The TRPV1 receptor is involved in the modulation of cardiovascular, respiratory, and temperature control systems at the level of the ventrolateral medulla 2728. Microinjection of capsaicin (0.5–50 nmol) into the ventrolateral medulla at the level of the hypoglossal nerve roots was found to increase respiratory output, arterial pressure, and heart rate in an anesthetized rat preparation 27. Infusion of capsaicin into more caudal regions reduced arterial pressure and heart rate in both anesthetized and chronic rat preparations 27.

Acute systemic administration of capsaicin results in an initial hypothermia, followed by hyperthermia 282930. The hypothermia is a result of enhancement of autonomic heat loss mechanisms (e.g. peripheral vasodilation) and a depression of heat saving mechanisms (e.g. shivering) 31. The latent hyperthermia is likely a result of sympathoadrenal activation 2932. Osaka et al. 28 found that lesions of the rostral ventrolateral medulla, a region containing sympathoadrenal preganglionic neurons, largely attenuated capsaicin-induced hyperthermia in anesthetized rats. Consistently, microinjection of capsaicin (500 μmol) into the rostral ventrolateral medulla was found to elicit hyperthermia 28. The results suggest that capsaicin activates the rostral ventrolateral medulla which then increases sympathoadrenal activation leading to heat production. It will be of interest to determine whether the actions of capsaicin in this region are specific to the TRPV1 receptor.

The periaqueductal grey is a well established component of the pain modulatory circuitry and projects to the rostral ventromedial medulla 2533. The rostral ventromedial medulla can subsequently exert descending modulation over nociceptive spinal reflex pathways 3334353637. Palazzo et al. 38 demonstrated that capsaicin injection (1–6 nmol) at the periaqueductal grey can increase the latency of nociceptive responses, indicating analgesia. This effect could be blocked by local antagonism of NMDA and metabotropic glutamate receptors. In contrast, McGaraughty et al. 39 found that capsaicin (10 nmol) injected into the dorsal periaqueductal grey could decrease the latency of both nociceptive behavioral responses and rostral ventromedial medulla tail-flick-on cell activity, suggesting hyperalgesia. To account for this discrepancy, McGaraughty et al. 39 suggested that the fast delivery of capsaicin by Palazzo et al. 38 may have desensitized the TRPV1 receptors resulting in analgesia.

A recent investigation by Maione et al. 40 demonstrated that elevation of endocannabinoid levels, with an inhibitor of fatty acid amide hydrolase, in the ventrolateral periaqueductal grey can produce analgesia and hyperalgesia. This effect was shown to be dependent on the activation of TRPV1 and CB1 (cannabinoid receptor-1) receptors. Low doses of inhibitor at the periaqueductal grey produced rapid hyperalgesia. The hyperalgesia was proposed to result from an increase in 2-arachidonoylglycerol, which stimulates CB1 receptors preferentially over TRPV1 receptors 40. This leads to descending inhibition of off-cells and stimulates on-cells in the rostral ventromedial medulla, speeding up nociceptive responses 40. Higher doses of fatty acid amide inhibitor cause rapid analgesia followed by a delayed hyperalgesia 40. The findings were explained by suggesting that anandamide levels increase and stimulate TRPV1 receptors resulting in analgesia. Subsequently, 2-arachidonoylglycerol levels increase to stimulate CB1 receptors resulting in hyperalgesia. Again, the effects of the inhibitor at the periaqueductal grey would be mediated through descending modulation of the appropriate rostral ventromedial medulla circuitry 40. Consistent with the concept that these two receptors modulate descending facilitatory and inhibitory output to the rostral ventromedial medulla, Maione et al. 40 found that some neurons of the periaqueductal grey co-expressed TRPV1 and CB1 receptors.

Activation of TRPV1 receptors in the NTS has been found to induce hypotension, bradycardia 41, and reduction of respiratory rate 42. In-vitro brainstem slice experiments demonstrated that acute capsaicin (100 nM) treatment induces a rapidly developing inward current in NTS neurons. Capsaicin treatment also enhanced spontaneous glutamatergic currents 43. The effects of the capsaicin treatment were restricted to a subpopulation of NTS neurons 43. Additional evidence suggested that the capsaicin was acting on presynaptic TRPV1 receptors to enhance glutamate release onto AMPA receptors 43. In addition, capsaicin sensitive neurons of the NTS, but not insensitive neurons, can be characterized by large transient outward currents 44. The results suggest that within a particular brain region, activation of TRPV1 receptors may selectively affect neurons characterized by distinct electrophysiological properties.

Peripheral administration of capsaicin results in bursting activity in the dorsal raphé nucleus, recorded with intracortical electroencephalogram in rats 45. In addition, direct injection of capsaicin (65 nmol) into the dorsal raphé nucleus increases vasodilation of the skin and decreases core body temperature in anesthetized rats 46.

The locus coeruleus is activated by painful stimuli and is involved in the production of antinociception 3347. Intravenous administration of capsaicin increases firing rates of locus coeruleus neurons in anesthetized rats 48. This increased firing even occurred following neonatal capsaicin treatment to destroy sensory nerve fibers, indicating a central effect of capsaicin 48. Consistent with this excitatory effect, TRPV1 activation at the locus coeruleus with capsaicin (1 μM) was found to enhance glutamatergic miniature excitatory postsynaptic currents through a presynaptic mechanism 49.

Injection of capsaicin (2–80 nmol) into the preoptic area of the hypothalamus causes an abrupt hypothermic response 50, and increases the activity of warm-sensitive neurons while depressing the activity of cold-sensitive neurons 30. In addition, capsaicin (~4 μM) can evoke glutamate release in rat hypothalamic slice preparations 1322 and enhance postsynaptic currents 51 (Fig. 2).

Nociceptive (pinch sensitive) neurons in the medial thalamus can be activated by arterial capsaicin infusion 525354, an effect that can be blocked by morphine 54. Interestingly, TRPV1 gene knockout mice are not impaired in the detection of noxious mechanical stimuli as determined by tail pinch, von-Frey test, and spinal nociceptive neuron responses 12. However, this does not rule out the possibility that thalamic TRPV1 receptors modulate noxious mechanical information once it has been detected.

Application of capsaicin (1–10 μM) to the ventral tegmental area increases the firing rate and bursting activity of dopaminergic neurons in-vitro 55 (Fig. 3). In addition, it was shown that activation of TRPV1 receptors of the ventral tegmental area could enhance dopaminergic output to the nucleus accumbens, following peripheral noxious stimulation 55.

Peripheral administration of capsaicin results in bursting activity in the substantia nigra, recorded with intracortical electroencephalogram in rats 45. Injection of capsaicin into the substantia nigra can enhance locomotor behaviors (100 nmol capsaicin) and produce peripheral vasodilation (30–100 nmol capsaicin) 5657. In-vitro studies have demonstrated that TRPV1 activation (1–10 μM capsaicin) enhances glutamatergic synaptic transmission to dopaminergic neurons of the substantia nigra 58. In addition, analysis of excitatory postsynaptic currents suggested a presynaptic mechanism for this enhancement 58. Importantly, this study demonstrated that TRPV1 is activated by endogenous ligands in-vitro, since antagonism of the receptor reduced the frequency of spontaneous excitatory postsynaptic currents.

In the hippocampal CA1 region, TRPV1 activation enhances paired-pulse depression 759. It is possible that the mechanism of the depression was the activation of presynaptic TRPV1 receptors at GABAergic terminals, which feed back and inhibit CA1 neurons 5960. This would be expected to have the net effect of increasing GABA output 60. However, TRPV1 receptor activation was found to inhibit the influx of calcium and reduce GABA release in synaptosomal hippocampus preparations 60. This discrepancy between in-vitro and ex-vivo data may be a consequence of the disruption of intracellular or extracellular molecules under ex-vivo conditions. These molecules may modulate TRPV1 receptor function. Alternatively, the discrepancy may be due to rapid desensitization of TRPV1 receptors under ex-vivo conditions 60.

Microiontophoretically applied capsaicin into the cerebellum depresses neuron spike activity 61. This finding is interesting because it differs from the excitatory effect of capsaicin in other regions of the brain. In contrast with the hypothalamus and cerebral cortex (below), activation of the TRPV1 receptor does not evoke glutamate release in cerebellum tissue slices 13.

The somatosensory cortex and ACC are both involved in the processing of pain 24253362. However, few studies have examined the effect of direct TRPV1 receptor activation in these regions. It has been shown that activation of the TRPV1 receptor can evoke glutamate release from cortical slices 13. In addition, a study by Toldi et al. 63 showed that local application of capsaicin to the somatosensory cortex reduced mechanically and electrically evoked potentials of anesthetized rats 63.

Preliminary in-vitro data from our laboratory show that capsaicin application (50 μM) to the ACC increases the firing frequency of some neurons (Fig. 4), while depressing firing of other neurons. The differing direction of neuron firing patterns is similar to the effects observed in the hypothalamic preoptic area 30. Since the ACC is involved in the formation of pain-associated memory and the descending modulation of nociception 6465, it will be of interest to determine whether or not the TRPV1 receptor can influence these processes.