Deng Shukun, Mei Shengrui, Zhou Qunyan, Zhi Wenjun, Wu Wenjun, Cai Junyan, Yuan Peng
Department of Rehabilitation Medicine, The Affiliated Wuxi People's Hospital of Nanjing Medical University, Wuxi People's Hospital, Wuxi Medical Center, Nanjing Medical University, Wuxi, China.
Department of Nutrition, The Affiliated Wuxi People's Hospital of Nanjing Medical University, Wuxi People's Hospital, Wuxi Medical Center, Nanjing Medical University, Wuxi, China.
Front Physiol. 2025 Jan 20;15:1466153. doi: 10.3389/fphys.2024.1466153. eCollection 2024.
To explore the characteristics of cardiopulmonary exercise capacity in adults with different degrees of obesity through cardiopulmonary exercise test (CPET).
From September 2019 to January 2024, the data of patients undergoing CPET in the Rehabilitation Department of the Affiliated Wuxi People's Hospital of Nanjing Medical University were analyzed retrospectively. A total of 231 cases were included. They were categorized into five groups based on their body mass index (BMI): the control group (18.5 ≤ BMI < 24 kg/m, n = 28), the overweight group (24.0 ≤ BMI < 28 kg/m, n = 48), the mild obesity group (28 ≤ BMI < 35 kg/m, n = 75), the moderate obesity group (35.0 ≤ BMI < 40 kg/m, n = 47), and the severe obesity group (BMI ≥ 40 kg/m, n = 33). Collected informations on the age, gender, height, and weight of five groups of participants. The VO at anaerobic threshold (VO), percentage of predicted VO (VO% Pred), peak oxygen consumption (VO), percentage of predicted VO (VO% Pred), peak kilogram oxygen consumption (VO/kg), maximum exercise power (WR), breathing reserve (BR), maximum heart rate (HR), percentage of predicted HR (HR% Pred), maximum O pulse (VO/HR), percentage of predicted maximum O pulse (VO/HR%Pred), maximum relative O pulse (VO/HR/kg),heart rate response (HRr), forced vital capacity (FVC), ratio of forced expiratory volume to vital capacity in 1 s (FEV1/FVC), percentage of predicted forced vital capacity (FVC% Pred), percentage of predicted forced expiratory volume ratio of 1 s (FEV1% Pred), peak expiratory flow rate (PEF), maximum exercise ventilation (VE), maximum voluntary ventilation (MVV) and other indicators during the CPET were collected. Single factor analysis of variance was used to compare the mean of each index between groups. Spearman correlation analysis was used to analyze the correlation between BMI and various indicators.
There was no statistical significance in gender composition, age, height, and exercise habit of the five groups of participants (P > 0.05). The body mass and BMI of the five groups had significant differences (P < 0.001). In terms of cardiopulmonary exercise capacity, there were statistical differences among the five groups in the overall distribution of VO (H = 37.370,P < 0.001), VO/kg (H = 34.747, < 0.001), VO (H = 23.018,P< 0.001), VO/kg (H = 66.606, < 0.001) and WR%Pred (H = 45.136, < 0.001). There was no significant difference among the five groups in the overall distribution of VO%Pred, VO%Pred and WR. There were statistical significant difference among the five groups in HR (F = 2.443, = 0.048), HR%Pred (F = 6.920, < 0.001), VO/HR (F = 8.803, < 0.001), VO/HR%Pred (F = 11.354, < 0.001), VO2/HRmax/kg (F = 18.688, < 0.001) and BR (F = 6.147, < 0.001) and HRr (F = 9.467, < 0.001). There were no significant differences among the five groups in RER (F = 0.336, > 0.05). In terms of static pulmonary function, there were significant differences among the five groups in FVC%Pred (F = 4.577, = 0.001), FEV1%Pred (F = 3.681, = 0.006) and FEV1/FVC (F = 3.344, = 0.011). There was no differences among the five groups in MVV(P> 0.05), and there were significant differences among the five groups in VE ( = 0.005) In terms of correlation analysis, BMI was positively correlated with VO,VO VE and VO/HR, and negatively correlated with VO/kg, VO/kg,WR%Pred, HR%Pred, VO/HR%Pred, VO/HR/kg,BR and HRr. In terms of static pulmonary function, BMI was negatively correlated with FVC%Pred, FEV1%Pred.
With the aggravation of obesity, the maximum exercise ability of adults decreases, VO/kg and VO/HR%Pred decreases, and the breathing reserve decreases.
通过心肺运动试验(CPET)探讨不同肥胖程度成人的心肺运动能力特征。
回顾性分析2019年9月至2024年1月在南京医科大学附属无锡人民医院康复科接受CPET检查的患者资料。共纳入231例患者。根据体重指数(BMI)将其分为五组:对照组(18.5≤BMI<24kg/m²,n = 28)、超重组(24.0≤BMI<28kg/m²,n = 48)、轻度肥胖组(28≤BMI<35kg/m²,n = 75)、中度肥胖组(35.0≤BMI<40kg/m²,n = 47)和重度肥胖组(BMI≥40kg/m²,n = 33)。收集五组参与者的年龄、性别、身高和体重信息。收集CPET期间无氧阈时的VO₂(VO₂@AT)、预测VO₂百分比(VO₂%Pred)、峰值摄氧量(VO₂peak)、预测VO₂百分比(VO₂%Pred)、峰值千克摄氧量(VO₂/kg)、最大运动功率(WR)、呼吸储备(BR)、最大心率(HR)、预测HR百分比(HR%Pred)、最大氧脉搏(VO₂/HR)、预测最大氧脉搏百分比(VO₂/HR%Pred)、最大相对氧脉搏(VO₂/HR/kg)、心率反应(HRr)、用力肺活量(FVC)、一秒用力呼气容积与肺活量比值(FEV₁/FVC)、预测用力肺活量百分比(FVC%Pred)、预测一秒用力呼气容积比值百分比(FEV₁%Pred)、呼气峰值流速(PEF)、最大运动通气量(VE)、最大自主通气量(MVV)等指标。采用单因素方差分析比较各组间各指标的均值。采用Spearman相关分析分析BMI与各项指标的相关性。
五组参与者的性别构成、年龄、身高和运动习惯差异无统计学意义(P>0.05)。五组的体重和BMI差异有统计学意义(P<0.001)。在心肺运动能力方面,五组在VO₂(H = 37.370,P<0.001)、VO₂/kg(H = 34.747,P<0.001)、VO₂peak(H = 23.018,P<0.001)、VO₂/kg(H = 66.606,P<0.001)和WR%Pred(H = 45.136,P<0.001)整体分布上有统计学差异。五组在VO₂%Pred、VO₂%Pred和WR整体分布上无显著差异。五组在HR(F = 2.443,P = 0.048)、HR%Pred(F = 6.920,P<0.001)、VO₂/HR(F = 8.803,P<0.001)、VO₂/HR%Pred(F = 11.354,P<0.001)、VO₂/HRmax/kg(F = 18.688,P<0.001)和BR(F = 6.147,P<0.001)以及HRr(F = 9.467,P<0.001)上有统计学差异。五组在呼吸交换率(RER)上无显著差异(F = 0.336,P>0.05)。在静态肺功能方面,五组在FVC%Pred(F = 4.577,P = 0.001)、FEV₁%Pred(F = 3.681,P = 0.006)和FEV₁/FVC(F = 3.344,P = 0.011)上有显著差异。五组在MVV上无差异(P>0.05),在VE上五组有显著差异(P = 0.005)。在相关性分析方面,BMI与VO₂、VO₂peak、VE和VO₂/HR呈正相关,与VO₂/kg、VO₂/kg、WR%Pred、HR%Pred、VO₂/HR%Pred、VO₂/HR/kg、BR和HRr呈负相关。在静态肺功能方面,BMI与FVC%Pred、FEV₁%Pred呈负相关。
随着肥胖程度加重,成人最大运动能力下降,VO₂/kg和VO₂/HR%Pred降低,呼吸储备减少。
