Introduction

The aetiology of many modern-day diseases, such as the metabolic syndrome, is often associated with alterations in the autonomic nervous system. The relatively sudden acceptance that autonomic imbalance is both causative and essential for the maintenance of disease states in animal models and humans, has led to an eruption of interventional approaches to manage these diseases. Modulation of the autonomic nervous system, whether via stimulation [1, 2] or ablation of organ-specific afferents and denervation of sympathetic post-ganglionic fibres targeting selected vascular beds [3•], is a strong current trend producing spectacular results. Here, we consider an intervention that is based on pre-clinical proof of principle data and previously published clinical results supporting carotid body modulation as a treatment for neurogenic hypertension.

The Problem of Hypertension is that Not Only Does It Not Go Away, It Gets Worse

Carey has recently proposed that 14 % of the world’s treated hypertensive patients are resistant to contemporary pharmacological therapy [4]. Even if this number is an overestimate, we are still left with a substantial clinical problem, given that there are presently almost 1 billion hypertensives worldwide [5]. Most hypertensive patients are well managed with anti-hypertensive drugs, yet there appears to be an increasing trend to greater resistance [4]. As Carey reports, resistant hypertensives have increased from 5.5 % in 1988–1994, to 8.5 % in 1999–2004 and 11.8 % in 2005–2008 [4]. A resistant hypertensive is a patient with office blood pressure >140/90 mmHg, despite taking ≥3 anti-hypertensive medications, ideally including a diuretic [6]. However, we believe the clinical problem of blood pressure management extends beyond drug resistance, and includes hypertensive patients that are drug intolerant due to adverse effects impacting on quality of life, often a consequence of high drug dosing and multi-pill therapy. If accepted that the sympathetic nervous system is in part responsible in the etiology and maintenance of hypertension [79, 10•, 11, 12], then we need to find innovative ways to control it. Although highly effective, the early attempts at gross surgical [13, 14] and then pharmacological sympathectomy [15] are unsurprisingly poorly tolerated. Given that sympathetic nervous system function is controlled differentially the idea of targeted sympathectomy, such as to the kidney [3•, 17•] or splanchnic vascular bed [16], has had considerable success in lowering blood pressure clinically and in animal models. However, the majority of patients receiving renal denervation have remained on anti-hypertensive medication and hypertensive [3•, 17•]. Given the hypothetical aim of curing hypertension and reducing/removing anti-hypertensive medication, especially those with severe life quality impeding side effects, further exploration into novel interventional therapies is warranted. We will discuss the idea of removing a distinct sympatho-excitatory afferent drive as a novel treatment for neurogenic hypertension.

The Peripheral Chemoreceptor

The peripheral or arterial chemoreceptors located in the carotid body send signals via a branch of the carotid sinus nerve to the nucleus of the solitary tract located in the dorsomedial medulla [18]. The carotid body consists of supporting cells (or type II cells, analogous to astrocytes) and glomus cells (type I cells) that embryologically originate from neural crest cells. Glomus cells are morphologically distinct as large and spherical in shape and are highly sensitive to oxygen delivery, arterial oxygen and carbon dioxide levels, blood pH, reduced blood flow (e.g. hemorrhage), inorganic phosphate and sodium cyanide [19]; the latter being used as a convenient experimental tool to produce tissue hypoxia and profound stimulation [20]. The carotid body is profusely perfused with blood [21] and the arterioles are innervated by the sympathetic nervous system. This is an important point as excessive sympathetic activity could potentially trigger activation of the chemoreceptor (via hypoperfusion). Persistent sympathetic activity might also re-model carotid body arterioles causing alterations in perfusion that could directly affect sensitivity of the chemoreceptor. The carotid body cells produce a vast array of chemical transmitters (including dopamine, noradrenaline, substance P) that are released to trigger a receptor potential on nearby afferent endings, resulting in their depolarisation and action potential generation [22]. In some species, such as rabbit, cat and human, there are additional glomus tissue accumulations on the aorta and subclavian arteries [23]. Aortic chemoreceptors have a distinct reflex response [23] compared to those evoked from carotid chemoreceptors (see below), and for this reason our focus will be on the carotid body.

Carotid Body Reflex Response Patterns and the Intimate Association with Respiration

Stimulation of the carotid body chemoreceptors triggers hyperventilation, an important protective reflex mechanism ensuring blood gas homeostasis. The peripheral chemoreceptors may also contribute to dyspnoea [24] and arousal [25], which is likely due to their supra-bulbar projections [26].

The reflex cardiovascular response evoked from the carotid body is interesting, as it comprises a primary and secondary response [27, 28]. The pattern of response evoked is dependent on the degree to which respiration increases. Hyperventilation recruits into play an afferent signal originating from mechanoreceptors surrounding bronchioles that on inflation trigger the pulmonary stretch receptor (Hering-Breuer) reflex giving the secondary response. This secondary response consists of tachycardia and vasodilatation; the former is mediated by cardiac vagal withdrawal and increased cardiac sympathetic tone, and the latter via inhibition of sympathetic vasomotor tone. This competes with the primary response of profound bradycardia (vagally mediated) and sympathetically mediated vasoconstriction. The resultant response depends on the relative strength of the two afferent reflexes and the magnitude of the respiratory response, which is dependent on animal species. The primary response prevails in the following examples: a diving mammal; human face immersion into cold water; sleep apnea; sudden infant death syndrome; and in anesthetised and mechanically ventilated animals. The bradycardia is potent, abolished with atropine and most likely protective in function to reduce cardiac metabolism and preserve oxygen. Intriguingly, despite the potent bradycardia, the sympathetic nervous system targeting the heart is co-activated [29] along with the cardiac vagal system and may increase cardiac force of contraction.

The type of stimulus used to activate the peripheral chemoreceptors will also dictate the response pattern. Using systemic hypoxia, for example, will produce a direct hyperpolarising effect on the vascular smooth muscle causing blood pressure to fall. This will unload baroreceptors that may trigger a compensatory response, although it is acknowledged that their interaction with peripheral chemoreceptors is antagonistic [20, 30, 31]. Finally, the strength of the stimulus may also produce a graded response, perhaps overturning coincident reflexes originating from pulmonary receptors in spontaneously breathing animals. When the stimulus is intense, peripheral chemoreceptors can trigger an alerting response, including the classical behavioural and visceral adjustments associated with fight or flight [19, 25]. In the context of carotid chemoreceptors and hypertension, this is most relevant, as it has been hinted that continuous activation of the fight or flight response (so called defence response) could lead to systemic hypertension [32].

The Association Between Peripheral Chemoreceptor Sensitivity and Sympathetic Nerve Activity Excess

The peripheral chemoreceptor reflex sensitivity has been shown to be significantly enhanced in both patients with primary hypertension [3337, 38•, 39] and spontaneously hypertensive (SH) rat [40••]; this has included the ventilatory and sympathetic nerve activity response components. Incidentally, an increased hypoxic ventilatory response is characteristic of heart failure patients. This increased peripheral chemoreceptor sensitivity is a prognostic indicator for mortality in these patients [41].

Hypersensitivity of the carotid body occurs before hypertension is established in both SH rats [40••] and white coat hypertensive patients [36]. Repetitive exposure of conscious normotensive rats to hypoxia can induce mild hypertension [42]. This is dependent on stimulation of peripheral chemoreceptors, as the hypertension is abolished by a priori carotid body removal [42]. This model of chronic intermittent hypoxia has been used as a model for sleep apnea. The model is tenuous, because it exhibits hypocapnia (not hypercapnia) and increased ventilation (not apnea). However, the hypertension produced is caused by activation of the sympathetic nervous system in rats [43•]. This is consistent with the sympathetic activation associated with the hypertension seen during obstructive or central sleep apnea in human patients with or without heart failure [44, 45]. Repeated peripheral chemoreceptor activation in sleep apnea has also been proposed to contribute to derangements in metabolism and obesity [46••]. Further, there is evidence that patients with sleep apnea develop tonic peripheral chemoreceptor afferent discharge that functionally drives muscle sympathetic activity [47]. Repeated carotid body activation in rats and humans results in enhanced respiratory-sympathetic coupling and increased muscle vasoconstrictor activity, which may contribute to the development of hypertension [10•, 33, 34, 36, 43•, 45]. Recently, we found that adrenomedullin in the rostral ventrolateral medulla was key for producing the long-term potentiation of sympathetic nerve activity evoked with repetitive stimulation of the carotid body (Colombari DS, Colombari E, Murphy D & Paton JF—unpublished data). The mechanisms causing release of adrenomedullin are unknown, but intermittent hypoxia cannot be ruled out. It should also be recognised that rostral ventrolateral medullary neurons are themselves intrinsically excited by hypoxia, providing a ‘fail safe’ mechanism for driving sympathetic activity in conditions of prolonged apnea and severe hypoxia, for example [47].

The ‘Hypertensive’ Carotid Body

Morphological studies have revealed that carotid bodies are enlarged in hypertensive patients [48]. In the spontaneously hypertensive (SH) rat, the glomus cells are hypertrophied suggesting up regulation of protein synthesis and there is angiogenesis within the microvasculature relative to controls [49]. Above, we described that the peripheral chemoreceptor reflex is sensitised in patients with hypertension. The mechanism/s for this remain to be fully understood. However, in pre-hypertensive (juvenile) SH rats, type I cells display enhanced sensitivity to low pH, due to increased expression of two acid-sensing non-voltage gated channels, ASIC3 and TASK1 [40••]. There is also evidence that the balance between carbon monoxide and hydrogen sulphide signalling within the CB, as well as the relative activity of HIF1α versus HIF2α play a role [50]. Animal models of chronic heart failure have revealed that carotid body (CB) chemoreceptor activity is augmented by activation of angiotensin II receptors [51], impaired nitric oxide synthase activity [52], reduced CB blood flow [53•], enhanced adenosine monophosphate-activated protein kinase [54], and inflammation [55], but whether these changes are also seen in hypertensive carotid bodies remains to be elucidated. Heightened sympathetic drive to the arterioles of the CB may also contribute to its hyperactivity due to hypoperfusion (via vasoconstriction and vascular remodelling). Kato et al. described that there is significant dopamine β-hydroxylase (DBH) immunoreactivity in fibres around glomus cells [56•]. A possibility is that the larger morphology of the CB in the SH rat may be the effect of the sympathetic innervation [57]. Interestingly, glomus cells in SH rats exhibited greater DBH immunoreactivity relative to normotensive rats, suggesting that this amine is released in abundance in hypertension [56•]. This is in stark contrast to the normal age-dependent (i.e. maturational) reduction in DBH in the healthy CB [57].

Given the role for the immune system in hypertension and the pro-inflammatory function of the sympathetic nervous system [5860], inflammation within the carotid body may also be a potential mechanism. Activation of toll-like receptors increases NLRP3 inflammasome expression in carotid body cells, which enhances IL-1β production that acts in an autocrine manner to enhance peripheral chemoreceptor drive [61•].

Making the Distinction Between Peripheral Chemoreflex Sensitivity and Carotid Body Tonicity

We previously raised the issue of whether reflex chemosensitivity is always associated with carotid body hyperactivity (tonicity), or if increased carotid body tone can occur in the absence of increased chemosensitivity [62]. This remains to be fully validated. Nevertheless, it may be crucial to understand the relationship between reflex sensitivity and tonicity if the carotid body is targeted therapeutically (see below). Hyperoxia has been used to demonstrate carotid body tonicity by inactivating aberrant discharge [38•, 63]. In SH rats, hyperoxia (100 % oxygen) was found to reduce arterial pressure and renal sympathetic nerve activity [64••]. In human hypertensive patients [38•] and patients with sleep apnea [46••], a similar effect was observed, including reductions in arterial pressure and muscle sympathetic nerve activity. The cause for this pathological tone is not known, but could include mechanisms described above, driving sensitivity. These mechanisms demonstrate a fundamental role of the carotid bodies in the pathogenesis of cardiovascular disease including essential hypertension.

The Carotid Body Can Generate Hypertension: A Pre-Clinical Proof of Principle Study

Our recent endeavours with a pre-clinical model of hypertension have shown that carotid body (CB) ablation can prevent both the development of hypertension and reduce established hypertension in the SH rat [64••, 65]. The effect is prompt (1–2 days post-surgery) and very well maintained (up to 6 weeks). It is associated with a profound reduction in sympathetic nerve activity (~55 %), improved baroreceptor reflex gain and renal function, and reduced systemic inflammation [64••]. The anti-hypertensive effect is independent of the renal nerves, yet provides a summative effect if performed after renal denervation [64••]. As reviewed recently [62], unilateral carotid body resection has been used extensively as a treatment for dyspnoea in asthmatic and chronic obstructive pulmonary disease patients. In two studies, blood pressure changes were reported. Nakayama et al. documented sustained blood pressure reductions following CB resection [66]. They reported a reduction in systolic blood pressure from 170 mmHg to 130 mmHg at 5-days post-op that was maintained throughout the duration of the study (6 months). Additionally, Winter et al. noted acute blood pressure reductions after CB removal [67]. No clinical trial has studied the effect of unilateral carotid body resection for hypertension in humans.

Novel Insights Revealed by the Hypertensive Carotid Body

An understanding of the drivers of carotid body tonicity becomes crucial academically as well as clinically. We raise the question as to whether all glomus cells in hypertension become active or perhaps only those regulating sympathetic activity. Said differently, are there distinct connections from the carotid body into the nervous system targeting different reflex pathways (Fig. 1)? The observation that deactivation of carotid bodies in SH rats and humans [38•, 64••] reduces sympathetic activity, but does not affect respiration or end tidal carbon dioxide, is consistent with the distinct connection between glomus cells and central regulatory pathways as proposed above. This is further upheld by the finding that dopamine infusion to reversibly inactivate the carotid body had no effect on femoral blood flow, conductance or mean arterial pressure either at rest or during exercise, but did reduce the ventilatory response to hypoxia in healthy normotensive subjects [63]. This being the case, one might predict seeing heterogeneity amongst glomus cells in response to stimulants. Recently, a sub-population of glomus cells was found responsive to pH, but not hypoxia and vice versa [68]. Moreover, there appears to be clear demarcation of inputs to neurons within the nucleus tractus solitarii (NTS), the central site of termination of carotid chemoreceptor primary afferents. There are distinct convergence patterns on to NTS cells receiving carotid body inputs, some being excitatory and others inhibitory, from baroreceptors, cardiac receptors, and pulmonary receptors [69, 70]. Based on the patterns of reflex response from these inputs, this was interpreted as indicating the functional role of individual NTS cells in circuits controlling sympathetic, parasympathetic, respiratory outputs, or higher brain functions. This idea was consistent with the unique projection patterns of different carotid body activated NTS neurons [20]. Based on this, we hypothesise that there will a distinct sub-population of glomus cells within the carotid body that drive sympathetic activity uniquely (Fig. 1). We are underway with the quest to determine what this driver is.

Fig. 1
figure 1

Mechanistic, hypothetical model depicting separate lines of communication from individual glomus cells to distinct functional neuronal networks regulating a range of reflex visceral and behavioural responses. It is also conceivable that different glomus cells connect to different pre-motor sympathetic neurons in the rostral ventrolateral medulla (RVLM) controlling distinct target organs. Abbreviations: post-gangs post-ganglionic sympathetic neuron; pre-gangs pre-ganglionic sympathetic neurons

Trzebski and colleagues studied 20 subjects with mild hypertension versus age and sex-matched control subjects [36]. Ventilatory and blood pressure responses to hypoxia were greater in the hypertensive subjects. Interestingly, there was a significant correlation between the responses to hypoxia and hypercapnia in the normotensive subjects but not the hypertensive subjects, suggesting a predominant role for hypoxic stimulation of peripheral chemosensors in hypertension. This supports the importance of hypoxic preconditioning for chemosensitivity. However, we argue that while chemosensitivity may be present in many chronic hypertensive patients who "precondition for chemosensitivity", it remains unclear if this is coincidental or even dependent upon underlying tonic hyperactivity. In support of this, we have seen recently a hypotensive effect resulting from dopamine-mediated inhibition of the CB, while hypoxic chemosensitivity was low, in a hypertensive patient (L Ratcliffe, P Sobotka, J Paton—unpublished observation). Thus, whether chemosensitization of some type is required to increase tonicity, or if chemosensitivity can be increased without changing tonicity, is an open question. However, given our pilot data, it appears that tonicity can be increased without apparent chemosensitivity, at least to hypoxia. Indeed, the physiologic consequences of chemosensitivity and tonic hyperactivity activity may prove to be different.

Conclusions and future perspectives

In discussing carotid body chemoreceptors, Ponte and Purves (1974) remarked: “their function of ensuring adequate oxygenation of the brain may be the most important one they possess” [71]. This must include maintenance of cerebral perfusion brought about by increasing systemic arterial pressure. However, an assessment of carotid body reflex control on cerebral circulation and any modulation of this in cardiovascular disease will become important to fully appreciate Ponte and Purves’ proposal.

With direct input to the caudal commissural nucleus tractus solitarii, the carotid body provides excitatory synaptic drive to neurons that is both powerful and long lasting relative to other inputs [20]. Carotid chemoreceptors generate sympathetic activity reflexively by activating rostral ventrolateral medullary pre-sympathetic neurons [72], and indirectly by exciting respiratory neurons connected to these sympathetic neurons [43•]. Importantly, carotid chemoreceptors are essential for inducing chronic potentiation of sympathetic activity and hypertension seen after intermittent hypoxia in rats, for example [42]. Thus, their activity can cause long-term synaptic plasticity within brainstem sympatho-excitatory networks. Recent work indicates that this may include alteration in the excitability of the respiratory neurons coupled to pre-motor sympathetic neurons (Moraes, DJA, Machado BH and Paton JFR—unpublished data). Future studies now need to assess how repeated carotid body activation triggers neuronal plasticity, and why this is to functionally specific neuronal types.

Future studies will need to determine the molecular basis for the differences in carotid body reflex sensitivity versus tonicity of chemoreceptor afferents, and whether these changes occur at the level of the glomus cell and/or on the terminal ending of the primary afferents. Since in hypertension (but also heart failure), there is an increase in carotid body reflex sensitivity such that evoked increases in sympathetic activity are larger in hypertensive animals [40••] and humans [35, 36], and since this occurs before the onset of hypertension [40••], a transcriptomic analysis may be optimal in the first instance.