温度对军配盲蝽生长发育及繁殖的影响

【目的】为明确温度对军配盲蝽Stethoconus japonicus生长发育及繁殖的影响。【方法】以悬铃木方翅网蝽Corythucha ciliata为猎物,置于15、20、25、30和35℃的人工气候箱恒温条件下饲养军配盲蝽,统计恒温处理下军配盲蝽发育历期、存活率和成虫繁殖力等指标,计算其发育起点温度与有效积温。【结果】在15-35℃内,军配盲蝽各虫态发育历期均随温度升高而缩短。军配盲蝽卵、若虫、卵-成虫、产卵前期及世代存活率随温度升高均先增加后降低,在25℃下的存活率最高。军配盲蝽全世代的发育起点温度为10.59℃,有效积温550.22日·度。随着温度升高,成虫寿命和雌虫产卵期逐渐缩短,雌虫寿命较雄虫长,25℃时单雌平均产卵量最大,为218.36粒,35℃时最低,为47.62粒。25℃下军配盲蝽实验种群趋势指数值最大,为I=18.01,是20℃的2.05倍,30℃的7.97倍。【结论】25-30℃最有利于军配盲蝽实验种群的增长。研究结果为室内人工繁殖军配盲蝽提供基础参考数据。     

温度对加州新小绥螨以截形叶螨为猎物的发育及繁殖的影响

在15～35℃、RH80%～85%条件下,研究了加州新小绥螨Neoseiulus (Amblyseius) californicus (Mcgregor)以截形叶螨Tetranychus truncatus Ehara为猎物时,不同螨态的发育和实验种群生命表。结果表明,加州新小绥螨在此温度范围内能完成世代发育,世代发育历期随着温度升高而逐渐缩短。该螨能适应35℃的高温条件,雌性的发育历期最短仅为6.14d。平均产卵期和平均寿命均随着温度的上升逐渐缩短。20℃～25℃时,该螨的平均产卵量最大,达53.73粒/雌。净增殖率在20℃时最高(48.2525),且雌雄性比最大。15℃时内禀增长率和周限增长率均最低,分别为0.0638和1.0659,种群倍增时间最长(10.8669d),35℃时内禀增长率和周限增长率均最高,分别为0.1954和1.2158,种群倍增时间最短(3.5477d)。     

温度对巨膜长蝽生长发育与繁殖的影响

【目的】近年来巨膜长蝽Jakowleffia setulosa (Jakovlev)由稳定种群的荒漠昆虫上升为暴发性发生并迁移至农区危害的农业害虫。由于缺乏巨膜长蝽生物学基础研究,给监测预警及综合防治带来许多困难。本研究旨在探明温度对巨膜长蝽发育和繁殖的影响。【方法】本实验以白茎盐生草Halogeton arachnoideus Moq.为寄主植物,分别在7个恒温（13,18,23,28,33,35和37℃）下研究了温度对巨膜长蝽各虫态平均发育历期、发育速率、成活率、产卵量和种群参数的影响。【结果】在13~37℃范围内,各虫态的发育历期随温度的升高而缩短,13℃完成一个世代发育需要82.63 d,37℃只需要14.61 d。各虫态的发育速率（V）与温度（T）的关系均符合多项式回归模型,且极显著相关。采用直接最优法分析,巨膜长蝽世代的发育起点温度为8.30℃,有效积温为555.77日·度,在宁夏一年可发生2代。巨膜长蝽世代存活率均在33℃时最高,为35.44%。28～37℃之间单雌产卵量较多,达到10粒以上,通过方程拟合得到理论上雌虫产卵最适温度为34.59℃,产卵量最高可达到16.73粒/雌;种群趋势指数在13℃为零,18～23℃小于1,种群呈负增长;28～37℃大于1,且33℃时最高,为2.77;净增殖率、内禀增长率及周限增长率均在37℃时最高,分别为7.24, 0.3912和1.4787;种群世代周期以13℃时最长,为45.8936 d,37℃时最短,为5.0608。【结论】巨膜长蝽在28～35℃下存活率、增长指数和繁殖力较高,说明该温度范围是巨膜长蝽生长发育和繁殖的适宜温度。本研究为有效开展巨膜长蝽的监测预报及综合防控提供了科学依据。     

腐食酪螨在不同温度和营养条件下生长发育的比较研究

在12.5℃、15℃、20℃、25℃和30℃恒温下,用啤酒酵母粉和玉米粉为饲料,测定了不同温度和饲料条件下腐食酪螨Tyrophagus putrescentiae各个发育阶段和世代的发育历期,获得其在各条件下的发育起点温度和有效积温。结果表明,在本文的实验温度范围内,该螨的发育历期与温度呈负相关,即随着温度的升高发育历期缩短。在各发育阶段不同饲料条件下发育起点温度和有效积温都有所差异。用啤酒酵母粉作饲料时,腐食酪螨的全世代历期为48.04天（12.5℃下）和8.41天（30℃下）,发育起点温度为10.18℃,有效积温为155.44 d·℃; 用玉米粉作饲料时,全世代历期为78.79天（12.5℃下）和10.77天（30℃下）,发育起点温度为10.52℃,有效积温为208.33 d·℃。以成螨体长和体宽为指标,比较了在各温度条件及不同饲料条件对其生长的影响,结果表明不同饲料对螨体大小有显著影响,温度的影响不明显。     

斯氏新小绥螨以神泽氏叶螨为猎物的发育与实验种群生命表研究

本研究进行了斯氏新小绥螨Neoseiulus swirskii （Athias-Henriot）以神泽氏叶螨Tetranychus kanzawai（Kishida）为猎物时,在15℃、18℃、20℃、25℃、30℃和35℃下的发育历期和实验种群生命表的研究,结果表明15℃时斯氏新小绥螨不能完成发育,18℃时仅少量个体能完成发育.在18～35℃之间,雌螨的发育历期为7.15～18.70 d,雄螨的发育历期为4.00～16.20 d.在20℃～35℃之间,斯氏新小绥螨的雌雄性比（♀∶♂）随着温度的升高而变小,20℃时性比最大（1.77）,25℃时净增殖率（R0）最大（36.497）,35℃时世代生长周期最短（15.433）,30℃时内禀增长率（rm）和周限增长率（λ）均最大,分别为0.197和1.218,种群倍增时间（t）最短（3.513）;随着温度的增加,斯氏新小绥螨的平均寿命逐渐变短,20℃时最长（73.40±1.26 d）,35℃时最短（25.10±1.20d）;25℃时每雌平均产卵量最高（60.44±1.51粒/雌）,35℃时日平均产卵量最高（2.06±0.09粒/雌/d）.     

温湿度对腐食酪螨存活和繁殖的影响

研究了33种不同温湿度处理对腐食酪螨卵发育、孵化,成螨存活和繁殖的影响。结果表明：在15±1℃、20±1℃、25±1℃、30±1℃、35±1℃5种恒温下,相对湿度低于60％腐食酪螨几乎不能存活,高湿环境条件才有利于该种群正常繁衍。在适宜相对湿度范围,湿度与腐食酪螨成螨存活率关系显著,温度与腐食酪螨卵的发育历期、成螨日均产卵量关系极显著。     

叶螨及两种替代食物对尼氏真绥螨发育和繁殖的影响

在温度25 ℃、相对湿度80％条件下,以油茶花粉、二斑叶螨和腐食酪螨3种食物饲喂尼氏真绥螨,研究不同食物对尼氏真绥螨生长发育和繁殖的影响.结果表明：尼氏真绥螨虽能取食腐食酪螨的卵,但因摄食量不足导致不能完成正常发育;而取食油茶花粉和二斑叶螨能正常完成发育,并进行繁殖.取食油茶花粉的尼氏真绥螨全世代发育历期、雌螨寿命、产卵历期、平均每雌总产卵量分别为6.18 d、24.97 d、16.72 d和23.03粒,取食二斑叶螨的尼氏真绥螨分别为5.67 d、25.72 d、18.17 d和25.38粒;以二斑叶螨为食的尼氏真绥螨发育快,寿命和产卵历期长,平均每雌产卵量高.以油茶花粉和二斑叶螨为食的尼氏真绥螨实验种群数量动态均呈上升趋势,其中以油茶花粉饲养的种群趋势指数最高（I=14.28）,以二斑叶螨饲养的种群加倍时间最短（t=3.5201 d）.     

温度对取食芦笋蓟马的巴氏钝绥螨生长发育、存活和繁殖的影响

观察了巴氏钝绥螨Amblyseius barkeri Hughes在5种温度(15、20、25、30和35℃)、食料为芦笋蓟马,相对湿度72%,L∶D=12∶12条件下的发育历期、存活率和繁殖力。结果表明:巴氏钝绥螨卵、幼螨、前若螨、后若螨及世代发育历期在15℃下最长,随着温度的升高而缩短,35℃下最短。产卵前期在15～30℃下,随温度的上升而缩短,35℃下稍有延长。存活率15℃下最低,随温度的上升而提高,30℃下最高。产卵量15℃下最少,其次是35℃,20～30℃下产卵量较多。根据实验结果,组建了巴氏钝绥螨以芦笋蓟马为食料在5种不同温度下的实验种群生命表。     

Influences of temperature on development, survival and reproduction of Amblyseius barkeri on asparagus thrips, Thrips tabaci

观察了巴氏钝绥螨Amblyseius barkeri Hughes在5种温度(15、20、25、30和35℃)、食料为芦笋蓟马,相对湿度72％,L:D=12:12条件下的发育历期、存活率和繁殖力.结果表明:巴氏钝绥螨卵、幼螨、前若螨、后若螨及世代发育历期在15℃下最长,随着温度的升高而缩短,35℃.下最短.产卵前期在15～30℃下,随温度的上升而缩短,35℃下稍有延长.存活率15℃下最低,随温度的上升而提高,30℃下最高.产卵量15℃下最少,其次是35℃,20～30℃下产卵量较多.根据实验结果,组建了巴氏钝绥螨以芦笋蓟马为食料在5种不同温度下的实验种群生命表.     

温度对三叶草彩斑蚜种群参数的影响

为了探讨温度对三叶草彩斑蚜种群增长的影响,在实验室研究了15～35℃范围内共9个温度下三叶草彩斑蚜的发育、繁殖和生命表.结果表明:三叶草彩斑蚜种群在35℃下不能存活.若虫的发育历期随着温度的上升而显著缩短,在15 ～ 32℃内为18.33～4.02 d,存活率在40.0％～83.6％,25℃下若虫的存活率最高、32℃下存活率最低.成蚜的平均寿命在10.64 ～ 20.87 d,23℃下寿命最长、32℃下最短.产蚜高峰期随温度的上升而提前,除15℃为15 d以外,其余温度下均在3～6d.平均繁殖力和单头最高繁殖力以25℃下最高,分别为82.0和149.0头.平均世代周期随着温度的上升从15℃的31.17 d逐渐缩短到32℃的10.17 d.净增殖率在25℃下最大(68.62),32℃下最小(13.96).内禀增长率在0.10 ～0.30 d-1,其中28 ℃下最高、15℃下最低.若虫的发育起点温度和有效积温分别为9.35℃和97.83 d·℃.繁殖力、净增殖率和内禀增长率与温度的关系均可用一元二次方程描述.     

Comparative study of circadian variation in oral,tympanic, forehead,axillary and elbow pit temperatures measured in a cohort of young university students living their normal routines

The primary objective of the present research work is to study and compare the circadian variability in body temperature recorded from different locations of the body during subjects’ normal routines. Temperatures of oral cavity (sublingually), tympanum, forehead, axilla and the elbow pit were measured simultaneously at approximate 1-h intervals for five consecutive days during subjects’ waking span in their routine living condition. The observations were made in eight young, apparently healthy, university students. Data were analysed using cosinor rhythmometry for evaluation of circadian rhythms and two-way ANOVA with repeated measures to assess the effect of time of day and measuring site on body temperatures and their interaction. Significant circadian rhythms in body temperature, irrespective of site, were found. Based on autocorrelation analysis, it was observed that the day-to-day variability in body temperature was consistent. The acrophases of all the studied temperature rhythms were located in the afternoon, except axillary temperature, which occurred in the early evening. The mean daytime temperature was found to be the highest when recorded sublingually and it was the lowest on the forehead or elbow pit. On the basis of the results of this study, we recommend that the methods used could be introduced into laboratory courses in a curriculum of chronobiology courses for both UG and PG classes for the demonstration/study of circadian rhythms in body temperature under normal routines. The methods used are valuable as they are non-invasive, easily accepted and assessable in a student setting.     

灰飞虱发育起点温度及有效积温的探讨

利用培养箱在恒温条件下饲养灰飞虱Laodelphax striatellus Fallén,测定了卵、若虫、成虫繁殖前和全世代发育历期,用直线回归法计算了灰飞虱各虫态和全世代的发育起点温度和有效积温分别为10.06、6.43、10.29、8.08℃和102.3、365.2、87.5、552.1日·度。并根据有效积温法则预测了该虫在济宁市1年完成的代数为4～5代。     

桑树(Morus alba)朱砂叶螨（Tetranychus cinnabarinus）实验种群的温度效应

采用生命表分析、生存分析、"王-兰-丁"模型及线性模型等分析方法,对15～28℃温区的5个恒温处理朱砂叶螨(Tetranychus cinnabarinus)实验种群进行了系统研究.结果表明,此温区内,种群在生殖、发育和生存3方面,有明显的温度效应:内禀增长力、周限增长力、净增殖力和平均日产卵量、世代平均周期、及种群倍增时间的倒数呈线性增长;而平均寿命、最大死亡年龄,随温度升高而递减;性比和实际产卵天数对温度不敏感.种群在生殖、发育和生存三者之间,采取了较为"折衷"的策略:8℃为发育临界点;13℃左右为生殖和种群增长临界温度;22℃左右为生殖和种群增长最适温度;30℃左右为发育最适温度.     

竹织叶野螟发育起点温度和有效积温

采用19,22,25,28和31℃5个温度对竹织叶野螟Algedonia coclesalis Walker各虫态(龄)发育起点温度和有效积温进行测定。结果表明,竹织叶野螟的在19～31℃范围内均能正常生长发育,尤其是28～31℃范围最适宜于竹织叶野螟的生长发育。卵、1龄幼虫、2龄幼虫、3龄幼虫、4龄幼虫、5龄幼虫、6龄幼虫、7龄幼虫、蛹、成虫及世代的发育起点温度分别为6.63,12.51,11.18,10.93,10.05,8.01,6.80,5.78,6.20,7.81和8.33℃,有效积温分别为124.19,64.54,72.59,82.08,93.46,136.84,155.42,201.06,211.55,111.49和1235.50日.度。     

核桃扁叶甲的发育起点温度和有效积温

室内观察测定5个恒温条件下,核桃扁叶甲Gastrolina depressa Baly各虫态的发育历期及起点温度和有效积温。结果表明:在16～32℃温度范围内,核桃扁叶甲均能完成发育,其发育历期随温度的升高而缩短,卵期、幼虫期、蛹期、产卵前期的发育起点温度分别为9.4,12.2,14.3和11.1℃,有效积温分别为43.2,77.2,36.0和104.7日.度;整个世代的发育起点温度为12.0℃,有效积温为260.5日.度。持续过高温度不适合核桃扁叶甲的生长发育。     

变温和恒温对沙葱萤叶甲发育速率的影响

沙葱萤叶甲为近年来在内蒙古草原猖獗成灾的新害虫,为明确温度对其发育速率的影响,分别设置5个变温组合(8/20℃,11/23℃,14/26℃,17/29℃和20/32℃)和6个恒温(13℃,17℃,21℃,25℃,29℃和33℃),比较了变温和恒温对沙葱萤叶甲幼虫和蛹发育速率的影响。结果表明,不同变温组合和恒温对沙葱萤叶甲幼虫和蛹的发育速率有显著的影响。发育历期随温度的升高而缩短,在变温条件下,1龄幼虫期、2龄幼虫期、3龄幼虫期、总幼虫期和蛹期分别从最低温度组合(8/20℃,平均15℃)的11.00,13.44,23.18,46.42和16.89 d,缩短至最高温度组合(20/32℃,平均27℃)的4.92,4.63,9.17,17.83和5.83 d;在恒温条件下,13℃下幼虫不能发育和存活,1龄幼虫期、2龄幼虫期、3龄幼虫期、总幼虫期和蛹期分别从17℃的14.50,10.75,20.63,45.50和11.00 d,缩短至33℃的6.10,5.47,10.60,22.17和5.33 d。在变温条件下,幼虫和蛹的发育起点温度分别为7.44℃和8.48℃,有效积温分别为344.82日度和113.52日度;在恒温条件下,幼虫和蛹的发育起点温度分别为0.64℃和5.11℃,有效积温分别为714.28日度和147.06日度。变温促进了沙葱萤叶甲幼虫和蛹的发育,本研究结果为沙葱萤叶甲的预测预报及综合防控提供了科学依据。     

恒温下大戟长管蚜的发育起点温度和有效积温

在16,19,22,25,28和31℃恒温条件下以花卉一串红(Salvia splendens)饲养大戟长管蚜Macrosiphum euphorbiae(Thomas),测得该蚜虫的各龄历期和产仔前期,得出全若虫期的历期。依据有效积温法则计算的1～4龄若蚜和全若虫期的发育起点分别是12.5,7.8,10.3,4.1和9.3℃,有效积温分别是14.6,43.9,29.9,31.9和117.2日.度。大戟长管蚜适合生长发育的温度是19～28℃,最适合温度为25℃。     

Considerations for the measurement of core,skin and mean body temperatures

Despite previous reviews and commentaries, significant misconceptions remain concerning deep-body (core) and skin temperature measurement in humans. Therefore, the authors have assembled the pertinent Laws of Thermodynamics and other first principles that govern physical and physiological heat exchanges. The resulting review is aimed at providing theoretical and empirical justifications for collecting and interpreting these data. The primary emphasis is upon deep-body temperatures, with discussions of intramuscular, subcutaneous, transcutaneous and skin temperatures included. These are all turnover indices resulting from variations in local metabolism, tissue conduction and blood flow. Consequently, inter-site differences and similarities may have no mechanistic relationship unless those sites have similar metabolic rates, are in close proximity and are perfused by the same blood vessels. Therefore, it is proposed that a gold standard deep-body temperature does not exist. Instead, the validity of each measurement must be evaluated relative to one's research objectives, whilst satisfying equilibration and positioning requirements. When using thermometric computations of heat storage, the establishment of steady-state conditions is essential, but for clinically relevant states, targeted temperature monitoring becomes paramount. However, when investigating temperature regulation, the response characteristics of each temperature measurement must match the forcing function applied during experimentation. Thus, during dynamic phases, deep-body temperatures must be measured from sites that track temperature changes in the central blood volume.     

Evaluation of the cold strain index (CSI) for peripheral cold environmental stress

The purpose of this study was to evaluate the cold strain index (CSI) for peripheral environmental stress using data from a previous footwear study. Eight men (20±2 yr) dressed in protective cold weather clothing with varying footwear underwent 5 days of cold air (−23.4 °C) testing while attempting to sit for 240 min. Rectal, skin, and toe temperatures (T_toe) were continuously measured. All test exposures were ended after 50–165 min due to cold foot discomfort or T_toe<5 °C. However, CSI values indicated little cold strain. Therefore, we revised CSI to include peripheral cold assessment, which was found to be consistent with subject behavior and measured low T_toe.     

Development of a self-contained,indwelling vaginal temperature probe for use in cattle research

A device was developed to monitor the vaginal temperature of cattle in a research setting. This device decreases labor involved with monitoring body temperature compared with manual temperature readings, allows for continuous monitoring of vaginal temperature at 1 min intervals, and also allows for temperature measurements without the presence of a human handler or without restraint, which can agitate cattle. The device consists of a blank controlled internal drug release (CIDR) device (designed by Pfizer Animal Health as an indwelling vaginal probe) that holds an indwelling vaginal temperature probe logger. The fabrication of the vaginal probe costs approximately US $325 per unit. Similar rectal and vaginal temperature responses to lipopolysaccharide challenge were observed when vaginal and rectal temperatures were measured simultaneously in the same heifer (P>0.05). Additionally, rectal and vaginal temperatures were highly correlated (r=0.97; P<0.0001). Similar to the rectal temperature monitoring device, the vaginal device allows for the measurement of vaginal temperature without the potential biases associated with the stress response produced as a reaction to the handling by and (or) presence of humans. The vaginal temperature recording device will provide researchers with an additional inexpensive tool to study physiological responses in female cattle.