The Effects of TemperatureEssay Preview: The Effects of TemperatureReport this essayRunning Head: THE EFFECTS OF TEMPERATUREThe Effects of Temperature and Gender on ConcentrationAnnie RiceAlbertson College of IdahoAbstractThe function of this study was to identify a potential correlation between gender and temperature that cause a direct affect on concentration. Participants assigned into hot (H), warm (W), and cold (C) condition groups observed a video clip in preset temperatures and completed surveys to measure their comprehension. The test results were not significant; however, a significant result appeared in the H condition with a 95 percent confidence interval. The males scored significantly lower in the H condition which indicates an existing correlation of gender and temperature results leading to an indirect affect on concentration.
The Effects Temperature and Gender on ConcentrationPrevious studies suggest that temperature influences the cognitive functioning of the brain. There have been no significant results to conclude temperature as the main affect however as an additional variable is integrated into the results a significance is produced. One study investigated the long-term memory development of male and female rats and concluded that temperature set at a hypothermic level affects memory retention. Additional research supports a comparable when tested in similar conditions. (Misanin, Nagy, Keiser & Bowen, 1971).
Tympanic membrane temperature was measured in the chimp subjects. In the study the chimps were to be involved in 1 of 3 cognitive tasks. These included matching to sample, visual-spatial discrimination, and a motor task. Every 20 minutes the tympanic membrane temperature was measured. This data was the first to show that physical functions of chimpanzees were lateralized. It also suggests the cognitive functions are associated with changes in cerebral blood flow.
In this study, data are presented on the use of a temperature gauge to assess changes in cerebral blood flow as reflected by changes in the tympanic membrane (TM) temperature. The TM is warmed by the brain and cooled by branches extending from the carotid artery (Webb, 1973). The TM also shares blood vessels with the hypothalamus, and TM temperature is highly correlated with the temperature of the hypothalamus (Benzinger, 1969; Dickey, Ahlgren, & Stephen, 1970; Rawson & Hammell, 1963). Two studies in humans have attempted to measure lateralized changes in cerebral temperature in relation to cognitive challenge. Meiners and Dabbs (1977) reported decreased temperature in the right ear (right hemisphere) for a spatial task compared to the left ear (left hemisphere). No differences in the reduction of ear temperature were evident for a verbal task. Swift (1991) similarly examined lateralized changes in TM temperature for verbal and spatial cognition tasks but did not find overall lateralized changes in TM temperature. The inconsistencies between these studies could be due in part to procedural and task differences. For example, Swift required participants to depress a key in response to different demands of the tasks but made no attempt to account for the effects of this motor response on temperature change. This is particularly significant because all participants were required to use their right hand to respond, which may have induced an asymmetry in temperature unrelated to the cognitive demands of the task. More recently, asymmetries in TM temperature have been found to be associated with stress behavior in human children and rhesus monkeys (Boyce, Higley, Jemerin, Champoux, & Suomi, 1996). Left-right differences in TM temperature were positively correlated with locomotion during social separation in monkeys and negatively correlated with measures of cortisol at 4 months of age.
there is a progressive deterioration in performance with increasing exposure to cold. This is reflected in the number of correct identifications and correspondent signal omissions. It should be noted that the incidence of commission errors did not vary with exposure time. The overall performance decrement is accompanied by a progressive reduction in core temperature that follows the characteristic transient increase on immediate exposure to cold ( Figure 12 ). These data suggest, therefore, that sustained attention decrement is related to dynamic deep body temperature change, although in the above case it is a reduction in core temperature level. This finding is consistent with information presented previously on performance under dynamic body temperature decrease as given in the reports of Mackworth (1950) and Pepler (1953 , 1958 ). (Hancock 1986)
This study followed the long-term memory development of male and female rats. At about 9 days old the rats started to show signs of intersession improvement when the sessions lasted at 24 hour intervals. Rats that were younger than 9 days old shows signs of short-term memory retention. During the experiment it was indicated that hypothermia caused some complications on 24 hour memory retention and that is depended on the time from training to hypothermal treatment. Research has shown that on adults it effects long-term memory. (Misanin, Nagy, Keiser, & Bowen, 1971)
In this study, the authors examined the role of task stressfulness. Female hooded rats were tested during proestrus or estrus on the hidden-platform water maze in warm (33oC) or cold (19oC) water. There were no effects of cycle or temperature, but estrous phase interacted with temperature such that proestrous rats performed better overall under the warm condition and estrous rats performed better under the cold condition. (Rubinow, 2004)
Razmjou, S. & Kjellberg, A. (1992). Sustained attention and serial responding in heat:Mental effort in the control of performance [Electronic version]. Aviation, Space,& Environmental Medicine, 63, 594-601.The researchers based their study on previous studies which had found that heat (above 40 degrees Celsius was detrimental to sustained concentration. In their study, 20 participants were subjected to temperatures above 40 degrees Celsius. The participants were tested on body temperature, heart rate and reaction time. They found reaction times were negatively affected and a correlation in increased body temperature with increased heart rate. This supports our hypothesis that increased temperature may be responsible
[Abstract: ________________________________________] The effect of a heated body environment on response power and cardiovascular risk parameters is unknown. This effect was not shown in any previous studies. This is why we propose to do research to shed light on the underlying mechanisms of our changes, and investigate ways of reducing heat through different mechanisms.
[In order to understand the possible mechanisms of our changes, we decided that we use data from a study that looked at different subjects that was being assessed by physical and physiological laboratory members for an additional 12 months in order to compare differences in response power, cardiovascular and metabolic variables by body and other body systems. These subjects were then divided into 5 groups and assigned to 2 groups (n = 4 groups). We then used the data to calculate a model and compare the energy needs of the 6 individual variables. We looked at our data for: (1) cardiovascular rate, (2) heart rate, and, (3) total energy expenditure while the heat was above 40 C. Our analysis, if there is any significance, must include a control of these variables. (4) response power and (5) metabolic variables. Because those individual variables are not the key variables, we will not include them in our calculations. (5) total energy expended during each 15 minute heat session (5 minutes) or 30 minutes cold session (5 minutes) (n = 4) with no treatment.
The study looked at the effect of body temperature and heat intensity on the response parameters of participants. (See Figure 1A, Figure 2A). A. ________________________________________(s) ________________________________________, S. A. (1992). The effect of body temperature on cardiovascular risk and body mass index in adults. Health Risk Assessment. 2.01, 3.03, 3.04, 3.05, 3.06, 4.07; Kjellberg, A. K. & Eisener, S. [Abstract: ________________________________________] Changes in heart rate, body-mass index, lipid profile and mortality. Heart & Heart Research. 20:3.07, 38.07 (1997); DOI: 10.1132/heart.20.3.07
[In general, if a hot body is maintained in a hot place for several days, the effects of heat change on responses or metabolic variables are not apparent.]
We estimated the energy needs of each individual at the two highest and highest temperatures at each time part of a cold session. To ensure that these were correct, we calculated time for the baseline time of each individual so that we did not overfit the temperature. Thus, the difference in heat levels between the two temperature conditions resulted in a similar figure. (Figure 1B), ________________________________________ or ________________________________________ did not differ. Furthermore, to calculate our energy needs, we used a similar calculation of the
[Abstract: ________________________________________] The effect of a heated body environment on response power and cardiovascular risk parameters is unknown. This effect was not shown in any previous studies. This is why we propose to do research to shed light on the underlying mechanisms of our changes, and investigate ways of reducing heat through different mechanisms.
[In order to understand the possible mechanisms of our changes, we decided that we use data from a study that looked at different subjects that was being assessed by physical and physiological laboratory members for an additional 12 months in order to compare differences in response power, cardiovascular and metabolic variables by body and other body systems. These subjects were then divided into 5 groups and assigned to 2 groups (n = 4 groups). We then used the data to calculate a model and compare the energy needs of the 6 individual variables. We looked at our data for: (1) cardiovascular rate, (2) heart rate, and, (3) total energy expenditure while the heat was above 40 C. Our analysis, if there is any significance, must include a control of these variables. (4) response power and (5) metabolic variables. Because those individual variables are not the key variables, we will not include them in our calculations. (5) total energy expended during each 15 minute heat session (5 minutes) or 30 minutes cold session (5 minutes) (n = 4) with no treatment.
The study looked at the effect of body temperature and heat intensity on the response parameters of participants. (See Figure 1A, Figure 2A). A. ________________________________________(s) ________________________________________, S. A. (1992). The effect of body temperature on cardiovascular risk and body mass index in adults. Health Risk Assessment. 2.01, 3.03, 3.04, 3.05, 3.06, 4.07; Kjellberg, A. K. & Eisener, S. [Abstract: ________________________________________] Changes in heart rate, body-mass index, lipid profile and mortality. Heart & Heart Research. 20:3.07, 38.07 (1997); DOI: 10.1132/heart.20.3.07
[In general, if a hot body is maintained in a hot place for several days, the effects of heat change on responses or metabolic variables are not apparent.]
We estimated the energy needs of each individual at the two highest and highest temperatures at each time part of a cold session. To ensure that these were correct, we calculated time for the baseline time of each individual so that we did not overfit the temperature. Thus, the difference in heat levels between the two temperature conditions resulted in a similar figure. (Figure 1B), ________________________________________ or ________________________________________ did not differ. Furthermore, to calculate our energy needs, we used a similar calculation of the