| A tribute to Professor Autar Singh Paintal | 1 |
| Immunolocalization of tandem pore domain K[superscript +] channels in the rat carotid body | 9 |
| Neuroglobin, a new oxygen binding protein is present in the carotid body and increases after chronic intermittent hypoxia | 15 |
| Hypoxia-inducible factor (HIF)-1[alpha] and endothelin-1 expression in the rat carotid body during intermittent hypoxia | 21 |
| Expression of HIF-2[alpha] and HIF-3[alpha] in the rat carotid body in chronic hypoxia | 29 |
| Modulation of gene expression in subfamilies of TASK K[superscript +] channels by chronic hyperoxia exposure in rat carotid body | 37 |
| Postnatal changes in gene expression of subfamilies of TASK K[superscript +] channels in rat carotid body | 43 |
| Morphological changes in the rat carotid body in acclimatization and deacclimatization to hypoxia | 49 |
| Effect of carbon dioxide on the structure of the carotid body : a comparison between normoxic and hypoxic conditions | 55 |
| S-nitrosoglutathione (SNOG) accumulates hypoxia inducible factor-1[alpha] in main pulmonary artery endothelial cells but not in micro pulmonary vessel endothelial cells | |
| Changes in antioxidant protein SP-22 of chipmunk carotid bodies during the hibernation season | 73 |
| Potential role of mitochondria in hypoxia sensing by adrenomedullary chromaffin cells | 79 |
| Localization of Ca/calmodulin-dependent protein kinase I in the carotid body chief cells and the ganglionic small intensely fluorescent (SIF) cells of adult rats | 87 |
| Dual origins of the mouse carotid body revealed by targeted disruption of Hoxa3 and Mash1 | 93 |
| Genetic regulation of chemoreceptor development in DBA/2J and A/J strains of mice | 99 |
| Genetic influence on carotid body structure in DBA/2J and A/J strains of mice | 105 |
| The effect of hyperoxia on reaction oxygen species (ROS) in petrosal and nodose ganglion neurons during development (using organotypic slices) | 111 |
| Carotid body volume in three-weeks-old rats having an episode of neonatal anoxia | 115 |
| The effect of development on the pattern of A1 and A2a-adenosine and receptor gene and protein expression in rat peripheral arterial chemoreceptors | 121 |
| A comparative study of the hypoxic secretory response between neonatal adrenal medulla and adult carotid body from the rat | 131 |
| In search of the acute oxygen sensor : functional proteomics and acute regulation of large-conductance, calcium-activated potassium channels by hemeoxygenase-2 | 137 |
| Does AMP-activated protein kinase couple inhibition of mitochondrial oxydative phosphorylation by hypoxia to pulmonary artery constriction? | 147 |
| Function of NADPH oxidase and signaling by reactive oxygen species in rat carotid body type I cells | 155 |
| Hypoxemia and attenuated hypoxic ventilatory responses in mice lacking heme oxygenese-2 : evidence for a novel role of heme oxygenese-2 as an oxygen sensor | |
| Regulation of a TASK-like potassium channel in rat carotid body type I cells by ATP | 167 |
| Accumulation of radiolabeled N-oleoyl-dopamine in the rat carotid body | 173 |
| Profiles for ATP and adenosine release at the carotid body in response to O[subscript 2] concentrations | 179 |
| Hypoxic regulation of Ca[superscript +] signalling in astrocytes and endothelial cells | 185 |
| Does AMP-activated protein kinase couple hypoxic inhibition of oxydative phosphorylation to carotid body excitation? | 191 |
| Mitochondrial ROS production initiates A[beta][subscript 1-40]-Mediated up-regulation of L-type Ca[superscript 2+] channels during chronic hypoxia | 197 |
| Actue hypoxic regulation of recombinant THIK-I stably expressed in HEK293 cells | 203 |
| Differential expression of oxygen sensitivity in voltage-dependent K channels in inbred strains of mice | 209 |
| An overview on the homeostasis of Ca[superscript 2+] in chemoreceptor cells of the rabbit and rat carotid bodies | 215 |
| Midbrain neurotransmitters in acute hypoxic ventilatory response | 223 |
| Chronic intermittent hypoxia enhances carotid body chemosensory responses to acute hypoxia | 227 |
| The cell-vessel architecture model for the central respiratory chemoreceptor | 233 |
| Loop gain of respiratory control upon reduced activity of carbonic anhydrase or Na[superscript +]/H[superscript +] exchange | 239 |
| Adrenaline increases carotid body CO[subscript 2] sensitivity : an in vivo study | 245 |
| Peripheral chemoreceptor activity on exercise-induced hyperpnea in human | 251 |
| Effects of low-dose methazolamide on the control of breathing in cats | 257 |
| Stimulus interaction between hypoxia and hypercapnia in the human peripheral chemoreceptors | 263 |
| Gene expression and signaling pathways by extracellular acidification | 267 |
| Hypoxic modulation of the cholinergic system in the cat carotid glomus cell | 275 |
| Are there "CO[subscript 2] sensors" in the lung? | 281 |
| Nitric oxide in brain glucose retention after carotid body receptors stimulation with cyanide in rats | 293 |
| Pulmonary nociceptors and potentially connected with neuroepithelial bodies | 301 |
| Modulators of cat carotid body chemotransduction | 307 |
| Identification and characterization of hypoxia sensitive Kv[alpha] subunits in pulmonary neuroepithelial bodies | 313 |
| Voltage-dependent K channels in mouse glomus cells are modulated by acetylcholine | 319 |
| Modification of the glutathione redox environment and chemoreceptor cell responses | 325 |
| Carotid body transmitters actions on rabbit petrosal ganglion in vitro | 331 |
| Potassium channels in the central control of breathing | 339 |
| Role of endothelin-1 on the enhanced carotid body activity induced by chronic intermittent hypoxia | 345 |
| Concluding remarks | 351 |
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