Under most conditions the amount of metabolic heat produced by a frog is so small that the animal behaves like a non-living system and its temperature is controlled by external physical conditions.

The frog’s skin is so permeable that when the animal is exposed to moderately rapidly moving air (1 m. per sec. or over) evaporation reduces its internal temperature to the wet-bulb temperature.

About 25 % of the frog’s weight may be lost by evaporation before death ensues. After death water continues to evaporate at the same rapid rate until 50 % of the animal’s weight is lost.

It is well known that poikilothermous animals may have internal body temperatures different from that of the surrounding air. Their heat of metabolism tends to raise their body temperature, while evaporation of water has the opposite effect. A frog, exposed to saturated air, still loses water by evaporation from its skin, because the animal is warmer than the air (Adolph, 1932); the difference in temperature is, however, only a very small fraction of a degree. In unsaturated air, however, heat loss by evaporation greatly outweighs heat production by metabolism, and the animal may then be many degrees cooler than the air (Hall & Root, 1930).

This paper describes some experiments showing the effects of evaporation on the frog, and measurements of the animal’s internal temperatures under a variety of conditions.

The internal temperature of the frog was determined using a specially constructed mercury thermometer with a small bulb with little capacity for heat; this gave readings accurate to 0.1°C. very rapidly. The thermometer was inserted into the rectum of the frog. Usually the thermometer was inserted with the bulb at approximately the same temperature as the body of the animal, but even if it were io° different, its thermal capacity was so small that any error in the result was negligible (i.e. less than 0.1°C.).

When the evaporation from the frog was to be measured, the animal was removed from the water, dried with a duster and squeezed to empty the bladder. (This did not always succeed completely, but no urine was passed after the animal had been exposed to air for five minutes.) The frog was weighed to the nearest 110, g. It was then placed in a gauze cage and exposed to a current of air from an ordinary electric fan, the speed of the current being varied by altering the speed of the motor and the distance of the fan from the cage. This method, though crude, gave air speeds which when tested with an anemometer were found to vary only about 10 % over the whole area available to the frog. The best proof of the efficiency of the method is given by the uniformity of the results obtained. For accurate work at higher air speeds, an apparatus such as that used by Ramsay (1935) is necessary, but for lower velocities the technique used here is quite adequate.

At appropriate intervals the frog was removed from the cage to determine its temperature and weight. Both these measurements were made within i min.

About seventy frogs {Rana temporaria L.) were used in these experiments. They were small animals weighing 20 g. or less, and had been starved for some days before being used. The surface area of the skin of these frogs was about 80 sq. cm.

This was determined by removing the skin, floating it on to paper and measuring the area covered. Some previous workers (see Benedict, 1932) have assumed that there is a relation between the weight of a frog and its surface area. This is often absurd, because starvation and egg-laying can practically halve an animal’s weight, and desiccation can easily cause a loss of 25 % ; starvation or desiccation will hardly change the area of the skin.

The results figured here (Figs. 1-4) are taken from individual frogs. Under similar conditions, practically identical results for water loss and internal temperature were always obtained, and it appears simpler to give representative examples rather than average figures. For each of the curves shown, at least ten other examples could be given.

Fig. 1.

The internal temperature of frogs exposed to air moving at different speeds. The results are given in relation to the wet-bulb temperature (W.B.). D.B. = dry-bulb temperature.

Fig. 1.

The internal temperature of frogs exposed to air moving at different speeds. The results are given in relation to the wet-bulb temperature (W.B.). D.B. = dry-bulb temperature.

(a) The frog’s temperature in water

When the internal body temperature of a frog which had been immersed in water for more than 15 min. was measured, it was never more than o-i° C. different from that of the water. This result was obtained at many temperatures between 0 and 35° C. At the lower temperature, animals previously acclimatized to high temperatures went into chill coma (Mellanby, 1940a, b); at temperatures over 30° C., heat rigor was frequently obtained (Woodrow & Wigglesworth, 1927);

A frog whose body temperature was different from that of the water to which it was transferred soon assumed the water temperature. This process was complete within 15 min., but within a much shorter period a near approximation was reached. Thus, for instance, when an animal with body temperature of 6.o° C. was transferred to water at 28° C., within 5 min. the internal body temperature rose to 26.8° C. The circulation of blood, particularly rich in the skin, no doubt assists in this rapid equilibration.

No matter how much it was stimulated, a frog in water was never found to be as much as 0.1° C. warmer than the surrounding liquid. Metabolic heat must have been produced, but its effects on body temperature were very slight.

(b) The frog’s temperature in air

In unsaturated air, the frog is considerably cooler than its surroundings. Amphibian skin is known to offer little resistance to evaporation (Gray, 1928; Krogh, 1939), and the following experiments show how remarkably permeable it is. The evaporation is responsible for the very considerable lowering of the animal’s body temperature.

In one series of experiments, frogs from water at room temperature (21° C.) were exposed to air with different velocities and the changes of internal temperature are shown in Fig. 1, while their loss of weight due to evaporation is shown in Fig. 2. In still air the animal’s temperature fell about 3° C. in an hour. In moving air the falling temperature was much more rapid amounting to as much as 5° C. in 5 min. in air moving at a rate of 1.9 m. per sec. With air as rapidly moving as this the frog was only 0.1°C. above the wet-bulb temperature (7.4° C. below the dry-bulb temperature) within 15 min. The wet-bulb temperature is the lowest temperature which it is physically possible to reach by means of evaporation, so the frog could not very well get much colder. It will be seen that even with air moving as slowly as 0.3 m. per sec., the evaporation was sufficient to reduce the internal temperature of the animal to within half a degree of the wet-bulb temperature.

Fig. 2.

Loss of weight of frogs exposed to moving air. Inset: rate of loss after first half hour.

Fig. 2.

Loss of weight of frogs exposed to moving air. Inset: rate of loss after first half hour.

At the beginning of each experiment changes in weight of the animals were slightly erratic due to a small uncontrolled production of urine, but it will be seen from Fig. 2 that the rate of loss of water soon became remarkably steady. The small inset on the figure shows the rate of loss after the first 30 min. for four different air velocities.

The relation between evaporation and body temperature is again shown in Fig. 3. Here one frog was exposed first to slowly moving air, then to a more rapid current, and finally to still air. Evaporation as measured by change in body weight proceeded moderately rapidly (1.2 g. per hr.) when the air speed was 0.3 m. per sec. ; when the air speed was increased to 1.9 m. per sec. the rate of evaporation was doubled and in still air only about 0.3 g. of water was lost during the hour. In the slowly moving air, the body temperature was reduced to within less than a degree of the wet-bulb temperature. The swiftly moving air further reduced the body temperature right down to the wet-bulb temperature and then in still air the frog became nearly 3° warmer.

Fig. 3.

The internal temperature and loss in weight of a frog exposed to different air velocities.

Fig. 3.

The internal temperature and loss in weight of a frog exposed to different air velocities.

Even after it was dead the frog continued to lose water at an equally rapid rate. In Fig. 4 a small frog weighing at the start 12.2 g. was desiccated by being exposed to a current of 0.3 m. per sec. for 24 hr. The animal lost water at a rate of about 1g. per hr., and this loss proved fatal in about 212 hr. However, the rate of loss was maintained steadily for 6 hr. until the animal had lost 50% of its original body weight. After this the loss in weight fell very considerably, so that during the final 12 hr. the animal only lost ½ g. and finished by being almost completely desiccated, having lost 74 % of its original weight. It should be noted that to the touch the skin of the animal appeared quite dry, even some time before it died although it was losing water by evaporation at this very considerable speed. During the first few minutes this frog’s internal temperature fell 6.5° C. to just above the wet-bulb temperature. So long as the rapid evaporation was maintained (i.e. for about 6 hr.) the internal temperature of the animal remained at this low level, but during the latter part of the experiment when the desiccated animal was losing water slowly, the internal temperature rose and at the end of 24 hr. had practically reached air temperature. The fact that this animal lost water as rapidly after death as when alive, means that in comparison with the loss from the skin, evaporation during respiration must have been negligible.

Fig. 4.

The internal temperature and loss in weight of a frog desiccated until death and for many hours after death.

Fig. 4.

The internal temperature and loss in weight of a frog desiccated until death and for many hours after death.

As the internal temperature of a frog exposed to moving air is the same as the wet-bulb temperature, evaporation must be taking place as rapidly as is physically possible. Even if the animal had no skin, water could not be lost more rapidly. It is of interest to compare this process with the speed of water uptake through the skin of the frog. Adolph (1933) states that “it may be noted that the most rapid desiccation by a current of dry air caused the frog to lose water less rapidly than the same frog gained water when put into water again”, but this statement is not correct. The frog exposed to an air current of 1.9 m. per sec. (see Fig. 2) lost 3.2 g. of water per hour but only absorbed 1.6 g. per hr. when returned to water. This rate of increase is as rapid as was ever found by Adolph (the frog weighed 21 g. undesiccated, and so gained nearly 8% and lost almost 16% in an hour), but with more rapid currents and drier air considerably greater losses of water were obtained over short periods. The limit to the rate of loss is probably governed by the speed with which water reaches the skin and not by its permeability. The comparative slowness of uptake of water by osmosis, notwithstanding the difference of osmotic pressure of about 4 atm., must be due to its “stagnation” within the thickness (70 µ) of the skin.

When we say that the internal temperature of a frog exposed to moving air is the same as the wet-bulb temperature, it is obvious that this is only an approximation. The salts dissolved in the body fluids must tend to prevent evaporation andto keep up the temperature. However, water evaporates from a solution of equivalent strength very nearly as fast as from distilled water unless the air is almost saturated, and under most experimental conditions the effect of the substances dissolved will be practically negligible. Then the heat of metabolism of the frog will tend to raise its internal body temperature. It may be of some interest to give an idea of the magnitude of the two processes of heat production by metabolism and heat loss by evaporation. At 20° C. a 20 g. frog will produce approximately 2 mg. CO2per hr. (Vernon, 1895); this means that about 6 cal. will be produced. This frog may lose 3.2 g. of water by evaporation in an hour. The evaporation will absorb nearly 2000 cal. (Mellanby, 1932). This comparison makes it obvious that in dry air the heat gained by metabolism is negligible compared with the enormous loss due to evaporation. It is not always realized how low is the rate of metabolism of poikilotherms. Even when they are warmed to 37° C., at which temperature their metabolism reaches a maximum, reptiles and amphibians still have a metabolic rate only about 20% of that of a mammal of similar size (Benedict, 1932).

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