological cost index (PCI) for predicting energy consumption by heart rate (HR) at isokinetic ergometer exercise testing. The subjects were twenty-eight healthy men in their twenties. All of them performed upper and lower extremity isokinetic ergometer exercise tests which had six loads (400, 500, 600, 700, 800, and 900 kg-m/min) and five loads (400, 500, 600, 700, and 800 kg-m/min) respectively. The exercise sessions were finished when HR was in plateau. HR and oxygen consumption were determined during the final minute. Resting heart rate and oxygen consumption were used for calculating heart rate, oxygen consumption changes and modified PCI. Regression analysis established the relationship between each variable to work load, HR and oxygen consumption. The results were as follows: 1) In the lower extremity ergometer exercise test, oxygen consumption increased continuously as work load increased, but in the upper extremity ergometer test, oxygen consumption only increased until work load was 700 kg-m/min. 2) HR increased as work load increased in both exercise tests, but in the upper extremity ergometer test, HR decreased from the 700 kg-m/min. 3) The modified PCI increased as work load mcreased until the 700 kg-m/min point in the lower extremity ergometer test and until the 500 kg-m/min point in the upper extremity ergometer test when it started to decrease in both tests. 4) In the lower extremity ergometer exercise test, regression analysis established the relation as $dVO_2$ = -.0215HR - .2141 where $dVO_2$ is given in l/min and HR in beat/min ($R^2$ = .2677, p = .000). ln the upper extremity ergometer exercise test. regression analysis established the relation as $dVO_2$ = -.0115HR + .2746 ($R^2$ = .1308, p = .000). The results of this study were similar to previous studies but were different under high work load conditions. So modified PCI should be used with only low intensity work load testing. Subjects for upper extremity ergometer exercise testing should complete a prescribed training course prior to testing, and only low intensity work load should be used for safety considerations.

• Animal Bioscience
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• 제35권5호
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• pp.690-697
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• 2022

Objective: This study aimed to evaluate the effect of the ad libitum and restricted feeding regimen on fasting heat production (FHP) and body composition. Methods: Twelve Hubbard broilers breeders were selected with the same body weight and submitted in two feeding regimes: Restricted (T1) with feed intake of 150 g/bird/d and ad libitum (T2). The birds were randomly distributed on the treatments in two runs with three replications per treatment (per run). The birds were adapted to the feed regimens for ten days. After that, they were allocated in the open-circuit chambers and kept for three days for adaptation. On the last day, oxygen consumption (VO₂) and carbon dioxide production (VCO₂) were measured by 30 h under fasting. The respiratory quotient (RQ) was calculated as the VCO₂/VO₂ ratio, and the heat production (HP) was obtained using the Brower equation (1985). The FHP was estimated throughout the plateau of HP 12 hours after the feed deprivation. The body composition was analyzed by dual-energy X-ray absorptiometry scanning at the end of each period. Data were analyzed for one-way analysis of variance using the Minitab software. Results: The daily feed intake was 30 g higher to T2 (p<0.01) than the T1. Also, the birds of the T2 had significatively (p<0.05) more oxygen consumption (+3.1 L/kg^0.75/d) and CO₂ production (+2.2 L/kg^0.75/d). That resulted in a higher FHP 359±14 kJ/kg^0.75/d for T2 than T1 296±17.23 kJ/kg^0.75/d. In contrast, the RQ was not different between treatments, with an average of 0.77 for the fasting condition. In addition, protein and fat composition were not affected by the treatment, while a tendency (p<0.1) was shown to higher bone mineral content on the T1. Conclusion: The birds under ad libitum feeding had a higher maintenance energy requirement but their body composition was not affected compared to restricted feeding.