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研究生: 陳妍慧
Chen, Yen-Huey
論文名稱: 比較正常與過重大學生運動中腦氧合及血液動態學差異
Comparisons of hemodynamic and cerebral oxygenation during exercise between normal weight and overweight college students
指導教授: 方進隆
Fang, Chin-Lung
學位類別: 博士
Doctor
系所名稱: 體育學系
Department of Physical Education
論文出版年: 2017
畢業學年度: 105
語文別: 中文
論文頁數: 75
中文關鍵詞: 肥胖有氧運動腦氧合心輸出量
英文關鍵詞: obesity, aerobic exercise, cerebral oxygenation, cardiac output
DOI URL: https://doi.org/10.6345/NTNU202203311
論文種類: 學術論文
相關次數: 點閱:174下載:20
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  • 背景: 肥胖對於心血管功能有負面影響,可能會造成運動中心血管及腦氧不同的反應,過去少有研究比較肥胖和正常學生在運動中血液動態學與腦氧合的表現。本研究目的:(一)比較過重大學生與正常組於最大運動測試中腦氧合與血液動態學的差異。(二)比較正常體重與過重大學生於單次30分鐘高強度有氧運動中腦氧合與血液動態學的變化的差異。研究方法: 招募過重組大學男生14名(平均BMI29.0±5.4 kg/m2) 與正常組18名(平均BMI22.4±1.4 kg/m2 ) 進行腳踏車最大運動測試,測量最大攝氧量("Ṽ" O2max)和最大作功率。相隔一週後再從事30分鐘 (70% max workload, Wmax,最大作功負荷)之有氧運動。以生物電阻阻抗儀(Physioflow)測量兩次運動中血液動態學之心輸出量( CO)、心搏量(SV)、射血比(EF),以近紅外線光譜儀來測量腦部氧合(含氧血紅素, O2Hb)、去氧血紅素(HHb)和總血紅素( tHb)。統計分析: 所得資料以二因子變異數分析兩組血液動態學和腦氧合狀態差異。結果: 最大運動測試中,正常組之"Ṽ" O2max顯著大於過重組(41.3±5.7與30.0±5.0) ml/min/kg,p<0.05)。正常組CO從安靜時5.7±1.2L顯著增加至100%Wmax時19.2±4.1L (p<0.05);過重組的CO從安靜時6.9±1.3L 增加至100%Wmax時 20.4±4.4L (p<0.05)。兩組組間CO表現無顯著差異,但正常組在70%Wmax時CO增加幅度(179.8%)顯著大於過重組(137.0%) (p<0.05)。運動測試中,正常組腦tHb從安靜至50%Wmax共增加(7.0um),顯著大於過重組(1.7um)( p<0.05)。單次有氧運動中,兩組血液動態學無顯著差異,但運動中第10、20、30分鐘,正常組CO分別增加幅度為178.8%、199.3%、219.4%,顯著大於過重組105.8%、121.0%、130.0% (p<0.05)。運動停止後20分鐘,正常組腦部O2Hb增加13.9um,顯著大於過重組(1.0um) (p<0.05)。結論: 過重大學生於激烈運動時心輸出量和恢復其腦部供氧量增加幅度較正常體重組少。過重大學生從事激烈運動時應注意這些生理反應。

    BACKGROUND: Obesity has a negative impact on cardiovascular function that may increase the risk during exercise. Few studies have investigated the hemodynamics and cerebral oxygenation in this area. The purposes of this study are (a) to compare the hemodynamic and cerebral oxygen changes during maximal exercise test between overweight(OS) and normal weight students(NS). (b) to compare the hemodynamic and cerebral oxygenation changes during vigorous exercise between OS and NS. METHODS: Eighteen male NS college students (mean BMI29.0±5.4 kg/m2 ) and 14 OS (mean BMI22.4±1.4 kg/m2) were recruited and asked to perform maximal exercise test on ergometer to measure maximum oxygen uptake ("Ṽ" O2max) and maximum power. One week later, subjects had performed a high intensity (70% max workload, Wmax) cycling exercise for 30 min. The hemodynamics CO, SV, EF of all subjects during exercises were measured with a bioelectrical impedance device (Physioflow), and cerebral oxygenation status (oxygenated hemoglobin (O2Hb), deoxygenated hemoglobin (HHb), total hemoglobin (tHb) was measured by a near infrared spectrophotometer (NIRS). STATISTICS: The collected data were analyzed with 2-way ANOVA. RESULTS: The "Ṽ" O2max of NS was significantly higher than that of OS (41.3±5.7 vs 30.0 ±5.0 ml / min / kg, p<0.05). The CO of NS was significantly increased from resting status ( 5.7 ±1.2L) to 100% Wmax (19.2 ±4.1 L) (p<0.05) in the NS, and 6.9±1.3 L to 20.4±4.4 L (p<0.05) of OS. There were no significant differences of CO between the two groups, but CO increase179.8% in 70% Wmax in NS was significantly greater than that of the OS (137.0%) (p <0.05). The cerebral tHb of NS increased (7.0um) at 50% Wmax significantly greater than that (1.7um) of OS (p <0.05). During 30 min vigorous exercise, there was no significant difference in hemodynamics between the two groups (p> .05). During 10,20,30 minutes, the CO increases of NS (178.8%, 199.3%, 219.4%) were significantly higher than that of the OS (105.8% ,121% and 130%, respectively) (p <0.05). There was no significant difference of cerebral oxygenation between the two groups during endurance exercise. But the O2Hb of NS at 20 minutes of endurance exercise, increased 13.9um was significantly higher than that of the OS (1.0um ) (p <0.05). CONCLUSION: The overweight college students showed less cardiac output and cerebral oxygenation than that of NS during vigorous exercise and recovery. These physiological response may take into consideration while engage in vigorous exercise.

    目次 口試委員與系主任簽字之論文通過簽名表 ……………………i 論文授權書 …………………………………………………………… ii 中文摘要……………………………………………………………… iii 英文摘要……………………………………………………………… v 謝誌 ……………………………………………………………… vii 目次 ……………………………………………………………… viii 表次 ……………………………………………………………… xi 圖次 ……………………………………………………………… xiii 第壹章緒論 ………………………………………………………… 1 第一節 研究背景 ………………………………………………… 1 第二節 研究目的 ………………………………………………… 4 第三節 研究假設 ………………………………………………… 4 第四節 名詞操作性定義 ………………………………………… 5 第五節 研究限制 ……………………………………………… 7 第六節 研究的重要性 ………………………………………… 7 第貳章文獻回顧……………………………………………. 8 第一節 肥胖對健康的影響 ………………………..... …...8 第二節 肥胖對於心血管系統之影響 ………………………… 9 第三節 運動中血液動態學之變化 …………………………… 12 第四節 運動對腦氧合之影響 ……………………………….. 14 第五節 本章總結 …………………………………………….. 17 第叁章 研究方法 ………………………………………… 18 第一節 實驗參與者 ……………………………………………….….18 第二節 實驗設計與流程 …………………………………………..19 第三節 研究工具 …………………………………………………..… 23 第四節 測量方法 ………………………………………………….…..26 第五節 統計分析 …………………………………………….………...28 第肆章 研究結果 …………………………………………….. 29 第一節 研究對象基本資料 ……………………………………………29 第二節 過重組與正常組最大運動測試表現之差異…………30 第三節 過重組與正常組最大運動測試血液動態學之差異…… 31 第四節 過重組與正常組最大運動測試腦氧合之差異…………….35 第五節 過重組與正常組單次高強度有氧運動血液動態學之差異42 第六節 過重組與正常組單次高強度有氧運動腦氧合之差異…47 第伍章 討論與結論…………………………………………… 52 第一節 比較過重組與正常組心肺最大運動測試表現之差異 ……52 第二節 比較過重組與正常組最大運動測試血液動態學之差異…53 第三節 比較過重組與正常組最大運動測試腦氧合之差異…..…..54 第四節 比較過重組與正常組單次高強度有氧運動血液動態學之差異55 第五節 比較過重組與正常組單次高強度有氧運動運動腦氧合之差異56 第六節 結論與建議 …………………………………………………… 58 參考文獻 ………………………………………………………………… 60 附錄一 各組最大運動測試血液動態學趨勢圖…………………………… 67 附錄二 各組最大運動測試腦氧合趨勢圖………………………………… 68 附錄三 各組單次高強度有氧運動血液動態學趨勢圖………………… 69 附錄四 各組單次高強度有氧運動腦氧合趨勢圖 …………………….. 70 附錄五 活動量簡易自我評量表 ………………………………………….. 71 附錄六 IPAQ身體活動量問卷 …………………………………………. 72 表次 表1 受試者基本及身體組成資料 ………… 29 表2 各組最大運動測試資料 ………… 30 表3-1 各組最大運動測試心輸出量之比較 ………… 31 表3-2 各組最大運動測試心輸出量變異數摘要表 ………… 31 表3-3 各組最大運動測試心搏量比較 ………… 32 表3-4 各組最大運動測試心搏量變異數摘要 ………… 32 表3-5 各組最大運動測試射血比比較 ………… 33 表3-6 各組最大運動測試射血比變異數摘要表 ………… 33 表3-7 各組最大運動測試血液動態學變化幅度(%)………… 34 表4-1 各組最大運動測試腦氧合O2Hb比較 ………… 35 表4-2 各組最大運動測試腦氧合O2Hb變異數摘要表………… 35 表4-3 各組最大運動測試腦氧合HHb比較 ………… 36 表4-4 各組最大運動測試腦氧合HHb變異數摘要表 ………… 36 表4-5 各組最大運動測試腦氧合tHb比較 ………… 37 表4-6 各組最大運動測試腦氧合tHb變異數摘要表 ………… 37 表4-7 各組最大運動測試腦氧合變化值 ……….....… 38 表4-8 安靜血液動態學與體位指標之相關分析 ………… 39 表4-9 最大運動測試血液動態學與體位指標之相關分析...…40 表4-10最大運動測試腦氧合與血液動態學、攝氧量之相關分析41 表5-1 各組單次高強度有氧運動心輸出量比較 ………… 42 表5-2 各組單次有氧運動心輸出量變異數摘要表 ………… 42 表4-3 各組單次高強度有氧運動心搏量比較 ………… 43 表5-4 各組單次高強度有氧運動心博量變異數摘要表………… 43 表5-5 各組單次高強度有氧運動射血比比較 ………… 44 表5-6 各組單次高強度有氧運動射血比變異數摘要表………… 44 表5-7 各組單次高強度有氧運動血液動態學變化幅度(%)…… 46 表6-1 各組單次高強度有氧運動腦氧合O2Hb比較 ………… 47 表6-2 各組單次高強度有氧運動腦氧合O2Hb變異數摘要表……47 表6-3 各組單次高強度有氧運動腦氧合HHb比較 ………… 48 表6-4 各組單次高強度有氧運動腦氧合HHb變異數摘要表………48 表6-5 各組單次高強度有氧運動腦氧合tHb比較 ………… 49 表6-6 各組單次高強度有氧運動腦氧合tHb變異數摘要表…… 49 表6-7 各組單次高強度有氧運動腦氧合變化值 ………… 50 圖次 圖一 研究架構圖 …………………… 20 圖二 實驗流程圖—最大運動測試 …………………… 21 圖三 實驗流程圖—單次有氧運動 …………………… 22 圖四 Inbody 720 …………………… 23 圖五 Physioflow及貼片位置示意圖 …………………… 24 圖六 NIRS及配戴位置示意圖 …………………… 25

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