Evaporative water loss in two sympatric species of vespertilionid bat, Plecotus auritus and Myotis daubentoni: relation to foraging mode and implications for roost site selection

Simultaneous measures of oxygen consumption and evaporative water loss (EWL) were made in two species of temperate-zone vespertilionid bat ( Plecotus auritus and Myotis daubentoni ; mean body mass 9.12 and 10.12g, respectively) at ambient temperatures (T_a) of 5, 15 and 25°C and variable vapour pressure deficit. EWL was directly dependent on vapour pressure deficit and oxygen consumption and inversely dependent on T_a. EWL was significantly greater in P. auritus than in M. daubentoni. A model for EWL in P. auritus under a variety of environmental conditions (5–25°C and 20–80% relative humidity) suggested that EWL from bats in shallow summer torpor will be lowest at low T_a, and that, except at low (> 50%) relative humidity, EWL from euthermic bats will be lowest at high T_a. At low relative humidity (< 20%), resting bats could lose over 30% of body mass per day (24 h) through evaporation. At high T_a (> 25°C), EWL from euthermic bats could be over 65% lower at high (> 80%) compared to low (< 20%) relative humidity. In bats in shallow summer torpor at low (5°C) T_a the equivalent saving was > 96%. At low relative humidity predicted EWL from bats in shallow summer torpor was 34 to 81% of that from euthermic bats, and at low T_a and high relative humidity was only 2%. In the wild, M. daubentoni has freer access to drinking water than does P. auritus and yet EWL at rest was higher in the latter species. We suggest that post-prandial dumping of urinary water by M. daubentoni leads to a limit in the amount of body water available to this species to cover evaporative losses once within the day roost, which in turn has led to an adaptation of physiology towards the minimization of EWL when at rest.     

A comparison of hydration effect on body fluid and temperature regulation between Malaysian and Japanese males exercising at mild dehydration in humid heat

Background

This study investigated the effect of hydration differences on body fluid and temperature regulation between tropical and temperate indigenes exercising in the heat.

Methods

Ten Japanese and ten Malaysian males with matched physical characteristics (height, body weight, and peak oxygen consumption) participated in this study. Participants performed exercise for 60 min at 55% peak oxygen uptake followed by a 30-min recovery at 32°C and 70% relative air humidity with hydration (4 times each, 3 mL per kg body weight, 37°C) or without hydration. Rectal temperature, skin temperature, heart rate, skin blood flow, and blood pressure were measured continuously. The percentage of body weight loss and total sweat loss were calculated from body weight measurements. The percentage change in plasma volume was estimated from hemoglobin concentration and hematocrit.

Results

Malaysian participants had a significantly lower rectal temperature, a smaller reduction in plasma volume, and a lower heart rate in the hydrated condition than in the non-hydrated condition at the end of exercise (P <0.05), whereas Japanese participants showed no difference between the two hydration conditions. Hydration induced a greater total sweat loss in both groups (P <0.05), and the percentage of body weight loss in hydrated Malaysians was significantly less than in hydrated Japanese (P <0.05). A significant interaction between groups and hydration conditions was observed for the percentage of mean cutaneous vascular conductance during exercise relative to baseline (P <0.05).

Conclusions

The smaller reduction in plasma volume and percentage body weight loss in hydrated Malaysians indicated an advantage in body fluid regulation. This may enable Malaysians to reserve more blood for circulation and heat dissipation and thereby maintain lower rectal temperatures in a hydrated condition.     

Respiration in air and water of three mangrove snails

The oxygen consumption of three species of Malaysian mangrove gastropods was measured in air and sea water at the temperatures commonly recorded in the mangrove. The experiments in air were carried out after the animals had regained fluid lost from the mantle due to handling. Fluid loss can have considerable effects on rate of oxygen consumption. Nerita arliculata (Gould) was found throughout the mangrove and experiences from 50 to 92% aerial exposure. It has a gill and a ratio of aerial to aquatic respiration rates of 2.7 at 28°C. 50% of the animals can survive underwater for 72 h at 28°C. The other two species, Cerithidea obtusa (Lamarck) and Cassidula aurisfelis (Brugière) experience over 95% aerial exposure, have their mantle cavities modified as lungs and have air : water respiration rate ratios of 5.5 and 6.0, respectively. 50% can survive from 48 to 36 h underwater at 28°C. Acclimated animals have Q₁₀'s of about 1.6 in air and 1.4 in water. The respiratory physiology of the snails is compared with that of rocky shore species.     

Blood volume and total water content of the woodlouse, Oniscus asellus, in conditions of hydration and desiccation

Changes in the blood volume and total water content of Oniscus asellus were measured by means of inulin dilution and weight. The relationship between body weight and blood volume, total water content, and weight loss does not change during desiccation. The process of desiccation is similar in 0% r.h. and 62% r.h., although the rates of reduction of blood volume, total water content and weight are different in these two humidities. During desiccation most of the water lost by the animal comes from the blood. There is no evidence to suggest that O. asellus takes up an excess of water in moist conditions.     

Oral administration of γ-aminobutyric acid affects heat production in a hot environment in resting humans

Background

Central administration of γ-amino butyric acid (GABA) induces lower body temperature in animals in hot ambient air. However, it is still unknown whether oral GABA administration affects temperature regulation at rest in a hot environment in humans. Therefore, in the present study, we specifically hypothesized that systemic administration of GABA in humans would induce hypothermia in a hot environment and that this response would be observed in association with decreased heat production.

Methods

Eight male participants drank a 200-ml sports drink with 1 g of GABA (trial G) or without GABA (trial C), then rested for 30 minutes in a sitting position in a hot environment (ambient air temperature 33°C, relative humidity 50%).

Results

We found that changes in esophageal temperature from before drinking the sports drink were lower in trial G than in trial C (-0.046 ± 0.079°C vs 0.001 ± 0.063°C; P < 0.05), with lower heat production calculated by oxygen consumption (41 ± 5 W/m² vs 47 ± 8 W/m²; P < 0.05).

Conclusions

In this study, we have demonstrated that a single oral administration of GABA induced a larger decrease in body core temperature compared to a control condition during rest in a hot environment and that this response was concomitant with a decrease in total heat production.     

Sorptionsmessungen an den beiden Schabenarten Periplaneta americana und Blaberus trapezoideus

The absorption rate of adult males of the two cockroaches Periplaneta americana and Blaberus trapezoideus has been investigated by weight measurements and a tracer method.Both species loose weight in 26°C and 33%, 53%, 78%, and 98% relative humidity, and they finally die after a weight loss of 25 to 35%. Even in a high air humidity there is always a certain loss of weight. This weight loss masks the small absorption rate—shown by tracer methods—which increases disproportionally with rising humidity. The absorption represents probably a passive transport because narcotized animals show the same rate of absorption as normal insects. Also, there is a reduction of the absorption rate during exposure time. The water exchange between the animal and its atmosphere is therefore likely to lead to an equilibrium between the radioactive atmosphere and the unlabelled body water.Absorption occurs over the whole body surface. The amount absorbed via the posterior wing and the anus has no ecological significance. P. americana shows a higher cuticular permeability than B. trapezoideus.     

Water loss and respiration of Lucilia cuprina during development within the puparium

The rate of loss of water and the rate of uptake of oxygen were measured continuously throughout the development of Lucilia cuprina within the puparium. Changes in these parameters were correlated with changes observed in morphology of cuticles and respiratory structures during development.In development at 26°C, there is, at 20–22 hr after puparium formation a major loss of water by mechanical expulsion of moulting fluid chiefly through the posterior larval spiracles after the severing of the posterior larval tracheae. This loss of water is essential to survival and is followed by an extremely low rate of water loss attributed to slow diffusion of water through the resulting air gap between the pupal cuticle and the puparium. There is an increase in oxygen consumption during the pupal movements associated with the casting of the larval tracheae followed by a sharp reduction in oxygen consumption until the pupal horns are everted a short time later. This combination of physiological events enables development to proceed over a wide range of conditions in the puparial environment.     

Pre-exercise hyperhydration delays dehydration and improves endurance capacity during 2 h of cycling in a temperate climate

Whether the use of pre-exercise hyperhydration could improve the performance of athletes who do not hydrate sufficiently during prolonged exercise is still unknown. We therefore compared the effects of pre-exercise hyperhydration and pre-exercise euhydration on endurance capacity, peak power output and selected components of the cardiovascular and thermoregulatory systems during prolonged cycling. Using a randomized, crossover experimental design, 6 endurance-trained subjects underwent a pre-exercise hyperhydration (26 ml of water x kg body mass(-1) with 1.2 g glycerol x kg body mass(-1)) or pre-exercise euhydration period of 80 min, followed by 2 h of cycling at 65% maximal oxygen consumption (VO(.)2max) (26-27 degrees C) that were interspersed by 5, 2-min intervals performed at 80% V(.)O2max. Following the 2 h cycling exercise, subjects underwent an incremental cycling test to exhaustion. Pre-exercise hyperhydration increased body water by 16.1+/-2.2 ml.kg body mass(-1). During exercise, subjects received 12.5 ml of sports drink x kg body mass(-1). With pre-exercise hyperhydration and pre-exercise euhydration, respectively, fluid ingestion during exercise replaced 31.0+/-2.9% and 37.1+/-6.8% of sweat losses (p>0.05). Body mass loss at the end of exercise reached 1.7+/-0.3% with pre-exercise hyperhydration and 3.3+/-0.4% with pre-exercise euhydration (p<0.05). During the 2 h of cycling, pre-exercise hyperhydration significantly decreased heart rate and perceived thirst, but rectal temperature, sweat rate, perceived exertion and perceived heat-stress did not differ between conditions. Pre-exercise hyperhydration significantly increased time to exhaustion and peak power output, compared with pre-exercise euhydration. We conclude that pre-exercise hyperhydration improves endurance capacity and peak power output and decreases heart rate and thirst sensation, but does not reduce rectal temperature during 2 h of moderate to intense cycling in a moderate environment when fluid consumption is 33% of sweat losses.     

The respiratory responses of Carcinus maenas (L.) to changes in environmental salinity

Exposure of Carcinus to a reduction in salinity is accompanied by an increase in oxygen consumption. The highest rates of oxygen consumption are found during the first 2–3 h after a reduction in salinity, after which oxygen consumption then declines, but to a higher than ‘normal’ level which is maintained throughout the period of exposure to low salinity. This augmented rate of oxygen consumption persists even after 3–4 days in water of reduced salinity and indicates that the respiratory rate of Carcinus does not acclimate rapidly to reduced salinity. The increased oxygen consumption is associated with an increase in ventilation volume resulting from an increase in the rate of beating of the scaphognathites, while oxygen utilization remains at a low level. Since the oxygen-transporting properties of the blood of Carcinus show little change under conditions of reduced salinity, the increased oxygen demand of the tissues is met by a rise in cardiac output resulting mainly from an increase in heart rate.     

The environmental effects of salinity and temperature on the oxygen consumption and total body osmolality of the marine flatworm Procerodes littoralis

The present study examined the effect of salinity and temperature on the rate of oxygen consumption and total body osmolality of the triclad turbellarian Procerodes littoralis, a common marine flatworm normally found in areas where freshwater streams run out over intertidal areas. Extremes in environmental factors encountered by P. littoralis were recorded at the study site. These were salinity (0-44 psu), temperature (2.7-24.9 °C) and oxygen concentration (2.8-16.1 mg l⁻¹). Respirometry experiments showed minimal oxygen consumption rates at the salinity extremes encountered by the study species (0 and 40 psu). Further experiments showed relatively constant oxygen consumption rates over the temperature range 5-20 °C and elevated consumption rates at temperatures above 25 °C. Total body osmolality of P. littoralis increased with increasing salinity. The study illustrates how a marine flatworm uses integrated physiological and behavioural mechanisms to successfully inhabit an environment that is predominantly freshwater for up to 75% of the tidal cycle.     

The effect of extrinsic and intrinsic factors on oxygen consumption by the southern rock lobster, Jasus edwardsii

The oxygen consumption rate of the southern rock lobster, Jasus edwardsii, was evaluated in response to body weight, temperature, activity, handling, diurnal rhythm, feeding and oxygen saturation level. There was a positive relationship between standard oxygen consumption (M(O(2))) and both body weight and water temperature. The relationship between total oxygen consumption and wet whole body weight was described by the equation: LogM(O(2))=0.595log W-0.396 (r(2)=0.83). The relationship between weight-specific oxygen consumption and temperature was described by the equation: LogM(O(2))=0.047T-2.25 (r(2)=0.94). Activity had a significant influence on the oxygen consumption rate, causing a three-fold increase above the standard rate at the temperature of acclimation (13 degrees C). However, at temperatures approaching the upper and lower extremes, lobsters had a decreased ability to increase their oxygen consumption rates during activity. Lobsters took 4.5-5 h to return to standard oxygen consumption rates after a period of emersion and handling. A strong diurnal rhythm to oxygen consumption was recorded. J. edwardsii displayed a classic postprandial increase in oxygen consumption. A peak (1.72 times standard M(O(2))) occurred 10-13 h after feeding with an increase above standard M(O(2)) being maintained for 42 h. In its rested state J. edwardsii was an oxygen regulator down to a critical oxygen tension of 58 Torr, whilst activity resulted in the critical oxygen tension increasing to 93 Torr.     

中缅树鼩能量代谢的季节变化

小型哺乳动物的体重和产热特征的季节调节对其生存至关重要。为探讨中缅树鼩的能量代谢适应特征随季节的变化,采用耗氧量测定、食物平衡法、形态测量等方法,分别对其冬季和夏季的基础代谢率(BMR)、非颤抖性产热(NST)、体温、体重、蒸发失水、能量收支和消化道的长度和重量进行了测定。中缅树鼩冬季体温、体重、基础代谢率、NST、蒸发失水散热分别为37. 9℃ ± 0.14℃ ,126.1 ± 2.1 g,42. 94 ± 2.65 J/g· h,54. 97 ±2.14 J/ g·h,5. 69 ±0.33 J/ g·h;夏季体温、体重、基础代谢率、NST、蒸发失水散热分别为38.5℃ ± 0. 27℃ ,106.9 ±5.1 g,28. 69 ±3.06 J/ g·h,47.43 ± 2.45 J / g·h,7.12 ±0. 57 J/ g·h;中缅树鼩的每日摄入能、消化能、可代谢能冬季均比夏季显著增加,消化道特征冬季和夏季存在变化,随着温度降低、食物质量下降,小肠长度和重量增加。这些结果表明:中缅树鼩在冬季,通过增加体重、基础代谢率和NST、能量摄入、消化能和可代谢能,降低蒸发失水等方式应对季节性环境变化。代谢产热和消化生理调节在季节性适应过程中具有重要地位。     

The site of active uptake of atmospheric water in larvae of Tenebrio molitor

Larvae starved and desiccated for 8 days will then take up water from 93% r.h., the gain ceasing by 7 days. The rate and amount of uptake were the same in those starved at 0% r.h. as in those starved at 53% r.h. Tying off the last abdominal segment prevents uptake while tying off the first abdominal segment allowed one-third as much gain as controls. This supports the theory that active uptake of atmospheric water is by way of the rectum and not the body cuticle. Because of the time taken to reach equilibrium, of the same uptake after exposure at 53% as after 0% r.h., and of a large overshoot in uptake, it is suggested that the phenomenon in this species is a by-product of drying the faeces and not a vital aspect of the physiology of water balance.     

Effect of ingestion pattern on rehydration and exercise performance subsequent to passive dehydration

Six male volunteers performed three tests, each comprising a passive heating session to obtain dehydration (loss of 2.6% body mass), followed by exercise on a treadmill until exhaustion (50% of maximal oxygen consumption) in a warm environment (dry bulb temperature 35° C, relative humidity 20%–30%). In one test, the subjects exercised without rehydration (Dh). In the two other tests, 50% of the fluid lost in the dehydration session was replaced by drinking mineral water given either in one amount [913 (SEM 23) ml] before the exercise (Rh1) or divided into four equal portions [228 (SEM 5) ml] before the exercise and on three occasions at 15-min intervals during exercise (Rh4). Rehydration increased exercise duration in Rh1 compared to Dh [112 (SEM 7) min and 82 (SEM 3) min, respectively;P < 0.05]. The difference was not significant with Rh4 [103 (SEM 9) min]. A restoration of the time course of changes in plasma volume, plasma osmolality, heart rate and rectal temperature occurred immediately in Rh1 and was delayed in Rh4 until after 60 min of exercise. Our results demonstrated that the swift replacement of the fluid loss in the dehydrated subjects was beneficial to exercise performance by rapidly correcting the disturbances in body fluid balance.     

Studies on the critical water mass and the rehydration potential of unfed adult Dermacentor marginatus and D. reticulatus ticks (Acari: Ixodidae)

In unfed adult Dermacentor marginatus and D. reticulatusticks survival and capability to restore water balance after loss of high percentages of exchangeable body water were investigated. Furthermore, it was examined how frequently dehydrated ticks of these species were able to rehydrate by uptake of atmospheric water vapour. The critical water mass, defined as the water mass remaining in a tick at the nonambulatory state, differed between light and heavy weight groups and averaged 62.4 and 55.8%, respectively, of the total body water of fully hydrated ticks in females, and 54.4 and 51.1% respectively, in males of D. marginatus. In D. reticulatus, the corresponding figures were 55.9 and 54.7% in females and 52.1 and 52.7% in males. All ticks survived dehydration to 50, 75 or 100% of the critical water mass, and 96.7% of the D. marginatus ticks and 95.8% of the D. reticulatus ticks compensated water losses during subsequent incubation at 95% relative humidity (r.h.) and 20°C. Unfed females and males of both Dermacentor spp. were capable to balance water loss very frequently over a period of several months. When ticks were repeatedly dehydrated at 0% r.h. for 7 days and rehydrated at 95% r.h. and 20°C, females and males of D. marginatus reached the 50% mortality after 22 and 29 cycles of de- and rehydration, respectively, during 211 and 285 days, respectively. In D. reticulatus, 50% of females and males survived 23 and 17 cycles, respectively, during 248 and 186 days, respectively. Rehydration weights were as high or even higher as those of ticks kept at permanent 95% r.h.     

Effects of temperature and humidity on hydration and respiration in four strains of Drosophila

The four strains of Drosophila melanica studied were found to be most sensitive to low humidities during the first 19 hr after formation of the puparium. The mean fresh weights for the four strains were consistently different at all ages after puparium formation and at all conditions of temperature and humidity. The Forest Park strain, which showed greatest mortality at low humidity, had least body water per unit dry weight in the early pupal stage.A typical U-shaped oxygen consumption rate curve was found during the puparial-pharate adult period at all conditions of temperature and humidity. Differences among the strains were manifested at an earlier age under the more extreme environmental conditions.     

影响蝴蝶兰类原球茎耐脱水性的主要因素

为探讨蝴蝶兰(Phalaenopsis spp.)类原球茎(protocorm-like body,PLB)耐脱水性的主要影响因素,对PLB的平均粒重、含水率、脱水相对湿度、时间、温度、光周期与耐脱水性的关系进行了研究.结果表明,PLB的平均粒重与脱水后失水率、含水率、相对电导率、成活率呈显著或极显著相关.在较高湿度下...     

Activity and respiration in the anemone, Metridium senile (L.) exposed to salinity fluctuations

Activity and respiration in the anemone, Metridium senile (L.), were monitored under both constant and fluctuating salinity conditions. During constant exposure to 50% sea water it was found that the animals retracted the tentacles and that the rate of oxygen consumption decreased by ≈50%. The same response was elicited from animals in 100% sea water in a contracted state. Animals exposed to continually fluctuating salinities were found to retract the tentacles, contract the body wall, and produce amounts of mucus during periods of decreasing salinities. These reactions were reversed during exposure to increasing salinity. Oxygen consumption never ceased entirely in animals exposed to dilute sea water and it was found that during declining oxygen tension M. senile regulated its oxygen consumption until the environmental oxygen tension fell to ≈30% saturation.     

Effects of caffeine ingestion on body fluid balance and thermoregulation during exercise

This study investigated the effects of caffeine supplementation on thermoregulation and body fluid balance during prolonged exercise in a thermoneutral environment (25 degrees C, 50% RH). Seven trained male subjects exercised on a treadmill at an intensity of 70-75% of maximal oxygen consumption to self-determined exhaustion. Subjects exercised once after caffeine and once after placebo ingestion, given in a double-blind crossover design. Five milligrams per kilogram body weight of caffeine followed by 2.5 mg.kg-1 of caffeine were given 2 and 0.5 h before exercise, respectively. Rectal temperature was recorded and venous blood samples were withdrawn every 15 min. Water loss and sweat rate were calculated from the difference between pre- and post-exercise body weight, corrected for liquid intake. Following caffeine ingestion, when compared with placebo, no significant difference in final temperature or in percent change in plasma volume were found. No significant differences were observed in total water loss (1376 +/- 154 vs. 1141 +/- 158 mL, respectively), sweat rate (12.4 +/- 1.1 vs. 10.9 +/- 0.7 g.m-2.min-1, respectively), rise in rectal temperature (2.1 +/- 0.3 vs. 1.5 +/- 0.4 degrees C, respectively), nor in the calculated rate of heat storage during exercise (134.4 +/- 17.7 vs. 93.5 +/- 22.5 W, respectively). Thus, in spite of the expected rise in oxygen uptake, caffeine ingestion under the conditions of this study does not seem to disturb body fluid balance or affect thermoregulation during exercise performance.     

Occurrence,properties and biological implications of the active uptake of water vapour from the atmosphere in Psocoptera

Water vapour absorption is shown to occur in 22 species of Psocoptera inhabiting diverse environments and representing all major groups of this insect order. Evidently the faculty is a common feature of the whole order and it seems not to be related to specific environmental conditions. For the first time water vapour uptake could be demonstrated in fully winged and flying insects. The critical equilibrium humidities vary considerably among different species ranging from 58 to 85% r.h. Marked interspecific differences are also observed in water loss and uptake rates but no clear correlation with habitat or systematic group is recognizable. The uptake rates of Psocoptera are among the highest of all arthropods investigated so far. From weight recordings with a sensitive microbalance it could be seen that continuous operation of the uptake mechanism is restricted to limited periods of time of less than 1 hr regardless of the water status of the animals. Initiation and termination of the uptake process are abrupt and continuous uptake proceeds at a constant rate at a given relative humidity. Uptake rates are humidity-dependent decreasing with falling relative humidity whereas the adjustment of the equilibrium level of body water is independent of ambient humidity. Equilibrium is maintained by intermittent operation of the uptake mechanism within ca. 3% of body water mass. The uptake mechanism exhibits marked sensitivity to starvation in most members of the Psocomorpha. Some features of the uptake process of Psocoptera are in close agreement with those of Mallophaga reflecting the close relationship between the two groups.