Roger A. L. Dampney

A method for evoking physiological responses by stimulation of cell bodies, but not axons of passage, within localized regions of the central nervous system

A method for evoking physiological responses by microinjection of sodium glutamate solution into localized regions of the central nervous system (CNS) is described. The major advantage of this method is that the cell bodies or dendritic processes of neurones within the injection site are excited, whereas axons of passage are unaffected. It was demonstrated that injections of minute volumes (50-100 nl) of 0.5 M glutamate solution into selected sites within the medulla or midbrain of anaesthetized or conscious animals, respectively, elicited marked autonomic, somatomotor or behavioural responses, depending on the injection site. In contrast, glutamate microinjection into fibre tracts failed to elicit any response, whereas electrical stimulation applied at the same sites elicited marked responses. The degree of localization of the glutamate stimulus and the relation between glutamate concentration and magnitude of evoked response are described. It is concluded that this method is a very effective means of selectively stimulating cell bodies within highly localized regions of the CNS. Further, by using this method in combination with focal electrical stimulation, it is possible in some cases to provide evidence that a response arises from excitation of axons of passage rather than cell bodies.

Role of ventrolateral medulla in vasomotor regulation: a correlative anatomical and physiological study

Two groups of experiments were carried out in rabbits. First, the ventrolateral reticular formation of the medulla oblongata was stimulated either by microinjection of sodium glutamate solution (exciting only cell bodies) or electrically (exciting cell bodies and axons). This region has been shown previously to contain a dense and compact group of bulbospinal cells. The effects of both electrical and chemical stimulation of specific sites were correlated with the density of ventrolateral bulbospinal cells at the same sites. Glutamate microinjection into the center of the group of bulbospinal cells elicited a very large and sustained increase in arterial pressure, whereas microinjection into sites outside this region elicited a very small or no response. These results suggest that it is the bulbospinal ventrolateral cells which mediate the pressor response to glutamate stimulation. Focal electrical stimulation in the ventrolateral medulla elicited increases in arterial pressure and decreases in femoral and renal vascular conductance, as well as a short-latency increase in renal sympathetic nerve activity. The most effective sites for focal electrical stimulation lay within the region of greatest density of bulbospinal cells; slightly less effective sites lay just rostral and caudal to this region. It is suggested that stimulation in these latter sites predominantly excites axons of passage. Secondly, the origin of afferent fibers to the ventrolateral vasomotor area was studied using the horseradish peroxidase (HRP) method. This revealed major projections from the medial part of the nucleus tractus solitarius and the parabrachial nucleus in the pons. The physiological and anatomical studies taken together are consistent with the hypothesis that the bulbospinal ventrolateral cells are vasomotor in function, and receive afferent inputs from brain stem nuclei which are known to play a role in autonomic regulation.

Central mechanisms underlying short- and long-term regulation of the cardiovascular system.

1. Sympathetic vasomotor nerves play a major role in determining the level of arterial blood pressure and the distribution of cardiac output. The present review will discuss briefly the central regulatory mechanisms that control the sympathetic outflow to the cardiovascular system in the short and long term.

Cell groups in the lower brain stem of the rabbit projecting to the spinal cord, with special reference to catecholamine-containing neurons

Two groups of experiments were carried out in rabbits. In the first groups, the distribution of cell bodies within the pons and medulla projecting ipsilaterally and contralaterally to the thoracic or lumbar spinal cord was studied using the horseradish peroxidase (HRP)/tetramethylbenzidine (TMB) procedure. In the second group, both a previously described double-labeling technique and a new modification of it were used to determine the location of catecholamine (CA)-fluorescent pontomedullary cells projecting to the spinal cord. The results demonstrate that the catecholamine (probably norepinephrine)-containing neurons which innervate the thoracic spinal cord are confirmed almost exclusively to the pons where they were found within the A5, A7 and subcoeruleus groups, as well as the ventral portion of the principal part of the locus coeruleus and the more caudal locus coeruleus, including the A4 cell group. Within the medulla oblongata no doubly labeled A2 cells were observed and the few double labeled A1 cells which were observed were confined to the rostral portion of this group. A dense group of HRP-positive but non-fluorescent cells was found rostral to the A1 area in the ventrolateral reticular formation. These cells, which correspond in position to PNMT-containing cells in the rat, appear to project to both thoracic and lumbar segments of the spinal cord. In contrast, spinally projecting neurons within the nucleus tractus solitarius originated from different subnuclei according to their segmental destination. New information about the organization of medial reticulospinal and vestibulospinal pathways was also obtained.

AT1 Receptors Mediate Excitatory Inputs to Rostral Ventrolateral Medulla Pressor Neurons From Hypothalamus

Angiotensin II type 1 (AT(1)) receptors are located on pressor neurons in the rostral ventrolateral medulla, and their activation results in an increase in arterial pressure. However, the normal role of these AT(1) receptors in cardiovascular regulation is unknown. In this study, we tested the hypothesis that these receptors mediate synaptic excitation of rostral ventrolateral medullary pressor neurons in response to activation of the hypothalamic paraventricular nucleus. In anesthetized rats, microinjections of the gamma-aminobutyric acid receptor antagonist bicuculline were made into the paraventricular nucleus; this injection causes activation of the nucleus as a consequence of disinhibition. The pressor and sympathoexcitatory responses evoked by paraventricular nucleus activation were significantly reduced (by approximately 40% to 50%) after microinjection of the specific AT(1) receptor antagonists losartan or L-158,809 into the rostral ventrolateral medulla on the ipsilateral, but not contralateral, side. These responses were reduced to a similar degree after microinjections of the neuroinhibitory compound muscimol into the ipsilateral, but not contralateral, rostral ventrolateral medulla. However, bilateral microinjections of the glutamate receptor antagonist kynurenic acid into the rostral ventrolateral medulla had no effect on the responses evoked from the paraventricular nucleus. Conversely, bilateral microinjections of kynurenic acid into the rostral ventrolateral medulla virtually abolished the somatosympathoexcitatory reflex, whereas bilateral microinjections of losartan or L-158,809 had no effect on this reflex. The results indicate that excitatory synaptic inputs to pressor neurons in the rostral ventrolateral medulla arising from activation of the paraventricular nucleus are mediated predominantly by AT(1) receptors.

LONG-TERM REGULATION OF ARTERIAL BLOOD PRESSURE BY HYPOTHALAMIC NUCLEI: SOME CRITICAL QUESTIONS

1. The long‐term level of arterial pressure is dependent on the relationship between arterial pressure and the urinary output of salt and water, which, in turn, is affected by a number of factors, including renal sympathetic nerve activity (RSNA). In the present brief review, we consider the mechanisms within the brain that can influence RSNA, focusing particularly on hypothalamic mechanisms.

Tonic cardiovascular effects of angiotensin II in the ventrolateral medulla.

The rostral and caudal parts of the ventrolateral medulla play a major role in the control of blood pressure. Both regions contain a high density of receptor binding sites for angiotensin II, and it has been shown previously that microinjection of angiotensin II into the rostral ventrolateral medulla causes a rise in blood pressure. The aims of this study were to determine the cardiovascular effects of microinjection of angiotensin II and its specific antagonist [Sar1Thr8]angiotensin II into the caudal ventrolateral medulla and to characterize the regional vascular effects elicited by both compounds in the rostral ventrolateral medulla. Microinjections of angiotensin II (0.2-20 pmol) into histologically verified sites in the caudal ventrolateral medulla of anesthetized baroreceptor-denervated rabbits produced dose-dependent decreases in blood pressure and renal sympathetic nerve activity, whereas microinjection of [Sar1Thr8]angiotensin II (40 pmol) produced increases in these variables. In the rostral ventrolateral medulla, angiotensin II (0.02-20 pmol) elicited a dose-dependent increase in blood pressure, iliac vascular resistance, and renal sympathetic nerve activity, whereas [Sar1Thr8]angiotensin II (40 pmol) produced decreases in these variables. The effects on heart rate elicited by either compound in the rostral or caudal ventrolateral medulla were small but were in the same direction as the other cardiovascular variables. In contrast, angiotensin II had no detectable effect on sympathoexcitatory neurons within the rostral dorsomedial medulla, a region that lacks angiotensin II receptor binding sites. The results indicate that endogenous angiotensin II acts on specific receptors within the rostral and caudal parts of the ventrolateral medulla and has a tonic excitatory action on sympathoexcitatory and sympathoinhibitory neurons within these respective regions.

Excitation of neurones in a restricted portion of the midbrain periaqueductal grey elicits both behavioural and cardiovascular components of the defence reaction in the unanaesthetised decerebrate cat

Microinjections of the excitant amino acid D,L-homocysteic acid (DLH) into a restricted part of the midbrain periaqueductal grey (PAG) of unanaesthetized decerebrate cats evoked a distinctive pattern of facio-vocal and cardiovascular changes characteristic of a defence reaction, including pupillary dilatation, howling vocalization, an increase in arterial pressure and heart rate, and skeletal muscle vasoconstriction. These facio-vocal and cardiovascular responses always occurred together, and thus may arise from excitation of a common population of neurones. DLH injections within a greater extent of the PAG elicited other facio-vocal changes characteristic of defence, such as hissing or growling, but these were not accompanied by significant cardiovascular changes.

Functional organization of brain pathways subserving the baroreceptor reflex: studies in conscious animals using immediate early gene expression.

Abstract1. This paper reviews studies carried out in our laboratory in which we have used the c-fos functional mapping method, in combination with other methods, to determine the functional organization of central baroreceptor pathways as they operate in the conscious rabbit.2. First, we showed that periods of induced hypertension or hypotension each result in a specific and reproducible pattern of activation of neurons in the brainstem and forebrain. In particular, hypotension (but not hypertension) results in the activation of catecholamine neurons in the medulla and pons and vasopressin-synthesizing neurons in the hypothalamus.3. The activation of medullary cell groups in response to induced hypertension or hypotension in the conscious rabbit is almost entirely dependent on inputs from arterial baroreceptors, while the activation of hypothalamic vasopressin-synthesising neurons in response to hypotension is largely dependent on baroreceptors, although an increase in circulating angiotensin also appears to contribute.4. Discrete groups of neurons in the rostral ventrolateral medulla (RVLM) and A5 area in the pons are the major groups of spinally projecting neurons activated by baroreceptor unloading. In contrast, spinally projecting neurons in the paraventricular nucleus in the hypothalamus appear to be largely unaffected by baroreceptor signals.5. Direct afferent inputs to RVLM neurons in response to increases or decreases in arterial pressure originate primarily from other medullary nuclei, particularly neurons located in the caudal and intermediate levels of the ventrolateral medulla (CVLM and IVLM), as well as in the nucleus tractus solitarius (NTS).6. There is also a direct projection from barosensory neurons in the NTS to the CVLM/IVLM region, which is activated by baroreceptor inputs.7. Collectively, the results of our studies in conscious animals indicate that baroreceptor signals reach all levels of the brain. With regard to the baroreceptor reflex control of sympathetic activity, our studies are consistent with previous studies in anesthetized animals, but in addition reveal other previously unrecognized pathways that also contribute to this reflex regulation.

Viscerotopic control of regional vascular beds by discrete groups of neurons within the midbrain periaqueductal gray

It is well established that a group of bulbospinal neurons within the rostral ventrolateral medulla plays a crucial role in the tonic and phasic control of arterial pressure. In the cat, these neurons are confined to a discrete region which has been termed the subretrofacial (SRF) nucleus. Recent evidence suggests that this nucleus is viscerotopically organized with respect to its control over different vascular beds. These observations raise the question as to whether functionally different subgroups of SRF pressor neurons receive inputs from supramedullary cell groups that also exert a specific control over particular vascular beds. To answer this question retrogradely transported tracers (i.e. rhodamine or fluorescein-labelled microspheres, wheat germ agglutinin-horseradish peroxidase) were injected into physiologically identified sites within the rostral or caudal parts of the SRF nucleus of the cat. Separate groups of neurons in the midbrain periaqueductal gray region (PAG) were found to project specifically to subgroups of cells within the rostral and caudal parts of the SRF nucleus. These findings, together with the results of recent functional studies of the PAG suggest that these distinct projections from the PAG to the SRF nucleus are involved in the expression of different patterns of emotionally coupled cardiovascular responses.