力竭追赶训练对两种鲤科鱼类呼吸循环系统参数和力竭运动后代谢特征的影响

为了考察力竭追赶训练对中华倒刺鲃(Spinibarbus sinensis)和岩原鲤(Procypris rabaudi)幼鱼呼吸循环系统和力竭运动后代谢特征的影响, 在(25±0.5)℃条件下, 将2种实验鱼各60尾 [体重分别为(28.36±0.08) g和(19.53±0.13) g]随机等分成对照组和训练组, 训练组进行1次/d共21d的力竭追赶训练。随后测定各组实验鱼的心脏和鳃指数、血液指标以及力竭运动后过量耗氧(Excess post-exercise oxygen consumption, EPOC)。结果发现: 2种鱼心脏指数、鳃指数、血红蛋白含量和红细胞数目在各自对照组和训练组之间都没有显著性差异; 岩原鲤对照组的鳃指数显著低于中华倒刺鲃对照组(P<0.05), 但心脏指数、血红蛋白含量和红细胞数目与中华倒刺鲃对照组无显著性差异。中华倒刺鲃训练组的运动前代谢率、运动代谢峰值、峰值比率、代谢恢复速率与其对照组没有显著差异, 但运动后恢复时间和过量耗氧显著大于对照组(P<0.05); 岩原鲤训练组的运动前代谢率显著低于其对照组(P<0.05), 但运动代谢峰值、峰值比率、运动后恢复时间、过量耗氧、代谢恢复速率与其对照组没有显著性差异。岩原鲤对照组的运动前代谢率、运动代谢峰值、过量耗氧和代谢恢复速率分别显著低于中华倒刺鲃对照组(P<0.05), 但峰值比率和运动后恢复时间与中华倒刺鲃对照组无显著性差异。研究表明: (1)力竭追赶训练对中华倒刺鲃和岩原鲤幼鱼的呼吸和循环系统参数没有产生显著性影响; (2)力竭追赶训练显著提高了中华倒刺鲃幼鱼的无氧代谢能力; (3)中华倒刺鲃幼鱼力竭运动前后代谢率显著高于岩原鲤幼鱼, 这可能与其较为活跃的习性有关。     

中华倒刺鲃幼鱼能量代谢特征个体差异及生态关联

为了探讨鱼类能量代谢特征个体变异及其生态关联, 以中华倒刺鲃(Spinibarbus sinensis)幼鱼为实验对象, 在25℃条件下测定44尾实验鱼的静止代谢率(Resting metabolic rate, RMR)、力竭运动后峰值代谢率(Peak metabolic rate, PMR)、力竭运动后过量耗氧(Excess post-exercise oxygen consumption, EPOC)、低氧胁迫后峰值代谢率PMR和低氧胁迫后过量耗氧(Excess post-hypoxia oxygen consumption, EPHOC)。研究发现, 中华倒刺鲃能量代谢特征参数存在较大个体差异, RMR、力竭运动后PMR、EPOC、低氧胁迫后PMR和EPHOC分别为193.62—460.33 [mg O₂/(kg·h)]、617.9—2165.02 [mg O₂/(kg·h)]、28.76—267.20 mg O₂/kg、484.3—1142.97 [mg O₂/(kg·h)]和30.27—211.88 mg O₂/kg。力竭运动后PMR(r=0.348, P=0.010)和低氧胁迫后PMR(r=0.449, P=0.002)与RMR间均呈显著正相关; EPOC与RMR间呈显著负相关(r=–0.426, P=0.004), 而EPHOC与RMR间的关系不显著(r=–0.292, P=0.054); 力竭运动后PMR与EPOC间(r=0.424, P=0.004)和低氧胁迫后PMR与EPHOC间(r=0.391, P=0.009)均呈显著正相关。力竭运动后PMR与低氧胁迫后PMR(r=0.673, P<0.001)和EPOC与EPHOC(r=0.526, P<0.001)在个体差异均显著正相关; 然而力竭运动后PMR和EPOC分别显著高于低氧胁迫后PMR与EPHOC(P<0.05)。研究表明: 维持代谢较高的中华倒刺鲃个体有助于其快速提升有氧功率输出以维持高的游泳运动能力; 而较低维持代谢个体具有相对较高的EPHOC有助于机体在极端环境条件下提升其低氧耐受能力。中华倒刺鲃能量特征的个体变异可能是经长期自然选择适应环境的结果。     

有氧运动训练对中华倒刺鲃幼鱼肠道排空及其数学模型选择的影响

为了考察有氧运动训练对中华倒刺鲃幼鱼肠道排空及其数学模型选择产生的影响, 在(250.5)℃条件下, 将108 尾大小相当的实验鱼(24.470.03) g, (10.900.02) cm随机分为对照组(CG), 1 BL/s 训练组(1TG)和2 BL/s 训练组(2TG), 在相应流速下运动训练8w 后, 轻度麻醉灌喂体重1.45%的饵料, 随后在不同时间点分别测定肠道内容物重量及其百分比, 用3 个常见数学模型对实验数据进行拟合并比较。结果发现, 1TG 和2TG 训练组的体重特定生长率(WSGR)显著高于CG 对照组 (P0.05);各实验组肠道内容物干重及其百分比随着摄食后时间的延长而显著降低;所有实验组肠道排空的最优数学模型均为平方根模型;训练组(1TG 和2TG)的肠道排空率(皆为0.49%/h)明显大于CG 对照组(0.41%/h)(P0.05), 1TG 和2TG 训练组的肠道排空时间(分别为 20.39h 和 20.33h)短于 CG 对照组(24.51h)。研究表明, 有氧运动训练没有对中华倒刺鲃幼鱼的肠道排空特征及其最优数学模型选择产生显著影响, 但明显提高了该种鱼的肠道排空率并缩短其肠道排空时间。       

中华倒刺鲃能量代谢和热耐受特征的体重效应

为了探讨体重对中华倒刺鲃能量代谢和热耐受特征的影响,在25℃条件下分别测定不同体重大小(1、10、25、50 g组)中华倒刺鲃的静止代谢率(Resting metabolic rate,RMR)、力竭运动后过量耗氧(Excess post-exercise oxygen consumption,EPOC)和热耐受参数。随体重的增加,中华倒刺鲃个体RMR、最大代谢率(Maximum metabolic rate,MMR)、代谢空间(Metabolic scope,MS)和EPOC均显著增加(P0.05);单位体重RMR、MMR和MS则均显著降低,而单位体重EPOC随体重的增加显著增加(P0.05)。RMR、MMR、MS和EPOC的代谢尺度指数分别为0.796、0.834、0.849和1.137且显著大于2/3,因此中华倒刺鲃的能量代谢参数均呈异速度增加的关系而变化。这些变化可能与其个体变大游泳运动能力增强导致能量代谢需求增加相关。中华倒刺鲃临界低温(Critical thermal minimum,CT_(min))和致死低温(Lethal thermal minimum,IL_(min))与体重之间均呈"微笑型"二次函数的关系,临界高温(Critical thermal maximum,CT_(max))和致死高温(Lethal thermal maximum,IL_(max))均呈"钟型"二次函数的关系,因此中等大小的中华倒刺鲃具有更强的热耐受能力。这种非线性关系可能与其生长发育阶段和温度驯化历时有关。     

摄食对鲇鱼幼鱼力竭性运动后过量耗氧的影响

为了检验鲇鱼(Silurus asotus Linnaeus)幼鱼力竭性运动(Exhaustive exercise)后过量耗氧(EPOC)是否受到摄食的影响,以阐明其在两种功能状态下的功率配置模式,在(25.0±1.0)℃条件下,分别测定了对照组(摄食前)、摄食组[摄食12 h,摄食水平为(8.74±0.40)%]、摄食代谢恢复组[摄食60 h,摄食水平为(8.84±0.25)%]鲇幼鱼力竭性运动后EPOC及力竭性运动后恢复过程中呼吸频率(Vf)的变化。研究结果显示:对照组、摄食组、摄食代谢恢复组力竭性运动前耗氧率(MO2)显著差异(P<0.05),而Vf差异不显著;力竭性运动后MO2和Vf均立即达到峰值,随后逐渐恢复到稳定状态;摄食组的耗氧率峰值(MO2peak)[(222.47±10.14)mgO2/(kg.h)]显著大于对照组[(180.53±6.79)mgO2/(kg.h)]和摄食代谢恢复组[(181.65±10.94)mgO2/(kg.h)](P<0.05),但三个组之间Vf无显著变化;摄食组的EPOC总量[(42.49±10.13)mgO2]显著小于对照组[(66.58±6.40)mgO2]和摄食代谢恢复组[(53.46±5.80)mgO2](P<0.05)。以上结果表明:(1)无论是摄食还是运动任一生理功能均不能诱导出鲇鱼幼鱼的最大的MO2;(2)当摄食和运动两种生理功能同时存在时,鲇鱼无氧运动能力减弱,同时力竭性运动后的恢复过程加快,可能与消化导致的内环境碱化减缓了运动后的内环境酸化有关。     

力竭性运动锻炼和饥饿对南方鲇运动后过量耗氧的影响

为了检验力竭性运动锻炼和饥饿是否对南方鲇Silurus meridonalis Chen维持能量消耗和无氧代谢能力产生影响,在25℃条件下测定了维持日粮(1.5%body mass per day)和饥饿条件下南方鲇15d力竭性锻炼(5min chasing)和随后5d恢复过程静止代谢率(VO2rest)和运动后过量耗氧(Excess post-exercise VO2,EPOC)的变化.另外两组非锻炼组分别作为摄食和饥饿对照组.实验过程中摄食和饥饿对照组VO2rest显著下降(P＜0.05),而摄食和饥饿对照组经过15d的锻炼显著上升(P＜0.05).经过5d的恢复2锻炼组VO2rest显著下降与对照组无显著差异.摄食和饥饿对照组力竭运动后代谢率峰值(VO2peak)在实验过程中显著下降(P＜0.05),而摄食和饥饿锻炼组经过15d没有显著变化.锻炼取消后2锻炼组VO2peak显著下降至对照组水平.各锻炼组和对照组间过量耗氧均无显著差异.实验提示:(1)锻炼导致VO2rest和VO2peak显著提高,但影响可塑性大,5d恢复期后影响消失;(2)锻炼导致力竭运动后代谢恢复速率加快,5d恢复期后锻炼影响依然存在;(3)对饥饿和摄食组,锻炼的生理影响相似,但饥饿组VO2rest对锻炼更为敏感.     

PFOS对中华倒刺鲃幼鱼爆发游泳及运动后代谢恢复的影响

为探究水体全氟辛烷磺酸(PFOS)污染对鱼类爆发游泳及其代谢恢复能力的影响, 将中华倒刺鲃幼鱼(Spinibarbus sinensis)暴露在不同浓度(0、0.32、0.8、2和5 mg/L)PFOS后, 测定PFOS暴露对其静止代谢率(RMR)、爆发游泳速度(U_burst)以及运动力竭后代谢恢复特征的影响。结果发现, 暴露浓度对实验鱼的U_burst和相对爆发游泳速度(rU_burst)均影响显著(P<0.05), 5 mg/L PFOS暴露导致U_burst和rU_burst分别下降了17.4%和10.8%, PFOS对rU_burst的影响表现出“非单调剂量效应”; 暴露浓度对实验鱼的RMR影响显著(P<0.05), 5 mg/L PFOS暴露导致RMR显著升高, 但PFOS对运动后代谢峰值(MMR)、代谢率增量(MS)、代谢变化倍率(F-MS)、力竭运动后过量氧耗(EPOC)无显著影响(P>0.05)。研究结果提示: PFOS污染改变实验鱼能量代谢水平的下限, 而对其代谢水平的上限无明显的限制性作用; PFOS污染将可能对鱼类捕食——逃避捕食者、穿越激流寻找适宜生境等生存关联的生命活动起到负面影响, 但对无氧代谢关联的代谢恢复能力无显著的生态毒理效应。     

锦鲫的摄食代谢与运动代谢及其相互影响

为了探讨锦鲫(Carassius auratus)幼鱼摄食后特殊动力作用(SDA)的变化特征及运动代谢与摄食代谢之间的相互影响,实验首先灌喂锦鲫4%体重的饲料和等体积的纤维素(湿重),测定灌喂前后的耗氧率;另设灌喂饲料、灌喂纤维素、空腹组(对照组)3个组,测定3组的临界游泳速度(Ucrit)和运动耗氧率(MO2);然后在70%、0%临界游泳速度下,分别测定饱足摄食组和空腹组的耗氧率。结果显示:1灌喂饲料后代谢率快速上升,达到峰值后又迅速下降,代谢时间较短,没有一个相对稳定的平台期,灌喂纤维素后代谢率没有显著性变化(P0.05)。提示锦鲫幼鱼的特殊动力作用功率曲线为一个典型的"三角型"模型,且在特殊动力作用总耗能中,生化特殊动力作用占特殊动力作用总耗能的绝大部分,而机械特殊动力作用只占特殊动力作用的极少部分。2锦鲫幼鱼在摄食后临界游泳速度显著下降(P0.05),代谢率显著升高(P0.05)。摄食后的运动过程中,代谢率从摄食开始到代谢率回落至空腹组代谢的标准误范围内的首个数据所对应的时间长度均为6.5 h,且摄食代谢无显著性差异。提示,对锦鲫幼鱼来说,摄食代谢降低了其运动能力,而运动代谢并没有影响摄食代谢。     

饥饿对鲤幼鱼内脏器官指数和力竭运动后代谢特征的影响

为了考察不同饥饿时间对鲤幼鱼内脏器官指数和力竭运动后代谢特征的影响, 在(25±0.5)℃条件下, 将35尾实验鱼[体质量(21.34±0.42) g, 体长(9.39±0.08) cm]随机平均分成5组, 即: 对照组(S0)、1周(S1)、2周(S2)、4周(S4)和8周(S8)饥饿组, 相应时间的饥饿处理后测定各实验组鱼体内脏器官指数及力竭运动后过量耗氧(Excess post-exercise oxygen consumption, EPOC)。结果发现: 除了体长以外, 鲤幼鱼体质量、空壳湿重、内脏团湿重、肝脏湿重、消化道湿重、心脏湿重和鳃湿重等均随着饥饿时间的延长呈下降趋势。S2、S4和S8组的幼鱼空壳指数显著高于S0和S1组(P<0.001)。S2、S4和S8组的幼鱼内脏团指数和肝脏指数都显著低于S0和S1组(P<0.001)。S1组幼鱼消化道指数显著低于S0组, 但显著高于S2、S4和S8组(P<0.001)。心脏指数和鳃指数在所有实验组之间差异不显著(P>0.05)。S1组幼鱼运动前代谢率显著低于S0组(P<0.001), 但显著高于S2、S4和S8组(P<0.001)。S1组幼鱼运动代谢峰值和代谢率增量与S1组差异不显著(P>0.05), 但显著高于S0、S4和S8组(P<0.001, P=0.003)。各组间幼鱼代谢峰值时间差异不显著(P>0.05)。各个饥饿组幼鱼运动代谢峰值比率都显著高于S0组(P=0.002)。S1组的幼鱼EPOC与S0和S2组的差异不显著(P>0.05), 但显著高于S4和S8组(P=0.043)。综上所述: (1) 鲤幼鱼各个组织器官对饥饿胁迫的响应不尽相同, 这可能与其执行的生理功能差异有关; (2) 短期饥饿胁迫提升了鲤幼鱼有氧和无氧代谢能力, 这可能有利于其摄食和逃逸能力的提高, 进而提高其生存适合度。     

溶氧水平对鳊鱼、中华倒刺鲃幼鱼游泳能力的影响

在(25 1)℃条件下, 以鳊鱼(Parabramis pekinensis)体重(4.70 0.11)g, n=32、中华倒刺鲃(Spinibarbus sinensis)体重(3.26 0.06)g, n=32幼鱼为研究对象, 采用鱼类游泳代谢测定仪在水体溶氧为8、4、2、1 mgO2/L条件下分别测定其临界游泳速度(Ucrit)和游泳代谢率(MO2), 并计算出静止代谢率(MO2rest)、最大游泳代谢率(MO2max)、代谢范围(MS)及单位位移能耗(COT)等相关参数。结果显示, 随着溶氧水平的下降, 鳊鱼、中华倒刺鲃幼鱼的Ucrit均逐渐下降, 除中华倒刺鲃幼鱼的值在4与8 mgO2/L下没有显著性差异外, 其他各组均差异显著(P0.05); 在同一溶氧水平下的中华倒刺鲃Ucrit显著大于鳊鱼(P0.05)。两种鱼的MO2max和MS均随DO的下降而显著下降, 但MO2rest在溶氧水平低于1 mgO2/L才显著下降(P0.05)。研究还发现鳊鱼、中华倒刺鲃幼鱼的MO2在同一游泳速度下随溶氧水平下降而降低, 而在相同溶氧水平下随游泳速度的上升而显著升高(P0.05); COT随游泳速度上升而显著降低(P0.05), 但在高游泳速度下相对稳定, 在同一游泳速度下随着DO的下降有所减小。中华倒刺鲃的COT整体上小于鳊鱼, 且在低游泳速度下差异更大。87.5%(1-8 mgO2/L)溶氧水平的下降导致两种鱼类相似的Ucrit变化(53% vs. 50%), 但溶氧水平由8降到4 mgO2/L时, 鳊鱼32%MO2max的下降导致Ucrit下降13%, 但同样的溶氧水平下降虽然导致中华倒刺鲃的MO2max下降20%, 但由于MO2rest和COT的下降, 其Ucrit并没有显著的变化。实验结果表明: 不同溶氧水平对不同鱼种游泳能力的影响存在差异, 这种差异与其代谢对策密切相关。       

Effect of meal size on excess post-exercise oxygen consumption in fishes with different locomotive and digestive performance

Effects of feeding on pre-exercise VO₂ and excess post-exercise oxygen consumption (EPOC) after exhaustive exercise were investigated in sedentary southern catfish, active herbivorous grass carp, omnivorous crucian carp, and sluggish omnivorous darkbarbel catfish to test whether feeding had different effects on EPOC and to compare EPOC in fishes with different ecological habits. For fasting fish, the pre-exercise and peak post-exercise VO₂ were higher and recovery rates were faster in crucian carp and grass carp compared to those of darkbarbel catfish and southern catfish. EPOC magnitudes of grass carp and southern catfish were significantly larger than those of crucian carp and darkbarbel catfish. Feeding had no significant effect on peak post-exercise VO₂, recovery rate, and EPOC magnitude in grass carp. Both the pre-exercise and peak post-exercise VO₂ increased with meal size, while the EPOC magnitude and duration decreased significantly in the larger meal size groups of crucian carp and southern catfish. In darkbarbel catfish, both the pre-exercise and peak post-exercise VO₂ increased with meal size, but the VO₂ increment elicited by exercise was larger in feeding groups compared with the fasting group. These results suggest that (1) the characteristics of the post-exercise VO₂ profile, such as peak post-exercise VO₂ and recovery rate, were closely related to the activity of fishes, whereas the EPOC magnitude was not and (2) the effects of feeding on EPOC were more closely related to the postprandial increase in VO₂.     

Effect of feeding and fasting on excess post-exercise oxygen consumption in juvenile southern catfish (Silurus meridionalis Chen)

The impact of feeding (fed to satiation, 13.85% body mass) on excess post-exercise oxygen consumption (EPOC, chasing for 2.5 min) was investigated in juvenile southern catfish (Silurus meridionalis Chen) (38.62-57.55 g) at 25. Cutlets of freshly killed loach species without viscera, head and tail were used as the test meal, and oxygen consumption (VO(2)) was adjusted to a standard body mass of 1 kg using a mass exponent of 0.75. Resting VO(2) increased significantly above fasting levels (49.89 versus 148.25 mg O(2) h(-)(1)) in 12 h postprandial catfish. VO(2) and ventilation frequency (V(f)) both increased immediately after exhaustive exercise and slowly returned to pre-exercise values in all experimental groups. The times taken for post-exercise VO(2) to return to the pre-exercise value were 20, 25 and 30 min in 12 h, 60 h and 120 h postprandial catfish, respectively. Peak VO(2) levels were 257.36+/-6.06, 219.32+/-6.32 and 200.91+/-5.50 mg O(2) h(-1) in 12 h, 60 h and 120 h postprandial catfish and EPOC values were 13.85+/-4.50, 27.24+/-3.15 and 41.91+/-3.02 mg O(2) in 12 h, 60 h and 120 h postprandial southern catfish, respectively. There were significant differences in both EPOC and peak VO(2) during the post-exercise recovery process among three experimental groups (p<0.05). These results showed that: (1) neither digestive nor exhaustive exercise could elicit maximal VO(2) in southern catfish, (2) both the digestive process and exercise (also the post-exercise recovery process) were curtailed under postprandial exercise, (3) the change of V(f) was smaller than that of VO(2) during the exhaustive exercise recovery process, (4) for a similar increment in VO(2), the change in V(f) was larger during the post-exercise process than during the digestive process.     

The effects of meal size on postprandial metabolic response and post-exercise metabolic recovery process in juvenile black carp (Mylopharyngodon piceus)

The effects of meal size on the postprandial metabolic response and of digestion on the post-exercise metabolic recovery process were investigated in juvenile black carp (Mylopharyngodon piceus) . Experimental fish were forcedly fed with compound feed (meal sizes: 0.5%, 1% and 2% body weight). Then, the postprandial oxygen consumption rate and excess post-exercise oxygen consumption (EPOC) of the experimental fish were measured. Both the duration and the peak of oxygen consumption rate (PMR) increased with increasing meal size. The peak post-exercise metabolic rate of digesting fish were significantly higher, whereas EPOC magnitude and its duration were significantly smaller or (shorter) than those in the fasting fish. It is suggested that (1) this fish fulfills the increased energy demand during the digestive process by increasing PMR and by prolonging SDA duration with increasing meal size and (2) digesting fish might decrease their anaerobic exhaustive activity but increase the post-exercise recovery capacity.     

Roles of lactate and catecholamines in the energetics of brief locomotion in an ectothermic vertebrate

We have investigated the magnitude and duration of excess post-exercise oxygen consumption (EPOC) in a lizard following a single bout of vigorous exercise of 5-60 s, common activity durations for many ectothermic vertebrates. Desert iguanas (Dipsosaurus dorsalis) were run for 5 s, 15 s, 30 s, or 60 s. Oxygen consumption (VO2) increased from 0.16 ml O2 g(-1) h(-1) at rest to 1.3-1.6 ml O2 g(-1) h(-1) during 5-60 s of running. EPOC duration increased with activity duration, ranging from 35-63 min. EPOC volume, the excess oxygen consumed post-exercise, doubled from 0.13 ml O2 g(-1) following 5 s of activity to 0.25 ml O2 g(-1) after 60 s. EPOC represented 91-98% of the total metabolic expense of the activity. EPOC durations were always shorter than the period required for lactate removal, illustrating that these two processes are not causally related. Alpha- and beta-adrenergic receptor blockade by phentolamine and propranolol had no effect on resting VO2 but depressed excess post-exercise oxygen consumption volumes 2540%. The extent of catechol stimulation post-exercise may be motivation or stimulus dependent. The data indicate that metabolic elevations post-exercise represent the majority of activity costs in lizards. The study suggests that EPOC of ectothermic vertebrates is sensitive to exercise duration and catecholamine release post-activity, even when activity periods are less than 60 s in duration.     

Metabolic response of bluegill to exercise at low water temperature: implications for angling conservation

The metabolic response of fish to exercise is highly dependent on environmental factors such as temperature. In addition to natural challenges that force exercise (foraging, avoiding predators, etc.), sportfish species are also subjected to exercise when they are hooked by anglers, leading to metabolic energy costs that may impact fitness. While several studies have examined the physiological response of fish to capture in warm conditions, little work has examined this response under cold winter conditions when fish are targeted by ice-anglers. To fill this gap, we examined the metabolic impacts of exercise duration and air exposure on bluegill, Lepomis macrochirus, at a temperature typical for ice angling. Thirty-two bluegill were subjected to a simulated angling session which included either a light (30 s) or exhaustive exercise procedure, followed by either 30 s or 4 min of air exposure. Fish were then assessed at 5 °C for the following metabolic metrics using intermittent-flow respirometry: standard metabolic rate (SMR), maximum metabolic rate (MMR), aerobic scope (AS), recovery time, and excess post-exercise oxygen consumption (EPOC). Fish exercised to exhaustion had higher EPOC compared to lightly exercised fish, however EPOC was not affected by air exposure time. No other metrics were impacted by air exposure or exercise duration. These results are directly applicable to physiological outcomes for fish captured by ice-anglers during the winter and suggest that both low temperatures and low durations of exercise serve to keep metabolic costs low for fish angled during the winter months.     

不同温度条件下运动和摄食对细鳞鲑幼鱼代谢模式的影响

为了揭示不同温度条件下运动和摄食对细鳞鲑幼鱼代谢模式的影响,在饱和溶氧(>8.0 mg·L^-1)条件下,分别测定了空腹组和摄食组在5个处理温度(4、8、12、16和20 ℃)下的运动前代谢率(MO_2p)、活跃代谢率(MO_2a)、代谢范围(MS)、临界游泳速度(U_C)以及10个流速水平下的实时游泳代谢率(MR).结果表明: 在各个温度条件下,摄食组的MO_2p和MO_2a均显著高于空腹组(P<0.05),且分别提高了15%和12%(4 ℃)、47%和23%(8 ℃)、30%和21%(12 ℃)、43%和36%(16 ℃)及8%和7%(20 ℃);摄食组与空腹组的U_C和MS均无显著性差异(P>0.05),但随着温度升高,两组的MS均呈现下降趋势;随流速的增加,各组的游泳代谢率呈先升高后降低的变化规律,且摄食组显著大于空腹组(P<0.05),各组的最大代谢率峰值均出现在低于U_C的流速条件下;在细鳞鲑幼鱼的游泳速度接近70%U_C的运动过程中,其代谢率不断增大至峰值,随后在游泳速度达到U_C的过程中,代谢率呈下降趋势.表明在一定温度范围条件下,细鳞鲑幼鱼的最大代谢率是由运动与摄食共同诱导产生的,在达到最大代谢率峰值的过程中代谢表现为添加模式;之后随游泳代谢率的下降,摄食诱导的代谢率被削减,该过程表现为运动优先代谢模式.     

Excess postexercise oxygen consumption is unaffected by the resistance and aerobic exercise order in an exercise session

The main purpose of this study was to compare the magnitude and duration of excess postexercise oxygen consumption (EPOC) after 2 exercise sessions with different exercise mode orders, resistance followed by aerobic exercise (R-A); aerobic by resistance exercise (A-R). Seven young men (19.6 ± 1.4 years) randomly underwent the 2 sessions. Aerobic exercise was performed on a treadmill for 30 minutes (80-85% of reserve heart rate). Resistance exercise consisted of 3 sets of 10 repetition maximum on 5 exercises. Previous to the exercise sessions, V(O2), heart rate, V(CO2), and respiratory exchange rate (RER) were measured for 15 minutes and again during recovery from exercise for 60 minutes. The EPOC magnitude was not significantly different between R-A (5.17 ± 2.26 L) and A-R (5.23 ± 2.48 L). Throughout the recovery period (60 minutes), V(O2) and HR values were significantly higher than those observed in the pre-exercise period (p < 0.05) in both exercise sessions. In the first 10 minutes of recovery, V(CO2) and RER declined to pre-exercise levels. Moreover, V(CO2) and RER values in A-R were significantly lower than in R-A. In conclusion, the main result of this study suggests that exercise mode order does not affect the EPOC magnitude and duration. Therefore, it is not necessary for an individual to consider the EPOC when making the decision as to which exercise mode is better to start a training session.     

摄食和饥饿对大口黑鲈游泳运动能力和低氧耐受的影响

为了研究摄食和饥饿对鱼类游泳运动能力和低氧耐受的影响; 以大口黑鲈(Micropterus salmoides)为对象, 在25℃下, 测定对照组(禁食2d)、摄食组(摄食后3h)和饥饿组(禁食16d)实验鱼的日常代谢率(RMR)、活跃代谢率(AMR)、代谢范围(MS)、临界游泳速度(U_crit)、临界氧压(P_crit)和失去平衡点(LOE)。研究显示摄食后实验鱼RMR显著提升, AMR没有显著变化, 而MS和U_crit显著下降(P<0.05); 饥饿后实验鱼RMR、AMR和MS均没有显著变化, 而U_crit显著下降(P<0.05); 摄食后实验鱼P_crit显著上升, 溶解氧(DO)高于P_crit时的代谢率(MR)与DO之间的关系的斜率显著大于对照组所对应的斜率, 而LOE没有变化(P<0.05); 饥饿后实验鱼P_crit和LOE均没有显著变化, 而DO 低于P_crit时的MR与DO之间的关系的斜率显著小于对照组所对应的斜率(P<0.05)。结果表明, 摄食削弱大口黑鲈游泳运动能力是因为“心鳃”系统对其有氧代谢能力的限制; 饥饿后大口黑鲈游泳运动能力下降可能与其无氧代谢能力下降相关; 摄食削弱大口黑鲈的低氧耐受, 而饥饿后其低氧耐受有所增强, 但大口黑鲈低氧耐受总体趋于保守。