Balanced excitation and inhibition in temperature responses to meth

Fatal hyperthermia after administration of various amphetamines is well-known clinical phenomenon, however, there is no consistent theory explaining its etiology and/or pathogenesis. Dose-dependence of temperature responses to methamphetamine is intricate. Recently, using mathematical modeling it was suggested that delicate interplay of excitatory and inhibitory mechanisms underlies this complexity

Core Body Temperature Regulation and Locomotor Activity

poster abstractMethamphetamine (Meth) enhances locomotor activity, and is known to cause life-threatening hyperthermia. There has been much debate about whether the locomotion plays a major role in hyperthermia caused by Meth or other stimulants. The existing model of the neural circuitry putatively involved in this phenomenon [1] accurately reproduces the temperature response to the different doses of Meth. We compared locomotor activity observed in the same experiments with activation patterns of neuronal populations as predicted by the model. We found that time-courses of locomotor activity closely resembles the activity of one particular node in the model putatively representing the medullary level. However, the data on locomotion did not match the model in the initial phase of the response within 1 hour after the injection. Therefore, we hypothesized that there were some changes in thermogenesis and heat exchange mechanisms that largely control temperature response during the first hour and make the influence of locomotion relatively small. The objective of the study was to measure the temperature dynamics in rats running on a treadmill at different speeds and to construct a mathematical model explaining the mechanism of their core body temperature response to such an intervention that takes into account potential changes in heat exchange, sensory input and feedback control mechanisms. In the experiments for every speed of 0, 6, 12, and 18 m/min we had 4 rats running for 15 min. For each speed we averaged the temperature over 4 rats to get the average temperature response curve. First, we found that the temperature response curves for different treadmill speeds were not different statistically. Second, every response curve starts with a short but profound (~0.25 deg C in the first 5 min) drop in the body temperature followed by virtually linear rise of the temperature which significantly (by ~1 deg C) overshoots the baseline temperature. To explain these findings we set up a model in a form of a system of two differential equations that described the change in the body temperature and the change in the body heat production under the hypothesis that there are contributions of varying heat exchange, sensory input and feedback mechanisms in thermogenesis. All parameters in the system were subject to fitting experimental time series of temperature response of rats to 4 consistent speeds of 0, 6, 12, and 18 m/min on treadmills. We found, that a sudden drop of the body temperature below the baseline in the first five minutes after rats were removed from their cages and placed on a treadmill was a result of the increased heat dissipation caused by changes in the body position and movement of rats. The following fast recovery of the body temperatures to the normal level was provided by the feedback mechanisms activated by the temperature drop and changed sensory input. Meth continues to stimulate thermogenesis even after the baseline temperature is achieved from feedback mechanisms. Estimated contribution of the locomotion was negligible as compared to the latter and hence played a relatively small role in the temperature change. We predict that varying locomotion might manifest itself in temperature dynamics after much longer (~1 hour) exposure to running. The suggested system, which considers major factors defining body temperature response, can help to uncover the mechanisms of hyperthermia elicited by Meth, but also can be used to understand the thermoregulatory mechanisms which underlie the responses to simultaneous changes in environmental and physical conditions

Modeling the effects of extracellular potassium on bursting properties in pre-Bötzinger complex neurons

There are many types of neurons that intrinsically generate rhythmic bursting activity, even when isolated, and these neurons underlie several specific motor behaviors. Rhythmic neurons that drive the inspiratory phase of respiration are located in the medullary pre-Bötzinger Complex (pre-BötC). However, it is not known if their rhythmic bursting is the result of intrinsic mechanisms or synaptic interactions. In many cases, for bursting to occur, the excitability of these neurons needs to be elevated. This excitation is provided in vitro (e.g. in slices), by increasing extracellular potassium concentration (K[subscript out]) well beyond physiologic levels. Elevated K[subscript out] shifts the reversal potentials for all potassium currents including the potassium component of leakage to higher values. However, how an increase in K[subscript out], and the resultant changes in potassium currents, induce bursting activity, have yet to be established. Moreover, it is not known if the endogenous bursting induced in vitro is representative of neural behavior in vivo. Our modeling study examines the interplay between K[subscript out], excitability, and selected currents, as they relate to endogenous rhythmic bursting. Starting with a Hodgkin-Huxley formalization of a pre-BötC neuron, a potassium ion component was incorporated into the leakage current, and model behaviors were investigated at varying concentrations of K[subscript out]. Our simulations show that endogenous bursting activity, evoked in vitro by elevation of K[subscript out], is the result of a specific relationship between the leakage and voltage-dependent, delayed rectifier potassium currents, which may not be observed at physiological levels of extracellular potassium.National Institutes of Health (U.S.) (National Center for Complementary and Integrative Health (U.S). Grant R01 AT008632)National Institutes of Health (U.S.) (National Institute of Neurological Disorders and Stroke (U.S.). Grant R01 NS069220

Effect of Low Dose of Amphetamine on Thermoregulation System and Performance of Rats Running on Treadmills

poster abstractAmphetamine has been used widely as a performance-enhancing drug among athletes. There are numerous reports showing that low dose of amphetamine increases one’s performance by suppressing sensations of fatigues. However, a little has been known about the mechanism by which such an effect of amphetamine is caused. The goal of this study was to investigate how a low dose of amphetamine changed the duration and the capacity of running in rats by studying thermoregulation system of rats running on treadmills with experimental results and a mathematical model. 12 rats were separated into two groups of 6 and rats in the experimental group were injected with 2mg/kg of amphetamine and ones in the control group were injected with saline. Then each rat in both groups ran on a treadmill at the room temperature (25°) while the speed and the incline of the treadmill were increased stepwise in every 3 minutes. The running time of individual rats were determined by their ability of keeping up with the intensity of running and the core body temperatures and the oxygen consumptions ()of rats were recorded during the experiments. Then a mathematical model was constructed to describe rates of temperature changes in the core and muscles by quantifying the heat dissipations and heat productions using . Modeling revealed that amphetamine increases the heat dissipation in the core body, which slowed down the core temperature increase. Therefore rats injected with amphetamine were kept their core temperatures below approximately 40 °C for longer time, at which both groups were unable to run anymore. Additionally, the fact that the core temperature at the end of run was not significantly different between two groups, while muscle temperature was significantly different, suggests that the indicator of running capacity was the core temperature, rather than the muscle temperature. Finally, the level of overheating in muscles for the amphetamine group was severe enough to cause damages in muscles

Circadian variability of body temperature responses to Methamphetamine (Meth)

poster abstractVital parameters of living organisms exhibit circadian rhythmicity. Despite rats are nocturnal animals, most of drugs of abuse studies in rodents are performed during the day. Virtually no data on circadian variability of responses to amphetamines is currently available. However, the amplitude of circadian variations of body temperature is comparable to the magnitude of temperature responses to Meth. Accordingly, one can expect that the responses may be qualitatively different during the day and at night. Experiments were performed on male Sprague-Dawley rats implanted with telemetric probes reporting body temperature. Rats received i.p. injections of Meth (1 or 5 mg/kg) or saline at 10-11am or at 10-11pm. Each rat received only one injection of Meth to avoid the effects of repeated administration. The responses were recorded for at least 5 h. The baseline body temperature at night was 0.8ºC higher than during the day. The body temperature increased after injections of saline during both day and night but returned to its baseline within 1 h. This response was developing faster, and more pronounced at night. The temperature responses to Meth were different during the day and at night. In both cases the lower dose of Meth (1 mg/kg) induced monophasic hyperthermia. However, the maximal deviation of the temperature from baseline was appr. twice smaller at night than during the day. Injection of the higher dose of Meth (5 mg/kg) at day time caused a delayed hyperthermic response, preceded by a slight increase of the body temperature immediately after injection. In contrast, at night the same dose produced immediate hypothermia, which was not observed during the day. Recently, we created a model which showed that the complex dose-dependence of day-time temperature responses to Meth results from the delicate balance between inhibitory and excitatory drives which have different sensitivity to the drug. To interpret the night time data, we extended this mathematical model by assuming that the excitatory and/or inhibitory components and general metabolism are affected by the circadian input. Our model revealed that during the night the baseline activity of the excitatory node is greater than during the day. Besides, after injection of either dose of Meth the equilibrium body temperature appears significantly lower than the temperature observed before injection. The suppression of the response to the lower dose of Meth is, therefore, explained by a combination of two factors. First, the excitatory drive, which is predominantly responsible for monophasic hyperthermia after low doses of Meth, gets partially saturated. Second, the reduced general metabolism, which underlies the lower equilibrium temperature, leads to gradual cooling thus limiting the hyperthermia. Same mechanisms mediate the observed hypothermia during the night after the higher dose of Meth, as the inhibitory drive starts dominating the excitatory one. The reduction of the equilibrium temperature after Meth injection during the active time period represents a major perturbation of the thermoregulatory system status, and may reflect a Meth-triggered disturbance of circadian rhythmicity

Tissue oxidative metabolism can increase the difference between local temperature and arterial blood temperature by up to 1.3oC: Implications for brain, brown adipose tissue, and muscle physiology

Tissue temperature increases, when oxidative metabolism is boosted. The source of nutrients and oxygen for this metabolism is the blood. The blood also cools down the tissue, and this is the only cooling mechanism, when direct dissipation of heat from the tissue to the environment is insignificant, e.g., in the brain. While this concept is relatively simple, it has not been described quantitatively. The purpose of the present work was to answer two questions: 1) to what extent can oxidative metabolism make the organ tissue warmer than the body core, and, 2) how quickly are changes in the local metabolism reflected in the temperature of the tissue? Our theoretical analysis demonstrates that, at equilibrium, given that heat exchange with the organ is provided by the blood, the temperature difference between the organ tissue and the arterial blood is proportional to the arteriovenous difference in oxygen content, does not depend on the blood flow, and cannot exceed 1.3oC. Unlike the equilibrium temperature difference, the rate of change of the local temperature, with respect to time, does depend on the blood flow. In organs with high perfusion rates, such as the brain and muscles, temperature changes occur on a time scale of a few minutes. In organs with low perfusion rates, such changes may have characteristic time constants of tens or hundreds of minutes. Our analysis explains, why arterial blood temperature is the main determinant of the temperature of tissues with limited heat exchange, such as the brain

Mechanisms of Left-Right Coordination in Mammalian Locomotor Pattern Generation Circuits: A Mathematical Modeling View

The locomotor gait in limbed animals is defined by the left-right leg coordination and locomotor speed. Coordination between left and right neural activities in the spinal cord controlling left and right legs is provided by commissural interneurons (CINs). Several CIN types have been genetically identified, including the excitatory V3 and excitatory and inhibitory V0 types. Recent studies demonstrated that genetic elimination of all V0 CINs caused switching from a normal left-right alternating activity to a left-right synchronized “hopping” pattern. Furthermore, ablation of only the inhibitory V0 CINs (V0D subtype) resulted in a lack of left-right alternation at low locomotor frequencies and retaining this alternation at high frequencies, whereas selective ablation of the excitatory V0 neurons (V0V subtype) maintained the left–right alternation at low frequencies and switched to a hopping pattern at high frequencies. To analyze these findings, we developed a simplified mathematical model of neural circuits consisting of four pacemaker neurons representing left and right, flexor and extensor rhythm-generating centers interacting via commissural pathways representing V3, V0D, and V0V CINs. The locomotor frequency was controlled by a parameter defining the excitation of neurons and commissural pathways mimicking the effects of N-methyl-D-aspartate on locomotor frequency in isolated rodent spinal cord preparations. The model demonstrated a typical left-right alternating pattern under control conditions, switching to a hopping activity at any frequency after removing both V0 connections, a synchronized pattern at low frequencies with alternation at high frequencies after removing only V0D connections, and an alternating pattern at low frequencies with hopping at high frequencies after removing only V0V connections. We used bifurcation theory and fast-slow decomposition methods to analyze network behavior in the above regimes and transitions between them. The model reproduced, and suggested explanation for, a series of experimental phenomena and generated predictions available for experimental testing

Amphetamine enhances endurance by increasing heat dissipation

Athletes use amphetamines to improve their performance through largely unknown mechanisms. Considering that body temperature is one of the major determinants of exhaustion during exercise, we investigated the influence of amphetamine on the thermoregulation. To explore this, we measured core body temperature and oxygen consumption of control and amphetamine‐trea ted rats running on a treadmill with an incrementally increasing load (both speed and incline). Experimental results showed that rats treated with amphetamine (2 mg/kg) were able to run significantly longer than control rats. Due to a progressively increasing workload, which was matched by oxygen consumption, the control group exhibited a steady increase in the body temperature. The administration of amphetamine slowed down the temperature rise (thus decreasing core body temperature) in the beginning of the run without affecting oxygen consumption. In contrast, a lower dose of amphetamine (1 mg/kg) had no effect on measured parameters. Using a mathematical model describing temperature dynamics in two compartments (the core and the muscles), we were able to infer what physiological parameters were affected by amphetamine. Modeling revealed that amphetamine administration increases heat dissipation in the core. Furthermore, the model predicted that the muscle temperature at the end of the run in the amphetamine‐treated group was significantly higher than in the control group. Therefore, we conclude that amphetamine may mask or delay fatigue by slowing down exercise‐induced core body temperature growth by increasing heat dissipation. However, this affects the integrity of thermoregulatory system and may result in potentially dangerous overheating of the muscles