Anette Ebberyd scite author profile

Key points• The carotid body (CB) is the key oxygen sensor and governs the ventilatory response to hypoxia.• CB oxygen sensing and signalling gene expression is well described in animals whereas human data are absent.• Here we have characterized the human CB global gene expression in comparison with functionally related tissues and mouse CB gene expression.• We show that the human CB expresses oxygen sensing genes in common with mice but also differs on key genes such as certain K + channels. There is moreover increased expression of inflammatory response genes in human and mouse CBs in comparison with related tissues.• The study establishes similarities but also important differences between animal and human CB gene expression profiles and provides a platform for future functional studies on human CBs.Abstract The carotid body (CB) is the key oxygen sensing organ. While the expression of CB specific genes is relatively well studied in animals, corresponding data for the human CB are missing. In this study we used five surgically removed human CBs to characterize the CB transcriptome with microarray and PCR analyses, and compared the results with mice data. In silico approaches demonstrated a unique gene expression profile of the human and mouse CB transcriptomes and an unexpected upregulation of both human and mouse CB genes involved in the inflammatory response compared to brain and adrenal gland data. Human CBs express most of the genes previously proposed to be involved in oxygen sensing and signalling based on animal studies, including NOX2, AMPK, CSE and oxygen sensitive K + channels. In the TASK subfamily of K + channels, TASK-1 is expressed in human CBs, while TASK-3 and TASK-5 are absent, although we demonstrated both TASK-1 and TASK-3 in one of the mouse reference strains. Maxi-K was expressed exclusively as the spliced variant ZERO in the human CB. In summary, the human CB transcriptome shares important features with the mouse CB, but also differs significantly in the expression of a number of CB chemosensory genes. This study provides key information for future functional investigations on the human carotid body.

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Sedation with Dexmedetomidine or Propofol Impairs Hypoxic Control of Breathing in Healthy Male Volunteers

Lodenius

Ebberyd

Cedborg

et al. 2016

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Background In contrast to general anesthetics such as propofol, dexmedetomidine when used for sedation has been put forward as a drug with minimal effects on respiration. To obtain a more comprehensive understanding of the regulation of breathing during sedation with dexmedetomidine, the authors compared ventilatory responses to hypoxia and hypercapnia during sedation with dexmedetomidine and propofol. Methods Eleven healthy male volunteers entered this randomized crossover study. Sedation was administered as an intravenous bolus followed by an infusion and monitored by Observer’s Assessment of Alertness/Sedation (OAA/S) scale, Richmond Agitation Sedation Scale, and Bispectral Index Score. Hypoxic and hypercapnic ventilatory responses were measured at rest, during sedation (OAA/S 2 to 4), and after recovery. Drug exposure was verified with concentration analysis in plasma. Results Ten subjects completed the study. The OAA/S at the sedation goal was 3 (3 to 4) (median [minimum to maximum]) for both drugs. Bispectral Index Score was 82 ± 8 and 75 ± 3, and the drug concentrations in plasma at the sedation target were 0.66 ± 0.14 ng/ml and 1.26 ± 0.36 μg/ml for dexmedetomidine and propofol, respectively. Compared with baseline, sedation reduced hypoxic ventilation to 59 and 53% and the hypercapnic ventilation to 82 and 86% for dexmedetomidine and propofol, respectively. In addition, some volunteers displayed upper airway obstruction and episodes of apnea during sedation. Conclusions Dexmedetomidine-induced sedation reduces ventilatory responses to hypoxia and hypercapnia to a similar extent as sedation with propofol. This finding implies that sedation with dexmedetomidine interacts with both peripheral and central control of breathing.

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The human carotid body releases acetylcholine, ATP and cytokines during hypoxia

Kåhlin

Mkrtchian

Ebberyd

et al. 2014

Experimental Physiology

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New Findings r What is the central question of this study?Data on human carotid body (CB) function are limited. The aim of this study was therefore to investigate whether the human CB releases acetylcholine, ATP or cytokines during hypoxia. r What is the main finding and its importance?Using human CBs, we demonstrate hypoxia-induced acetylcholine and ATP release, suggesting that these neurotransmitters, as in several experimental animal models, play a role in hypoxic signalling also in the human carotid body. Moreover, the human CB releases cytokines upon hypoxia and expresses cytokine receptors as well as hypoxia-inducible factor proteins HIF-1α and HIF-2α in glomus cells, indicating their role in immune signalling and oxygen sensing, respectively, in accordance with previous animal data.Studies on experimental animals established that the carotid bodies are sensory organs for detecting arterial blood O 2 levels and that the ensuing chemosensory reflex is a major regulator of cardiorespiratory functions during hypoxia. However, little information is available on the human carotid body responses to hypoxia. The present study was performed on human carotid bodies obtained from surgical patients undergoing elective head and neck cancer surgery. Our results show that exposing carotid body slices to hypoxia for a period as brief as 5 min markedly facilitates the release of ACh and ATP. Furthermore, prolonged hypoxia for 1 h induces an increased release of interleukin (IL)-1β, IL-4, IL-6, IL-8 and IL-10. Immunohistochemical analysis revealed that type 1 cells of the human carotid body express an array of cytokine receptors as well as hypoxia-inducible factor-1α and hypoxia-inducible factor-2α. Taken together, these results demonstrate that ACh and ATP are released from the human carotid body in response to hypoxia, suggesting that these neurotransmitters, as in several experimental animal models, play a role in hypoxic signalling also in the human carotid body. The finding that the human carotid body releases cytokines in response to hypoxia adds to the growing body of information M.J.F. and L.I.E. contributed equally to this paper.

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Control of pathogen growth and biofilm formation using a urinary catheter that releases antimicrobial nitrogen oxides

Kishikawa

Ebberyd

Römling

et al. 2013

Free Radical Biology and Medicine

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The Human Carotid Body

Fagerlund

Kåhlin

Ebberyd³

et al. 2010

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Anette Ebberyd

The human carotid body transcriptome with focus on oxygen sensing and inflammation – a comparative analysis

Sedation with Dexmedetomidine or Propofol Impairs Hypoxic Control of Breathing in Healthy Male Volunteers

The human carotid body releases acetylcholine, ATP and cytokines during hypoxia

Control of pathogen growth and biofilm formation using a urinary catheter that releases antimicrobial nitrogen oxides

The Human Carotid Body

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