Rapid temperature changes induce adenosine-mediated depression of synaptic transmission in hippocampal slices from rats (non-hibernators) but not in slices from golden hamsters (hibernators).

Disturbances in neuronal communication induced by rapid temperature changes are a risk in the context of accidental hypothermia and would be fatal for hibernators during arousal from hibernation. Therefore, we investigated the effects of rapid temperature changes on synaptically induced CA1 population spikes in hippocampal slices from golden hamsters (hibernators) and rats (non-hibernators). Temperature was changed ramp-like by 0.3 degrees C/min, which corresponds to the rise of body temperature in golden hamsters during arousal from hibernation. During cooling from 35 to 10-15 degrees C, the population spike amplitude increased, reached maximal values at 25-30 degrees C and 20-25 degrees C in hamster and rat slices, respectively, and then decreased with further cooling. During rewarming, hamster slices displayed the same temperature dependence as during cooling. In contrast, in rat slices dynamic effects of the temperature change occurred. These were most obvious in a strong depression of the spike amplitude during rewarming as compared to cooling. Above 26-29 degrees C, the depression was superimposed by an excitatory effect. The depression was largely attenuated by theophylline (100-200 microM) and thus seems to be based on an increase of the concentration of endogenous adenosine, which in turn may result from an imbalance in energy metabolism during warming. The lack of warming-related depression in hamster slices can be explained by a lower sensitivity for adenosine as compared to rat slices. In addition, a better resistance of metabolic balance against rapid temperature changes may prevent large elevations of endogenous adenosine in the hamster hippocampus. For hibernators, the avoidance of temperature change-induced disturbances of neuronal communication may be a prerequisite for safe arousal from hibernation.

Muscle coordination in hindlimbs of mice after bilateral nerve regeneration.

The common peroneal nerve was transected bilaterally in 25 adult mice. Nerve stumps were immediately readapted without nerve suture. Before transection and after nerve regeneration the muscle coordination of tibialis anterior (TA) and medial gastrocnemius (MG) muscle was examined by electromyographic recordings from both muscles (EMG) during free running. Using a personal computer, the degree of muscle coordination between TA and MG was determined by calculating a coordination index. In normal mice an antagonistic innervation pattern was observed. After nerve transection and regeneration the degree of muscle coordination of TA and MG substantially decreased with great interindividual but also great intraindividual variation. In 16 mice there was no correlation between the coordination index of the left and right hindlimbs. In nine out of 25 mice reinnervation was absent on one side. These results suggest that nerve regeneration by axonal sprouting to appropriate or foreign muscles occurs at random and that there are no intraindividual factors which might promote the finding of the proper target muscle.

Spectral analysis of tremorine and cold tremor electromyograms in animal species of different size.

In 14 mice (36.2 +/- 5.4 g), 17 rats (425 +/- 46.4 g), and 11 rabbits (3,200 +/- 340 g) a comparative electromyographic analysis of tremorine tremor and cold tremor was performed in gastrocnemius and tibialis anterior muscles using spectral analysis. The mean frequency of cold tremor decreased with increasing body weight (mice: 40.2 +/- 4.5 Hz; rats: 31.3 +/- 4.9 Hz; rabbits: 16.4 +/- 3.2 Hz). With tremorine tremor no such allometric correlation was found for tremor frequency and body weight (mice: 17.7 +/- 3.6 Hz; rats: 19.6 +/- 5.1 Hz; rabbits: 15.9 +/- 2.1 Hz). Cross spectral analysis revealed that during cold tremor the flexor muscle (tibialis anterior) and the extensor muscle (gastrocnemius) of rabbits are activated alternately. The mean phase shift between the activation of flexor and extensor muscle was -155.5 degrees. Stronger activation was observed in the flexor muscle. Tremorine tremor was characterized by synchronous activation of flexor and extensor muscles with a mean phase angle of 3.0 degrees and a predominance of the extensor muscle. The results suggest that the nervous mechanisms for the generation of tremorine tremor and cold tremor are different.

Localization and neurophysiological properties of motoneurones of the M. triceps surae of the rat after retrograde labelling with Evans blue.

Evans blue was injected into either the medial and lateral gastrocnemius or the soleus muscle of adult albino rats to mark retrogradely the corresponding motoneurones in the spinal cord. The labelled motoneurones were identified by the red fluorescence of their perikarya in the ventral horn of segments L4--L6. In addition, a monosynaptic reflex action potential was recorded only in the ventral roots L4--L6 after stimulation of the nerves to the medial and lateral gastrocnemius and the soleus muscle. Excitability and reflex latencies of labelled and unlabelled motoneurones of segment L4--L6 as well as the conduction velocities of their axons were measured. Apart from a small but statistically nonsignificant increase in excitability, no functional differences were found between labelled and control neurones. Thus, retrograde labelling of motoneurones with Evans blue prior to performing electrophysiological experiments has the advantage that the marked motoneurones can be identified under the fluorescence microscope without the need of additional staining or fixation.

Effect of temperature on postsynaptic potentials of cat spinal motoneurones.

The effect of spinal cord temperature on excitatory postsynaptic potentials (EPSP) and inhibitory postsynaptic potentials (IPSP) were measured by means of intracellular recordings from lumbar motoneurones of 43 cats. While body temperature and oil bath temperature were maintained between 37 and 38 degrees C, the temperature of the spinal segment under investigation was changed separately in the range between 30 and 42 degrees C. Cooling consistently produced an increase in amplitude and duration of both, mono- and poly-synaptic EPSPs and recurrent and direct IPSPs. Warming caused the opposite effect. The input resistance of the motoneurones was inversely related to the spinal cord temperature, while the latency of action potentials produced by intracellular injection of outward current was directly and exponentially related to spinal temperature. Although the data do not provide a quantitative differentiation of pre- versus postsynaptic temperature effects, they are consistent with the notion that temperature dependent changes on postsynaptic membrane properties contribute to the observed PSP changes. It is further suggested that similar postsynaptic temperature effects may be concerned in temperature sensitivity of proposed specific central neurones.