Updated on 2024/11/20

写真a

 
NAITOU Kiyotada
 
Organization
Research Field in Veterinary Medicine, Agriculture, Fisheries and Veterinary Medicine Area Joint faculty of Veterinary Medicine Joint Department of Veterinary Medicine Associate Professor
Title
Associate Professor

Degree

  • 博士(獣医学) ( 2016.9   岐阜大学 )

Research Areas

  • Life Science / Neuroscience-general

  • Life Science / Physiology

  • Life Science / Veterinary medical science

  • Life Science / Gastroenterology

Education

  • Gifu University   The United Graduate School of Veterinary Sciences

    2013.4 - 2016.9

Research History

  • Kagoshima University   Research Field in Veterinary Medicine, Agriculture, Fisheries and Veterinary Medicine Area Joint faculty of Veterinary Medicine Department of Veterinary Medicine   Associate Professor

    2017.11

  • Japan Society for the Promotion of Science

    2016.9 - 2017.10

  • Japan Society for the Promotion of Science

    2016.4 - 2016.9

Professional Memberships

  • 日本獣医学会

    2017

  • 日本病態生理学会

    2014.7

  • 日本生理学会

    2013.11

Committee Memberships

  • 日本生理学会   評議員  

    2023.3   

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    Committee type:Academic society

  • 日本獣医学会   生理学・生化学分科会企画委員  

    2018.9 - 2020.9   

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    Committee type:Academic society

  • 日本獣医学会   生理学・生化学分科会評議員  

    2017.11   

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    Committee type:Academic society

 

Papers

  • FERDOUS Jannatul, NAITOU Kiyotada, SHIRAISHI Mitsuya .  A peptide against the N-terminus of myristoylated alanine-rich C kinase substrate promotes neuronal differentiation in SH-SY5Y human neuroblastoma cells .  Journal of Veterinary Medical Scienceadvpub ( 0 ) 1136 - 1144   2024.9

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    Authorship:Lead author, Last author   Language:English   Publishing type:Research paper (scientific journal)   Publisher:JAPANESE SOCIETY OF VETERINARY SCIENCE  

    <p>Myristoylated alanine-rich protein kinase C substrate (MARCKS) plays crucial roles in neuronal functions and differentiation. However, specific effects of the myristoylated N-terminal sequence (MANS) peptide, a widely used MARCKS modulator comprising the initial 24 amino acids of MARCKS, on neuronal cells remain unclear. Therefore, in this study, we aimed to examine the effects and action mechanisms of the MANS peptide on SH-SY5Y human neuroblastoma cells, which served as the <i>in vitro</i> neuronal cell models. MANS treatment of SH-SY5Y cells resulted in significant neurite outgrowth within 24 hr, which was as prominent as that induced by seven days of treatment with all-trans retinoic acid, the most common agent used to induce SH-SY5Y cell differentiation. Levels of synaptophysin, a neuronal marker protein, were significantly increased in the MANS peptide-treated cells. Additionally, increased MARCKS levels and decreased MARCKS phosphorylation were observed in MANS peptide-treated cells. Notably, neurite outgrowth induced by the MANS peptide was significantly reduced in <i>MARCKS</i>-knocked-down cells. Overall, these results suggest the MANS peptide as a novel agent for SH-SY5Y cell differentiation, particularly for the analysis of MARCKS functions.</p>

    DOI: 10.1292/jvms.24-0276

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  • Jannatul Ferdous, Kiyotada Naitou, Mitsuya Shiraishi .  Distinct In Vitro Differentiation Protocols Differentially Affect Cytotoxicity Induced by Heavy Metals in Human Neuroblastoma SH-SY5Y Cells .  Biological Trace Element Research   2024.8

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    Language:English   Publishing type:Research paper (scientific journal)   Publisher:Springer Science and Business Media LLC  

    Abstract

    The SH-SY5Y cell line is widely used in neurotoxicity studies. However, the effects of inducing cell differentiation on the cytotoxic effects of heavy metals are unclear. Therefore, we investigated the effects of mercuric chloride (HgCl<sub>2</sub>), cadmium chloride (CdCl<sub>2</sub>), arsenic trioxide (As<sub>2</sub>O<sub>3</sub>), and methylmercury (MeHg) on SH-SY5Y cells differentiated in the presence of insulin-like growth factor-I (IGF-I) or all-trans retinoic acid (ATRA). Neurite outgrowth with distinct changes in neuronal marker expression, phenotype, and cell cycle was induced in SH-SY5Y cells by IGF-I treatment for 1 day or ATRA treatment for up to 7 days. The cytotoxic effects of HgCl<sub>2</sub> decreased at lower concentrations and increased at higher concentrations in both IGF-I- and ATRA-differentiated cells compared with those in undifferentiated cells. Differentiation with IGF-I, but not with ATRA, increased the cytotoxic effects of CdCl<sub>2</sub>. Decreased cytotoxic effects of As<sub>2</sub>O<sub>3</sub> and MeHg were observed at lower concentrations in IGF-I-differentiated cells, whereas increased cytotoxic effects of As<sub>2</sub>O<sub>3</sub> and MeHg were observed at higher concentrations in ATRA-differentiated cells. Changes in the cytotoxic effects of heavy metals were observed even after 1 day of ATRA exposure in SH-SY5Y cells. Our results demonstrate that the differentiation of SH-SY5Y cells by IGF-I and ATRA induces different cellular characteristics, resulting in diverse changes in sensitivity to heavy metals, which depend not only on the differentiation agents and treatment time but also on the heavy metal species and concentration.

    DOI: 10.1007/s12011-024-04342-x

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    Other Link: https://link.springer.com/article/10.1007/s12011-024-04342-x/fulltext.html

  • Otomo K, Omura T, Nozawa Y, Edwards SJ, Sato Y, Saito Y, Yagishita S, Uchida H, Watakabe Y, Naitou K, Yanai R, Sahara N, Takagi S, Katayama R, Iwata Y, Shiokawa T, Hayakawa Y, Otsuka K, Watanabe-Takano H, Haneda Y, Fukuhara S, Fujiwara M, Nii T, Meno C, Takeshita N, Yashiro K, Rosales Rocabado JM, Kaku M, Yamada T, Oishi Y, Koike H, Cheng Y, Sekine K, Koga JI, Sugiyama K, Kimura K, Karube F, Kim H, Manabe I, Nemoto T, Tainaka K, Hamada A, Brismar H, Susaki EA .  descSPIM: an affordable and easy-to-build light-sheet microscope optimized for tissue clearing techniques. .  Nature communications15 ( 1 ) 4941   2024.6descSPIM: an affordable and easy-to-build light-sheet microscope optimized for tissue clearing techniques.

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    DOI: 10.1038/s41467-024-49131-1

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  • Tomoya Sawamura, Natsufu Yuki, Kanae Aoki, Kazuhiro Horii, Yuuki Horii, Kiyotada Naitou, Shumpei Tsukamoto, Takahiko Shiina, Yasutake Shimizu .  Alterations in descending brain-spinal pathways regulating colorectal motility in a rat model of Parkinson's disease. .  American journal of physiology. Gastrointestinal and liver physiology326 ( 2 ) G195-G204 - G204   2024.2Alterations in descending brain-spinal pathways regulating colorectal motility in a rat model of Parkinson's disease.International journal

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    Patients with Parkinson's disease (PD) often have constipation. It is assumed that a disorder of the regulatory mechanism of colorectal motility by the central nervous system is involved in the constipation, but this remains unclear. The aim of this study was to investigate whether central neural pathways can modulate colorectal motility in a rat model of PD. PD model rats were generated by injection of 6-hydroxydopamine into a unilateral medial forebrain bundle and destruction of dopaminergic neurons in the substantia nigra. Colorectal motility was measured in vivo in anesthetized rats. Intraluminal administration of capsaicin, as a noxious stimulus, induced colorectal motility in sham-operated rats but not in PD rats. Intrathecally administered dopamine (DA) and serotonin (5-HT), which mediate the prokinetic effect of capsaicin, at the L6-S1 levels enhanced colorectal motility in PD rats similarly to that in sham-operated rats. In PD rats, capsaicin enhanced colorectal motility only when a GABAA receptor antagonist was preadministered into the lumbosacral spinal cord. Capsaicin-induced colorectal motility was abolished by intrathecal administration of a D2-like receptor antagonist but not by administration of 5-HT2 and 5-HT3 receptor antagonists. These findings demonstrate that the inhibitory GABAergic component becomes operative and the stimulatory serotonergic component is suppressed in PD rats. The alteration of the central regulatory mechanism of colorectal motility is thought to be related to the occurrence of constipation in PD patients. Our findings provide a new insight into the pathogenesis of defecation disorders observed in PD.NEW & NOTEWORTHY In a rat model of Parkinson's disease, the component of descending brain-spinal pathways that regulate colorectal motility through a mediation of the lumbosacral defecation center was altered from stimulatory serotonergic neurons to inhibitory GABAergic neurons. Our findings suggest that chronic constipation in Parkinson's disease patients may be associated with alterations in central regulatory mechanisms of colorectal motility. The plasticity in the descending pathway regulating colorectal motility may contribute to other disease-related defecation abnormalities.

    DOI: 10.1152/ajpgi.00181.2023

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  • Misuzu Okajima, Akiko Takenaka-Uema, Yuji Fujii, Fumiki Izumi, Isshu Kojima, Makoto Ozawa, Kiyotada Naitou, Yuto Suda, Shoko Nishiyama, Shin Murakami, Taisuke Horimoto, Naoto Ito, Hiroaki Shirafuji, Tohru Yanase, Tatsunori Masatani .  Differential role of NSs genes in the neurovirulence of two genogroups of Akabane virus causing postnatal encephalomyelitis. .  Archives of virology169 ( 1 ) 7 - 7   2023.12Differential role of NSs genes in the neurovirulence of two genogroups of Akabane virus causing postnatal encephalomyelitis.Reviewed International journal

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    Akabane virus (AKAV) is a member of the genus Orthobunyavirus, family Peribunyaviridae. In addition to AKAV strains that cause fetal Akabane disease, which is characterized by abortion in ruminants, some AKAV strains cause postnatal infection characterized by nonsuppurative encephalomyelitis in ruminants. Here, we focused on the NSs protein, a virulence factor for most viruses belonging to the genus Orthobunyavirus, and we hypothesized that this protein would act as a neurovirulence factor in AKAV strains causing postnatal encephalomyelitis. We generated AKAV strains that were unable to produce the NSs protein, derived from two different genogroups, genogroups I and II, and then examined the role of their NSs proteins by inoculating mice intracerebrally with these modified viruses. Our results revealed that the neurovirulence of genogroup II strains is dependent on the NSs protein, whereas that of genogroup I strains is independent of this protein. Notably, infection of primary cultured bovine cells with these viruses suggested that the NSs proteins of both genogroups suppress innate immune-related gene expression with equal efficiency. These results indicate differences in the determinants of virulence of orthobunyaviruses.

    DOI: 10.1007/s00705-023-05929-w

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  • Tomoya Sawamura, Natsufu Yuki, Kazuhiro Horii, Kiyotada Naitou, Hiroshi Yamaguchi, Akihiro Yamanaka, Takahiko Shiina, Yasutake Shimizu .  Essential roles of the hypothalamic A11 region and the medullary raphe nuclei in regulation of colorectal motility in rats. .  American journal of physiology. Gastrointestinal and liver physiology324 ( 6 ) G466-G475 - G475   2023.6International journal

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    The supraspinal brain regions controlling defecation reflex remain to be elucidated. The purpose of this study was to determine the roles of the hypothalamic A11 region and the medullary raphe nuclei in regulation of defecation. For chemogenetic manipulation of specific neurons, we used the double virus vector infection method in rats. hM3Dq or hM4Di was expressed in neurons of the A11 region and/or the raphe nuclei that send output to the lumbosacral defecation center. Immunohistological and functional experiments revealed that both the A11 region and the raphe nuclei directly connected with the lumbosacral spinal cord through descending pathways composed of stimulatory monoaminergic neurons. Stimulation of the hM3Dq-expressing neurons in the A11 region or the raphe nuclei enhanced colorectal motility only when GABAergic transmission in the lumbosacral spinal cord was blocked by bicuculline. Experiments using inhibitory hM4Di-expressing rats revealed that enhancement of colorectal motility caused by noxious stimuli in the colon is mediated by both the A11 region and the raphe nuclei. Furthermore, suppression of the A11 region and/or the raphe nuclei significantly inhibited water avoidance stress-induced defecation. These findings demonstrate that the A11 region and the raphe nuclei play an essential role in the regulation of colorectal motility. This is important because brain regions that mediate both intracolonic noxious stimuli-induced defecation and stress-induced defecation have been clarified for the first time.NEW & NOTEWORTHY The A11 region and the raphe nuclei, constituting descending pain inhibitory pathways, are related to both intracolonic noxious stimuli-induced colorectal motility and stress-induced defecation. Our findings may provide an explanation for the concurrent appearance of abdominal pain and defecation disorders in patients with irritable bowel syndrome. Furthermore, overlap of the pathway controlling colorectal motility with the pathway mediating stress responses may explain why stress exacerbates bowel symptoms.

    DOI: 10.1152/ajpgi.00019.2023

  • Kojima I., Onomoto K., Zuo W., Ozawa M., Okuya K., Naitou K., Izumi F., Okajima M., Fujiwara T., Ito N., Yoneyama M., Yamada K., Nishizono A., Sugiyama M., Fujita T., Masatani T. .  The Amino Acid at Position 95 in the Matrix Protein of Rabies Virus Is Involved in Antiviral Stress Granule Formation in Infected Cells .  Journal of virology96 ( 18 ) e0081022   2022.9Reviewed

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    Language:English   Publishing type:Research paper (scientific journal)   Publisher:American Society for Microbiology  

    Rabies virus (RABV) is a neglected zoonotic pathogen that causes lethal infections in almost all mammalian hosts, including humans. Recently, RABV has been reported to induce intracellular formation of stress granules (SGs), also known as platforms that activate innate immune responses.

    DOI: 10.1128/jvi.00810-22

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  • Kiyotada Naitou, Honoka Iwashita, Hiromi H Ueda, Mitsuya Shiraishi, Yoshikazu Fujimoto, Kazuhiro Horii, Tomoya Sawamura, Takahiko Shiina, Yasutake Shimizu .  Intrathecally administered substance P activated the spinal defecation center and enhanced colorectal motility in anesthetized rats. .  American journal of physiology. Gastrointestinal and liver physiology323 ( 1 ) G21 - G30   2022.4Reviewed International journal

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    Noxious stimuli on the colorectum cause colorectal contractions through activation of descending monoaminergic pathways projecting from the supraspinal defecation center to the spinal defecation center. Since it is known that substance P is involved in the response to peripheral noxious stimuli in the spinal cord, we investigated the effects of intrathecally administered substance P at L6-S1 levels on colorectal motility in rats that were anesthetized with alpha-chloralose and ketamine. Intrathecally administered substance P enhanced colorectal motility, even after transection of the thoracic spinal cord at the T4 level. Severing the pelvic nerves, but not the colonic nerves, abolished substance P-enhanced colorectal motility. In the spinal cord at L6-S1 levels, expression of mRNA coding NK1-3 receptors was detected by RT-PCR. Immunohistochemical experiments revealed that preganglionic neurons of the pelvic nerves express NK1 receptors, while expression of NK2 receptors was not found. In addition, substance P-containing fibers densely innervated around the preganglionic neurons expressing NK1 receptors. An intrathecally administered NK1 receptor antagonist (spantide) attenuated capsaicin-induced colorectal contractions. These results suggest that the colokinetic action of substance P is mediated by the NK1 receptor in the spinal defecation center. Our findings indicate that substance P may function as a neurotransmitter in the spinal defecation center.

    DOI: 10.1152/ajpgi.00342.2021

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  • Kazuhiro Horii, Tomoya Sawamura, Ayaka Onishi, Natsufu Yuki, Kiyotada Naitou, Takahiko Shiina, Yasutake Shimizu .  Contribution of sex hormones to the sexually dimorphic response of colorectal motility to noxious stimuli in rats. .  American journal of physiology. Gastrointestinal and liver physiology323 ( 1 ) G1 - G8   2022.4Reviewed International journal

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    Our recent studies have shown that noxious stimuli in the colorectum enhance colorectal motility via the brain and spinal defecation centers in male rats. In female rats, on the other hand, noxious stimuli have no effect on colorectal motility. The purpose of this study was to determine whether sex hormones are major contributing factors for sex-dependent differences in neural components of the spinal defecation center. Colorectal motility was measured using an in vivo method under ketamine and alpha-chloralose anesthesia in rats. Capsaicin was administered into the colorectal lumen as noxious stimuli. Orchiectomy in male rats had no effect on the capsaicin-induced response of colorectal motility. On the other hand, in ovariectomized female rats, capsaicin administration enhanced colorectal motility, though intact female animals did not show enhanced motility. When estradiol was administered by using a sustained-release preparation in ovariectomized female rats, capsaicin administration did not enhance colorectal motility unless a GABAA receptor antagonist was intrathecally administered to the lumbosacral spinal cord. These findings suggest that estradiol allowed the GABAergic neurons to operate in response to intracolonic administration of capsaicin. The operation of GABAergic inhibition by the action of estradiol could be manifested in male rats only when the effects of male sex hormones were removed by orchiectomy. Taken together, our results indicate that sex hormones contribute to the sexually dimorphic response in colorectal motility enhancement in response to noxious stimuli through modulating GABAergic pathways.

    DOI: 10.1152/ajpgi.00033.2022

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  • Hiromi H Ueda, Kiyotada Naitou, Hiroyuki Nakamori, Kazuhiro Horii, Takahiko Shiina, Tatsunori Masatani, Mitsuya Shiraishi, Yasutake Shimizu .  α-MSH-induced activation of spinal MC1R but not MC4R enhances colorectal motility in anaesthetised rats. .  Scientific reports11 ( 1 ) 487 - 487   2021.12Reviewed International journal

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    The central nervous system is involved in regulation of defaecation. It is generally considered that supraspinal regions control the spinal defaecation centre. However, signal transmission from supraspinal regions to the spinal defaecation centre is still unclear. In this study, we investigated the regulatory role of an anorexigenic neuropeptide, α-MSH, in the spinal defaecation centre in rats. Intrathecal administration of α-MSH to the L6-S1 spinal cord enhanced colorectal motility. The prokinetic effect of α-MSH was abolished by severing the pelvic nerves. In contrast, severing the colonic nerves or thoracic cord transection at the T4 level had no impact on the effect of α-MSH. RT-PCR analysis revealed MC1R mRNA and MC4R mRNA expression in the L6-S1 spinal cord. Intrathecally administered MC1R agonists, BMS470539 and SHU9119, mimicked the α-MSH effect, but a MC4R agonist, THIQ, had no effect. These results demonstrate that α-MSH binds to MC1R in the spinal defaecation centre and activates pelvic nerves, leading to enhancement of colorectal motility. This is, to our knowledge, the first report showing the functional role of α-MSH in the spinal cord. In conclusion, our findings suggest that α-MSH is a candidate for a neurotransmitter from supraspinal regions to the spinal defaecation centre.

    DOI: 10.1038/s41598-020-80020-x

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  • Kazuhiro Horii, Yuka Ehara, Takahiko Shiina, Kiyotada Naitou, Hiroyuki Nakamori, Yuuki Horii, Hiroki Shimaoka, Shouichiro Saito, Yasutake Shimizu .  Sexually dimorphic response of colorectal motility to noxious stimuli in the colorectum in rats. .  The Journal of physiology599 ( 5 ) 1421 - 1437   2021.3Reviewed International journal

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    KEY POINTS: This study showed a remarkable sex difference in responses of colorectal motility to noxious stimuli in the colorectum in rats: colorectal motility was enhanced in response to intracolonic administration of a noxious stimulant, capsaicin, in male rats but not in female rats. The difference in descending neurons from the brain to spinal cord operating after noxious stimulation could be responsible for the sex difference. In male rats, serotoninergic and dopaminergic neurons are dominantly activated, both of which activate the spinal defaecation centre. In female rats, GABAergic neurons in addition to serotoninergic neurons are activated. GABA may compete for facilitative action of 5-HT in the spinal defaecation centre, and thereby colorectal motility is not enhanced in response to intracolonic administration of capsaicin. The findings provide a novel insight into pathophysiological mechanisms of sex differences in functional defaecation disorders such as irritable bowel syndrome. ABSTRACT: We previously demonstrated that noxious stimuli in the colorectum enhance colorectal motility through activation of descending pain inhibitory pathways in male rats. It can be expected that the regulatory mechanisms of colorectal motility differ in males and females owing to remarkable sex differences in descending pain inhibitory pathways. Thus, we aimed to clarify sex differences in responses of colorectal motility to noxious stimuli in rats. Colorectal motility was measured in vivo in anaesthetized rats. Administration of a noxious stimulant, capsaicin, into the colorectal lumen enhanced colorectal motility in male rats but not in female rats. Quantitative PCR and immunohistochemistry showed that TRPV1 expression levels in the dorsal root ganglia and in the colorectal mucosa were comparable in male and female rats. When a GABAA receptor inhibitor was intrathecally administered to the L6-S1 level of the spinal cord, colorectal motility was facilitated in response to intracolonic capsaicin even in female rats. The capsaicin-induced response in the presence of the GABA blocker in female rats was inhibited by intrathecal administration of 5-HT2 and -3 receptor antagonists but not by a D2-like dopamine receptor antagonist. Our findings demonstrate that intracolonic noxious stimulation activates GABAergic and serotoninergic descending neurons in female rats, whereas serotoninergic and dopaminergic neurons are dominantly activated in male rats. Thus, the difference in the descending neurons operating after noxious stimulation would be responsible for the sexually dimorphic responses of colorectal motility. Our findings provide a novel insight into pathophysiological mechanisms of sex differences in functional defaecation disorders such as irritable bowel syndrome.

    DOI: 10.1113/JP279942

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  • Hiroyuki Nakamori, Kiyotada Naitou, Yuuki Horii, Hiroki Shimaoka, Kazuhiro Horii, Hiroki Sakai, Akihiro Yamada, Hidemasa Furue, Takahiko Shiina, Yasutake Shimizu .  Roles of the noradrenergic nucleus locus coeruleus and dopaminergic nucleus A11 region as supraspinal defecation centers in rats. .  American journal of physiology. Gastrointestinal and liver physiology317 ( 4 ) G545 - G555   2019.10Reviewed International journal

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    We previously demonstrated that administration of norepinephrine, dopamine, and serotonin into the lumbosacral defecation center caused propulsive contractions of the colorectum. It is known that the monoamines in the spinal cord are released mainly from descending neurons in the brainstem. In fact, stimulation of the medullary raphe nuclei, the origin of descending serotonergic neurons, enhances colorectal motility via the lumbosacral defecation center. Therefore, the purpose of this study was to examine the roles of the noradrenergic nucleus locus coeruleus (LC) and dopaminergic nucleus A11 region in the defecation reflex. Colorectal motility was measured with a balloon in anesthetized rats. Electrical stimulation of the LC and A11 region increased colorectal pressure only when a GABAA receptor antagonist was injected into the lumbosacral spinal cord. The effects of the LC stimulation and A11 region stimulation on colorectal motility were inhibited by antagonists of α1-adrenoceptors and D2-like dopamine receptors injected into the lumbosacral spinal cord, respectively. Spinal injection of a norepinephrine-dopamine reuptake inhibitor augmented the colokinetic effect of LC stimulation. The effect of stimulation of each nucleus was abolished by surgical severing of the parasympathetic pelvic nerves. Our findings demonstrate that activation of descending noradrenergic neurons from the LC and descending dopaminergic neurons from the A11 region causes enhancement of colorectal motility via the lumbosacral defecation center. The present study provides a novel concept that the brainstem monoaminergic nuclei play a role as supraspinal defecation centers.NEW & NOTEWORTHY The present study demonstrates that electrical and chemical stimulations of the locus coeruleus or A11 region augment contractions of the colorectum. The effects of locus coeruleus and A11 stimulations on colorectal motility are due to activation of α1-adrenoceptors and D2-like dopamine receptors in the lumbosacral defecation center, respectively. The present study provides a novel concept that the brainstem monoaminergic nuclei play a role as supraspinal defecation centers.

    DOI: 10.1152/ajpgi.00062.2019

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  • Kazuhiro Horii, Takahiko Shiina, Kiyotada Naitou, Hiroyuki Nakamori, Yuuki Horii, Hiroki Shimaoka, Yasutake Shimizu .  Characterization of peristaltic motility in the striated muscle portion of the esophagus using a novel in vivo method in rats. .  Neurogastroenterology and motility : the official journal of the European Gastrointestinal Motility Society31 ( 4 ) e13518   2019.4Reviewed International journal

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    BACKGROUND: Esophageal peristalsis is controlled by the brainstem via vago-vagal reflex. However, the precise regulatory mechanisms in the striated muscle portion are largely unknown. The aim of this study was to characterize peristaltic motility in the portion of the esophagus using a novel in vivo method in rats. METHODS: A balloon-tipped catheter was placed in the esophagus of a rat anesthetized with urethane. To induce esophageal peristalsis, the balloon was inflated by water injection. KEY RESULTS: When the balloon was inflated near the bronchial bifurcation, the balloon was transported in the aboral direction. Vagotomy abolished the peristaltic response. The threshold volume for inducing esophageal peristalsis varied according to the velocity of balloon distention; the volume being effective to induce peristalsis at a low inflation speed was smaller than the threshold volume at a rapid inflation speed. Even in the absence of inflation, keeping the balloon inside the esophagus during an interval period prevented subsequent induction of peristaltic motility. In addition, a nitric oxide synthase inhibitor abolished the induction of esophageal peristalsis. CONCLUSIONS AND INFERENCES: Our findings suggest that (a) in addition to the intensity, the velocity of distention is important for activating the mechanosensory mechanism to induce esophageal peristalsis, (b) tonic inputs from afferent fibers located at the mucosa may reduce the excitability of mechanosensors which is necessary for inducing peristalsis, and (c) nitric oxide plays essential roles in the induction of esophageal peristalsis. These results provide novel insights into the regulatory mechanisms of esophageal motility.

    DOI: 10.1111/nmo.13518

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  • Kiyotada Naitou, Hiroyuki Nakamori, Kazuhiro Horii, Kurumi Kato, Yuuki Horii, Hiroki Shimaoka, Takahiko Shiina, Yasutake Shimizu .  Descending monoaminergic pathways projecting to the spinal defecation center enhance colorectal motility in rats. .  American journal of physiology. Gastrointestinal and liver physiology315 ( 4 ) G631 - G637   2018.10Reviewed International journal

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    The central regulating mechanisms of defecation, especially roles of the spinal defecation center, are still unclear. We have shown that monoamines including norepinephrine, dopamine, and serotonin injected into the spinal defecation center cause propulsive contractions of the colorectum. These monoamines are the main neurotransmitters of descending pain inhibitory pathways. Therefore, we hypothesized that noxious stimuli in the colorectum would activate the descending monoaminergic pathways projecting to the spinal defecation center and that subsequently released endogenous monoamine neurotransmitters would enhance colorectal motility. Colorectal motility was measured in rats anesthetized with α-chloralose and ketamine. As a noxious stimulus, capsaicin was administered into the colorectal lumen. To interrupt neuronal transmission in the spinal defecation center, antagonists of norepinephrine, dopamine, and/or serotonin receptors were injected intrathecally at the L6-S1 spinal level, where the spinal defecation center is located. Intraluminal administration of capsaicin, acting on the transient receptor potential vanilloid 1 channel, caused transient propulsive contractions. The effect of capsaicin was abolished by surgical severing of the pelvic nerves or thoracic spinal transection at the T4 level. Capsaicin-induced contractions were blocked by preinjection of D2-like dopamine receptor and 5-hydroxytryptamine subtype 2 and 3 receptor antagonists into the spinal defecation center. We demonstrated that intraluminally administered capsaicin causes propulsive colorectal motility through reflex pathways involving the spinal and supraspinal defecation centers. Our results provide evidence that descending monoaminergic neurons are activated by noxious stimulation to the colorectum, leading to facilitation of colorectal motility. NEW & NOTEWORTHY The present study demonstrates that noxious stimuli in the colorectum activates the descending monoaminergic pathways projecting to the spinal defecation center and that subsequently released endogenous monoamine neurotransmitters, serotonin and dopamine, enhance colorectal motility. Our findings provide a possible explanation of the concurrent appearance of abdominal pain and bowel disorder in irritable bowel syndrome patients. Thus the present study may provide new insights into understanding of mechanisms of colorectal dysfunction involving the central nervous system.

    DOI: 10.1152/ajpgi.00178.2018

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  • Ban Wang, Yuri Murakami, Maiki Ono, Saki Fujikawa, Hayato Matsuyama, Toshihiro Unno, Kiyotada Naitou, Yasuyuki Tanahashi .  Muscarinic suppression of ATP-sensitive K+ channels mediated by the M3/Gq/11/phospholipase C pathway contributes to mouse ileal smooth muscle contractions. .  American journal of physiology. Gastrointestinal and liver physiology315 ( 4 ) G618 - G630   2018.10Reviewed International journal

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    ATP-sensitive K+ (KATP) channels are expressed in gastrointestinal smooth muscles, and their activity is regulated by muscarinic receptor stimulation. However, the physiological significance and mechanisms of muscarinic regulation of KATP channels are not fully understood. We examined the effects of the KATP channel opener cromakalim and the KATP channel blocker glibenclamide on electrical activity of single mouse ileal myocytes and on mechanical activity in ileal segment preparations. To explore muscarinic regulation of KATP channel activity and its underlying mechanisms, the effect of carbachol (CCh) on cromakalim-induced KATP channel currents ( IKATP) was studied in myocytes of M2 or M3 muscarinic receptor-knockout (KO) and wild-type (WT) mice. Cromakalim (10 µM) induced membrane hyperpolarization in single myocytes and relaxation in segment preparations from WT mice, whereas glibenclamide (10 µM) caused membrane depolarization and contraction. CCh (100 µM) induced sustained suppression of IKATP in cells from both WT and M2KO mice. However, CCh had a minimal effect on IKATP in M3KO and M2/M3 double-KO cells. The Gq/11 inhibitor YM-254890 (10 μM) and PLC inhibitor U73122 (1 μM), but not the PKC inhibitor calphostin C (1 μM), markedly decreased CCh-induced suppression of IKATP in WT cells. These results indicated that KATP channels are constitutively active and contribute to the setting of resting membrane potential in mouse ileal smooth muscles. M3 receptors inhibit the activity of these channels via a Gq/11/PLC-dependent but PKC-independent pathways, thereby contributing to membrane depolarization and contraction of smooth muscles. NEW & NOTEWORTHY We systematically investigated the regulation of ATP-sensitive K+ channels by muscarinic receptors expressed on mouse ileal smooth muscles. We found that M3 receptors inhibit the activity of ATP-sensitive K+ channels via a Gq/11/PLC-dependent, but PKC-independent, pathway. This muscarinic suppression of ATP-sensitive K+ channels contributes to membrane depolarization and contraction of smooth muscles.

    DOI: 10.1152/ajpgi.00069.2018

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  • Hiroki Shimaoka, Takayuki Kawaguchi, Kahori Morikawa, Yuuki Sano, Kiyotada Naitou, Hiroyuki Nakamori, Takahiko Shiina, Yasutake Shimizu .  Induction of hibernation-like hypothermia by central activation of the A1 adenosine receptor in a non-hibernator, the rat. .  The journal of physiological sciences : JPS68 ( 4 ) 425 - 430   2018.7Reviewed

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    Central adenosine A1-receptor (A1AR)-mediated signals play a role in the induction of hibernation. We determined whether activation of the central A1AR enables rats to maintain normal sinus rhythm even after their body temperature has decreased to less than 20 °C. Intracerebroventricular injection of an adenosine A1 agonist, N6-cyclohexyladenosine (CHA), followed by cooling decreased the body temperature of rats to less than 20 °C. Normal sinus rhythm was fundamentally maintained during the extreme hypothermia. In contrast, forced induction of hypothermia by cooling anesthetized rats caused cardiac arrest. Additional administration of pentobarbital to rats in which hypothermia was induced by CHA also caused cardiac arrest, suggesting that the operation of some beneficial mechanisms that are not activated under anesthesia may be essential to keep heart beat under the hypothermia. These results suggest that central A1AR-mediated signals in the absence of anesthetics would provide an appropriate condition for maintaining normal sinus rhythm during extreme hypothermia.

    DOI: 10.1007/s12576-017-0543-y

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  • Kiyotada Naitou, Takahiko Shiina, Hiroyuki Nakamori, Yuuki Sano, Hiroki Shimaoka, Yasutake Shimizu .  Colokinetic effect of somatostatin in the spinal defecation center in rats. .  The journal of physiological sciences : JPS68 ( 3 ) 243 - 251   2018.5Reviewed

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    Somatostatin and its receptors are expressed in the spinal cord, but the functional roles of the peptide remain unknown. In this study, we examined the colokinetic effect of somatostatin in the spinal defecation center in anesthetized rats. Intrathecal application of somatostatin into the lumbo-sacral cord caused propulsive contractions of the colorectum. However, somatostatin administered intravenously or intrathecally to the thoracic cord failed to enhance colorectal motility. Transection of the thoracic cord had no significant impact on the colokinetic action of somatostatin. The enhancement of colorectal motility by intrathecal administration of somatostatin was abolished by severing the pelvic nerves. Our results demonstrate that somatostatin acting on the spinal defecation center causes propulsive motility of the colorectum in rats. Considering that somatostatin is involved in nociceptive signal transmission in the spinal cord, our results provide a rational explanation for the concurrent appearance of chronic abdominal pain and colonic motility disorders in IBS patients.

    DOI: 10.1007/s12576-017-0524-1

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  • Rika Sawada, Hiroyuki Nakamori, Kiyotada Naitou, Kazuhiro Horii, Yuuki Horii, Hiroki Shimaoka, Takahiko Shiina, Yasutake Shimizu .  Local regulatory mechanism to coordinate colorectal motility in rats. .  Physiological reports6 ( 10 ) e13710   2018.5Reviewed International journal

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    The presence of a fecal pellet in the colorectum causes ascending contraction and descending relaxation, propelling the pellet aborally. However, random occurrence of the reflexes at multiple sites would disturb sequential excretion of the pellets, resulting in inefficient defecation. Hence, we postulated that a regulatory mechanism to coordinate peristaltic motility initiated at adjacent portions of the colorectum may exist. Colorectal motility was recorded with balloons located at 2 cm, 5 cm and 7 cm from the anus in vivo in anesthetized rats. The presence of a balloon in the colorectum inhibited motility of the oral side and enhanced motility of the anal side. Both the ascending inhibitory and descending facilitatory actions were unaffected by cutting the pelvic nerves, suggesting little contribution of the lumbosacral defecation center. In contrast, disrupting the continuity of the enteric nervous system abolished the local reflex mechanism. The ascending inhibitory pathway operated in a condition in which facilitatory input from the lumbosacral defecation center was fully activated by intrathecal injection of ghrelin. We also found that functional impairment of the local reflex pathways was evident in rats that recovered from 2,4,6-trinitrobenzensulfonic acid-induced colitis. These results demonstrate that an intrinsic regulatory mechanism to coordinate peristaltic motility initiated at adjacent portions exists in the rat colorectum. The regulation may be beneficial to propel multiple pellets efficiently. In addition, impairment of the local regulatory mechanism might be involved in postinflammatory dysmotility in the colorectum.

    DOI: 10.14814/phy2.13710

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  • Hiroyuki Nakamori, Kiyotada Naitou, Yuuki Horii, Hiroki Shimaoka, Kazuhiro Horii, Hiroki Sakai, Akihiro Yamada, Hidemasa Furue, Takahiko Shiina, Yasutake Shimizu .  Medullary raphe nuclei activate the lumbosacral defecation center through the descending serotonergic pathway to regulate colorectal motility in rats. .  American journal of physiology. Gastrointestinal and liver physiology314 ( 3 ) G341 - G348   2018.3Reviewed International journal

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    Colorectal motility is regulated by two defecation centers located in the brain and spinal cord. In previous studies, we have shown that administration of serotonin (5-HT) in the lumbosacral spinal cord causes enhancement of colorectal motility. Because spinal 5-HT is derived from neurons of the medullary raphe nuclei, including the raphe magnus, raphe obscurus, and raphe pallidus, we examined whether stimulation of the medullary raphe nuclei enhances colorectal motility via the lumbosacral defecation center. Colorectal pressure was recorded with a balloon in vivo in anesthetized rats. Electrical stimulation of the medullary raphe nuclei failed to enhance colorectal motility. Because GABAergic neurons can be simultaneously activated by the raphe stimulation and released GABA masks accelerating actions of the raphe nuclei on the lumbosacral defecation center, a GABAA receptor antagonist was preinjected intrathecally to manifest excitatory responses. When spinal GABAA receptors were blocked by the antagonist, electrical stimulation of the medullary raphe nuclei increased colorectal contractions. This effect of the raphe nuclei was inhibited by intrathecal injection of 5-hydroxytryptamine type 2 (5-HT2) and type 3 (5-HT3) receptor antagonists. In addition, injection of a selective 5-HT reuptake inhibitor in the lumbosacral spinal cord augmented the raphe stimulation-induced enhancement of colorectal motility. Transection of the pelvic nerves, but not transection of the colonic nerves, prevented the effect of the raphe nuclei on colorectal motility. These results demonstrate that activation of the medullary raphe nuclei causes augmented contractions of the colorectum via 5-HT2 and 5-HT3 receptors in the lumbosacral defecation center. NEW & NOTEWORTHY We have shown that electrical stimulation of the medullary raphe nuclei causes augmented contractions of the colorectum via pelvic nerves in rats. The effect of the medullary raphe nuclei on colorectal motility is exerted through activation of 5-hydroxytryptamine type 2 and type 3 receptors in the lumbosacral defecation center. The descending serotoninergic raphespinal tract represents new potential therapeutic targets against colorectal dysmotility such as irritable bowel syndrome.

    DOI: 10.1152/ajpgi.00317.2017

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  • H Nakamori, K Naitou, Y Sano, H Shimaoka, T Shiina, Y Shimizu .  Exogenous serotonin regulates colorectal motility via the 5-HT2 and 5-HT3 receptors in the spinal cord of rats. .  Neurogastroenterology and motility : the official journal of the European Gastrointestinal Motility Society30 ( 3 )   2018.3Reviewed International journal

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    BACKGROUND: We previously reported that intrathecal injection of noradrenaline or dopamine causes enhancement of colorectal motility. As these monoamines are neurotransmitters of descending pain inhibitory pathways in the spinal cord, we hypothesized that serotonin, which is one of the neurotransmitters involved in descending pain inhibition, also influences the lumbosacral defecation center. Therefore, we examined whether serotonin acting on the spinal defecation center enhances colorectal motility. METHODS: Colorectal intraluminal pressure and propelled liquid volume were recorded in vivo in anesthetized rats. KEY RESULTS: Intrathecal injection of serotonin into the L6-S1 spinal cord elicited periodic increases in colorectal intraluminal pressure, being associated with increases in liquid output. Pharmacological experiments revealed that the effect of serotonin is mediated by both 5-HT2 and 5-HT3 receptors. The serotonin-induced enhancement of colorectal motility was unaffected even after disconnection of the defecation center from supraspinal regions by cutting the T8 spinal cord, while transection of the parasympathetic pelvic nerves prevented the colokinetic effect of serotonin. Finally, we investigated interactions among serotonin, noradrenaline and dopamine. Simultaneous administration of sub-effective doses of these monoamine neurotransmitters into the spinal cord caused propulsive colorectal motility slightly but substantially. CONCLUSIONS AND INFERENCES: These results demonstrate that exogenous serotonin acts on 5-HT2 and 5-HT3 receptors in the lumbosacral defecation center and activates the parasympathetic nervous system to enhance colorectal motility in cooperation with noradrenaline and dopamine.

    DOI: 10.1111/nmo.13183.

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  • T Shiina, K Naitou, H Nakamori, Y Suzuki, K Horii, Y Sano, H Shimaoka, Y Shimizu .  Serotonin-induced contractile responses of esophageal smooth muscle in the house musk shrew (Suncus murinus). .  Neurogastroenterology and motility : the official journal of the European Gastrointestinal Motility Society28 ( 11 ) 1641 - 1648   2016.11Reviewed International journal

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    BACKGROUND: Serotonin (5-hydroxytryptamine, 5-HT) is a regulatory factor in motility of the gastrointestinal tract including the esophagus. Although we proposed that vagal cholinergic and mast cell-derived non-cholinergic components including serotonin coordinately shorten the esophagus, the precise mechanism of serotonin-induced contractions in the suncus esophagus is still unclear. Therefore, the aims of this study were to determine characteristics of contractile responses induced by serotonin and to identify 5-HT receptor subtypes responsible for regulating motility in the suncus esophagus. METHODS: An isolated segment of the suncus esophagus was placed in an organ bath, and longitudinal or circular mechanical responses were recorded using a force transducer. KEY RESULTS: Serotonin evoked contractile responses of the suncus esophagus in the longitudinal direction but not in the circular direction. Tetrodotoxin did not affect the serotonin-induced contractions. Pretreatment with a non-selective 5-HT receptor antagonist or double application of 5-HT1 and 5-HT2 receptor antagonists blocked the serotonin-induced contractions. 5-HT1 and 5-HT2 receptor agonists, but not a 5-HT3 receptor agonist, evoked contractile responses in the suncus esophagus. CONCLUSION & INFERENCES: The findings suggest that serotonin induces contractile responses of the longitudinal smooth muscle in the muscularis mucosae of the suncus esophagus that are mediated via 5-HT1 and 5-HT2 receptors on muscle cells. The serotonin-induced contractions might contribute to esophageal peristalsis and emetic response.

    DOI: 10.1111/nmo.12863.

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  • Kiyotada Naitou, Hiroyuki Nakamori, Takahiko Shiina, Azusa Ikeda, Yuuta Nozue, Yuuki Sano, Takuya Yokoyama, Yoshio Yamamoto, Akihiro Yamada, Nozomi Akimoto, Hidemasa Furue, Yasutake Shimizu .  Stimulation of dopamine D2-like receptors in the lumbosacral defaecation centre causes propulsive colorectal contractions in rats. .  The Journal of physiology594 ( 15 ) 4339 - 50   2016.8Reviewed International journal

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    KEY POINTS: The pathophysiological roles of the CNS in bowel dysfunction in patients with irritable bowel syndrome and Parkinson's disease remain obscure. In the present study, we demonstrate that dopamine in the lumbosacral defaecation centre causes strong propulsive motility of the colorectum. The effect of dopamine is a result of activation of sacral parasympathetic preganglionic neurons via D2-like dopamine receptors. Considering that dopamine is a neurotransmitter of descending pain inhibitory pathways, our results highlight the novel concept that descending pain inhibitory pathways control not only pain, but also the defaecation reflex. In addition, severe constipation in patients with Parkinson's disease can be explained by reduced parasympathetic outflow as a result of a loss of the effect of dopaminergic neurons. ABSTRACT: We have recently demonstrated that intrathecally injected noradrenaline caused propulsive contractions of the colorectum. We hypothesized that descending pain inhibitory pathways control not only pain, but also the defaecation reflex. Because dopamine is one of the major neurotransmitters of descending pain inhibitory pathways in the spinal cord, we examined the effects of the intrathecal application of dopamine to the spinal defaecation centre on colorectal motility. Colorectal intraluminal pressure and expelled volume were recorded in vivo in anaesthetized rats. Slice patch clamp and immunohistochemistry were used to confirm the existence of dopamine-sensitive neurons in the sacral parasympathetic nuclei. Intrathecal application of dopamine into the L6-S1 spinal cord, where the lumbosacral defaecation centre is located, caused propulsive contractions of the colorectum. Inactivation of spinal neurons using TTX blocked the effect of dopamine. Although thoracic spinal transection had no effect on the enhancement of colorectal motility by intrathecal dopamine, the severing of the pelvic nerves abolished the enhanced motility. Pharmacological experiments revealed that the effect of dopamine is mediated primarily by D2-like dopamine receptors. Neurons labelled with retrograde dye injected at the colorectum showed an inward current in response to dopamine in slice patch clamp recordings. Furthermore, immunohistochemical analysis revealed that neurons immunoreactive to choline acetyltransferase express D2-like dopamine receptors. Taken together, our findings demonstrate that dopamine activates sacral parasympathetic preganglionic neurons via D2-like dopamine receptors and causes propulsive motility of the colorectum in rats. The present study supports the hypothesis that descending pain inhibitory pathways regulate defaecation reflexes.

    DOI: 10.1113/JP272073.

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  • Takeshi Shima, Takahiko Shiina, Kiyotada Naitou, Hiroyuki Nakamori, Yuuki Sano, Yasutake Shimizu .  Does the capsaicin-sensitive local neural circuit constitutively regulate vagally evoked esophageal striated muscle contraction in rats? .  The journal of physiological sciences : JPS66 ( 2 ) 105 - 111   2016.5Reviewed

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    To determine whether a capsaicin-sensitive local neural circuit constitutively modulates vagal neuromuscular transmission in the esophageal striated muscle or whether the neural circuit operates in a stimulus-dependent manner, we compared the motility of esophageal preparations isolated from intact rats with those in which capsaicin-sensitive neurons had been destroyed. Electrical stimulation of the vagus nerve trunk evoked contractile responses in the esophagus isolated from a capsaicin-treated rat in a manner similar to those in the esophagus from a control rat. No obvious differences were observed in the inhibitory effects of D-tubocurarine on intact and capsaicin-treated rat esophageal motility. Destruction of the capsaicin-sensitive neurons did not significantly affect latency, time to peak and duration of a vagally evoked twitch-like contraction. These findings indicate that the capsaicin-sensitive neural circuit does not operate constitutively but rather is activated in response to an applied stimulus.

    DOI: 10.1007/s12576-015-0401-8.

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  • Takahiko Shiina, Takeshi Shima, Kazuhiro Horii, Kiyotada Naitou, Hiroyuki Nakamori, Yuuki Sano, Yasutake Shimizu .  Inhibitory action of hydrogen sulfide on esophageal striated muscle motility in rats. .  European journal of pharmacology771   123 - 129   2016.1Reviewed International journal

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    Hydrogen sulfide (H2S) is recognized as a gaseous transmitter and has many functions including regulation of gastrointestinal motility. The aim of the present study was to clarify the effects of H2S on the motility of esophageal striated muscle in rats. An isolated segment of the rat esophagus was placed in an organ bath and mechanical responses were recorded using a force transducer. Electrical stimulation of the vagus nerve evoked contractile response in the esophageal segment. The vagally mediated contraction was inhibited by application of an H2S donor. The H2S donor did not affect the contraction induced by electrical field stimulation, which can excite the striated muscle directly, not via vagus nerves. These results show that H2S has an inhibitory effect on esophageal motility not by directly attenuating striated muscle contractility but by blocking vagal motor nerve activity and/or neuromuscular transmissions. The inhibitory actions of H2S were not affected by pretreatment with the transient receptor potential vanniloid-1 blocker, transient receptor potential ankyrin-1 blocker, nitric oxide synthase inhibitor, blockers of potassium channels, and ganglionic blocker. RT-PCR and Western blot analysis revealed the expression of H2S-producing enzymes in esophageal tissue, whereas application of inhibitors of H2S-producing enzymes did not change vagally evoked contractions in the esophageal striated muscle. These findings suggest that H2S, which might be produced in the esophageal tissue endogenously, can regulate the motor activity of esophageal striated muscle via a novel inhibitory neural pathway.

    DOI: 10.1016/j.ejphar.2015.

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  • K Naitou, T P Mamerto, R V Pustovit, B Callaghan, L R Rivera, A J Chan, M T Ringuet, C Pietra, J B Furness .  Site and mechanism of the colokinetic action of the ghrelin receptor agonist, HM01. .  Neurogastroenterology and motility : the official journal of the European Gastrointestinal Motility Society27 ( 12 ) 1764 - 71   2015.12Reviewed International coauthorship International journal

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    BACKGROUND: It has been recently demonstrated that the ghrelin receptor agonist, HM01, caused defecation in rats that were treated to provide a model for the constipation of Parkinson's disease. HM01 significantly increased fecal output and increased Fos activity in neurons of the hypothalamus and hindbrain, but not in the spinal defecation center. Other ghrelin agonists act on the defecation center. METHODS: Receptor pharmacology was examined in ghrelin receptor (GHSR1a) transfected cells. Anesthetized rats were used to investigate sites and mechanisms of action. KEY RESULTS: HM01 activated rat GHSR1a at nanomolar concentrations and was antagonized by the GHSR1a antagonist, YIL781. HM01, intravenous, was potent to activate propulsive colorectal contractions. This was prevented by pelvic nerve section and by intravenous YIL781, but not by spinal cord section rostral to the defecation centers. Direct intrathecal application of HM01 to the defecation center at spinal level L6-S1 initiated propulsive contractions of the colorectum. CONCLUSIONS & INFERENCES: HM01 stimulates GHSR1a receptors on neurons in the lumbosacral defecation centers to cause propulsive contractions and emptying of the colorectum. It has greater potency when given systemically, compared with other GHSR1a agonists.

    DOI: 10.1111/nmo.12688.

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  • Takahiko Shiina, Takeshi Shima, Kiyotada Naitou, Hiroyuki Nakamori, Yuuki Sano, Kazuhiro Horii, Masaki Shimakawa, Hiroshi Ohno, Yasutake Shimizu .  Actions of probiotics on trinitrobenzenesulfonic acid-induced colitis in rats. .  BioMed research international2015   528523 - 528523   2015.12Reviewed International journal

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    We investigated the actions of probiotics, Streptococcus faecalis 129 BIO 3B (SF3B), in a trinitrobenzenesulfonic acid- (TNBS-) induced colitis model in rats. After TNBS was administered into the colons of rats for induction of colitis, the rats were divided into two groups: one group was given a control diet and the other group was given a diet containing SF3B for 14 days. There were no apparent differences in body weight, diarrhea period, macroscopic colitis score, and colonic weight/length ratio between the control group and SF3B group, suggesting that induction of colitis was not prevented by SF3B. Next, we investigated whether SF3B-containing diet intake affects the restoration of enteric neurotransmissions being damaged during induction of colitis by TNBS using isolated colonic preparations. Recovery of the nitrergic component was greater in the SF3B group than in the control group. A compensatory appearance of nontachykininergic and noncholinergic excitatory components was less in the SF3B group than in the control group. In conclusion, the present study suggests that SF3B-containing diet intake can partially prevent disruptions of enteric neurotransmissions induced after onset of TNBS-induced colitis, suggesting that SF3B has therapeutic potential.

    DOI: 10.1155/2015/528523.

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  • Kiyotada Naitou, Takahiko Shiina, Kurumi Kato, Hiroyuki Nakamori, Yuuki Sano, Yasutake Shimizu .  Colokinetic effect of noradrenaline in the spinal defecation center: implication for motility disorders. .  Scientific reports5   12623 - 12623   2015.7Reviewed International journal

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    Chronic abdominal pain in irritable bowel syndrome (IBS) usually appears in combination with disturbed bowel habits, but the etiological relationship between these symptoms remains unclear. Noradrenaline is a major neurotransmitter controlling pain sensation in the spinal cord. To test the hypothesis that the descending noradrenergic pathway from the brain stem moderates gut motility, we examined effects of intrathecal application of noradrenaline to the spinal defecation center on colorectal motility. Colorectal intraluminal pressure and expelled volume were recorded in vivo in anesthetized rats. Intrathecal application of noradrenaline into the L6-S1 spinal cord, where the lumbosacral defecation center is located, caused propulsive contractions of the colorectum. Inactivation of spinal neurons by tetrodotoxin blocked the effect of noradrenaline. Pharmacological experiments showed that the effect of noradrenaline is mediated primarily by alpha-1 adrenoceptors. The enhancement of colorectal motility by intrathecal noradrenaline was abolished by severing of the pelvic nerves. Our results demonstrate that noradrenaline acting on sacral parasympathetic preganglionic neurons through alpha-1 adrenoceptors causes propulsive motility of the colorectum in rats. Considering that visceral pain activates the descending inhibitory pathways including noradrenergic neurons, our results provide a rational explanation of the concurrent appearance of chronic abdominal pain and colonic motility disorders in IBS patients.

    DOI: 10.1038/srep12623.

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  • Yuuki Sano, Takahiko Shiina, Kiyotada Naitou, Hiroyuki Nakamori, Yasutake Shimizu .  Hibernation-specific alternative splicing of the mRNA encoding cold-inducible RNA-binding protein in the hearts of hamsters. .  Biochemical and biophysical research communications462 ( 4 ) 322 - 532   2015.7Reviewed International journal

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    The hearts of hibernating animals are capable of maintaining constant beating despite a decrease in body temperature to less than 10 °C during hibernation, suggesting that the hearts of hibernators are highly tolerant to a cold temperature. In the present study, we examined the expression pattern of cold-inducible RNA-binding protein (CIRP) in the hearts of hibernating hamsters, since CIRP plays important roles in protection of various types of cells against harmful effects of cold temperature. RT-PCR analysis revealed that CIRP mRNA is constitutively expressed in the heart of a non-hibernating euthermic hamster with several different forms probably due to alternative splicing. The short product contained the complete open reading frame for full-length CIRP. On the other hand, the long product had inserted sequences containing a stop codon, suggesting production of a C-terminal deletion isoform of CIRP. In contrast to non-hibernating hamsters, only the short product was amplified in hibernating animals. Induction of artificial hypothermia in non-hibernating hamsters did not completely mimic the splicing patterns observed in hibernating animals, although a partial shift from long form mRNA to short form was observed. Our results indicate that CIRP expression in the hamster heart is regulated at the level of alternative splicing, which would permit a rapid increment of functional CIRP when entering hibernation.

    DOI: 10.1016/j.bbrc.2015.04.135.

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  • Takahiko Shiina, Kiyotada Naitou, Hiroyuki Nakamori, Hiroki Sakai, Yasutake Shimizu .  Regulation of longitudinal esophageal motility in the house musk shrew (Suncus murinus). .  Autonomic neuroscience : basic & clinical189   37 - 42   2015.5Reviewed International journal

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    Suncus murinus (house musk shrew; suncus) is a species of insectivore that has an ability to vomit. Although longitudinal movement of the esophagus would be related to the emetic response, regulatory mechanisms for the suncus esophageal motility are unclear. Therefore, the aim of the present study was to clarify components that regulate esophageal motility in the suncus. An isolated segment of the suncus esophagus was placed in an organ bath, and longitudinal mechanical responses were recorded using a force transducer. Electrical stimulation of the vagus trunk evoked a biphasic contractile response. The first phase of the contractile response was blocked by α-bungarotoxin, a blocker of nicotinic acetylcholine receptors on striated muscle cells, whereas the second one was blocked by atropine, a blocker of muscarinic acetylcholine receptors on smooth muscle cells. Next, we investigated whether mast cells are involved in motor functions of the suncus esophagus. Application of a mast cell stimulator, compound 48/80, elicited contractile responses, which was resistant to tetrodotoxin. Exogenous application of serotonin and histamine induced contractile responses. The mast cell activation-mediated contraction was abolished by double desensitization by serotonin and histamine and pre-treatment with indomethacin, a cyclooxygenase inhibitor. The findings show that cholinergic and non-cholinergic transmitters induce longitudinal contraction in the suncus esophagus, which might contribute to esophageal shortening during emesis. Cholinergic transmitters are derived from vagal efferents, and non-cholinergic transmitters, which are thought to be serotonin, histamine and prostaglandins, are released from mast cells.

    DOI: 10.1016/j.autneu.2015.02.003.

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  • K Naitou, T Shiina, R Sugita, H Nakamori, Y Shimizu .  Characterization of ghrelin-sensitive neurons in the lumbosacral defecation center in rats. .  Neurogastroenterology and motility : the official journal of the European Gastrointestinal Motility Society27 ( 1 ) 147 - 55   2015.1Reviewed International journal

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    BACKGROUND: Ghrelin is involved in the regulation of somatic growth, feeding behavior and energy homeostasis. Ghrelin stimulates neuropeptide Y (NPY) neurons and activates intracellular AMP-activated protein kinase (AMPK) in the hypothalamus. These NPY neurons also express the leptin receptor and leptin inhibits ghrelin-induced activation of NPY neurons. In the spinal cord, we have demonstrated colokinetic action of ghrelin. However, the precise characteristics of the ghrelin-sensitive neurons remain to be clarified. The aim of this study was firstly to confirm that the action of ghrelin is mediated via a neurogenic pathway in the spinal cord, and secondly to characterize the ghrelin-sensitive neurons by comparing with hypothalamic ghrelin-sensitive neurons. METHODS: Rats were anesthetised with alpha-chloralose and ketamine, and colorectal intraluminal pressure and expelled volume were recorded in vivo. Drugs were applied intrathecally. KEY RESULTS: Ghrelin caused enhancement of propulsive contractions. Tetrodotoxin completely blocked the colokinetic effect of ghrelin. An AMPK activator, aminoimidazole carboxamide ribonucleotide, failed to mimic the ghrelin effect. Leptin had no effect on the spontaneous contractions and did not exert a suppressive effect on the ghrelin-enhanced colorectal motility. An NPY Y1 receptor antagonist did not affect the action of ghrelin. NPY had no effect on the colorectal motility. CONCLUSIONS & INFERENCES: This study showed that intrathecal injection of ghrelin stimulates colorectal motility by acting on ghrelin-sensitive neurons in the lumbosacral defecation center. The characteristics of ghrelin-sensitive neurons in the spinal cord are quite different from those of ghrelin-sensitive neurons in the hypothalamus.

    DOI: 10.1111/nmo.12492.

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  • Takeshi Shima, Takahiko Shiina, Kiyotada Naitou, Hiroyuki Nakamori, Yasutake Shimizu .  Functional roles of capsaicin-sensitive intrinsic neural circuit in the regulation of esophageal peristalsis in rats: in vivo studies using a novel method. .  American journal of physiology. Gastrointestinal and liver physiology306 ( 9 ) G811 - G818   2014.5Reviewed International journal

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    A well-developed myenteric plexus exists in the esophagus composed of striated muscle layers, but its functional role in controlling peristaltic movements remains to be clarified. The purpose of this study was to clarify the role of a local neural reflex consisting of capsaicin-sensitive primary afferent neurons and intrinsic neurons in esophageal peristalsis. We firstly devised a method to measure peristaltic movement of esophagus in vivo in rats. Rats were anesthetized with urethane, and esophageal intraluminal pressure and propelled intraluminal liquid volume were recorded. In the experimental system, an intraluminal pressure stimulus evoked periodic changes in intraluminal pressure of the esophagus, which were consistently accompanied by intraluminal liquid propulsion. Bilateral vagotomy abolished changes in intraluminal pressure as well as liquid propulsion. These results indicate that the novel method is appropriate for inducing peristalsis in the esophagus composed of striated muscles. Then, by using the method, we examined functional roles of the local reflex in esophageal peristalsis. For that purpose, we used rats in which capsaicin-sensitive neurons had been destroyed. The esophagus of capsaicin-treated rats showed a multiphasic rise in intraluminal pressure, which may due to noncoordinated contractions of esophageal muscles, whereas a monophasic response was observed in the intact rat esophagus. In addition, destruction of capsaicin-sensitive neurons increased the propelled liquid volume and lowered the pressure threshold for initiating peristalsis. These results suggest that the local neural reflex consisting of capsaicin-sensitive neurons and intrinsic neurons contributes to coordination of peristalsis and suppresses mechanosensory function of vagal afferents in the esophagus.

    DOI: 10.1152/ajpgi.00250.2013.

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    内藤清惟

    南日本新聞   2023.10

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    Authorship:Lead author   Language:Japanese  

  • 腰仙髄部脊髄における1型メラノコルチン受容体の発現および局在の検討

    内藤清惟, 児島一州, 植田大海, 白石光也, 奥谷公亮, 小澤真, 正谷達謄

    日本病態生理学会雑誌   32 ( 2 )   2023

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  • 研究におけるウイルスの利用 排便制御メカニズムの解明を目指して

    内藤 清惟

    日本病態生理学会雑誌   31 ( 3 )   46 - 48   2022.12

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    Language:Japanese   Publisher:日本病態生理学会  

    ウイルスは、病気を引き起こす原因として、一般的に「悪者」として扱われます。しかし、生理学・病態生理学の分野では、ウイルスを有益な研究ツールとして利用しています。特に、神経科学の領域では、アデノ随伴ウイルスや狂犬病ウイルスなどのウイルスがよく利用されています。私は、これまで中枢神経系による排便制御メカニズムの解明を目指して研究を行なってきました。特に、脊髄に着目した研究を行なってきており、様々な伝達物質が排便制御に関わっていること、排便制御に関わる脳神経領域など、中枢神経系による排便制御メカニズムの一端を明らかにしました。現在は、排便を制御する中枢神経系のシステムの全体像を明らかにするための研究を実施しています。現在行なっている、アデノ随伴ウイルスや狂犬病ウイルス、組織透明化などの新規技術を用いた研究を紹介させていただきます。(著者抄録)

  • 脊髄排便中枢においてα-MSHは1型メラノコルチン受容体(MC1R)を介して大腸運動を促進する

    植田大海, 内藤清惟, 白石光也, 児島一州, 正谷達謄, 椎名貴彦, 志水泰武

    日本病態生理学会雑誌   31 ( 2 )   2022

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  • 未分化型および分化型ヒト由来培養神経細胞におけるウイルス感受性の比較

    牧野遥, 正谷達謄, 藤本佳万, 藤本佳万, 内藤清惟, 白石光也

    日本獣医学会学術集会講演要旨集   164th (CD-ROM)   2021

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  • 脊髄排便中枢に着目した排便障害の病態メカニズムの解明

    内藤 清惟, 中森 裕之, 堀井 和広, 椎名 貴彦, 志水 泰武

    日本病態生理学会雑誌   26 ( 3 )   42 - 47   2017.12

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    Publisher:日本病態生理学会  

    近年、ストレスによる排便障害が注目を集めており、中枢神経系による排便制御メカニズムの解明が求められているが、未だその多くの部分が謎に包まれている。そこで私たちは、これまで特に研究の進んでいなかった脊髄排便中枢に着目することで、中枢神経系による排便制御メカニズムの解明を目指してきた。これまでの研究の成果から、1)モノアミン神経伝達物質であるノルアドレナリン、ドパミン、セロトニンが脊髄排便中枢に作用し、大腸運動を促進すること、2)大腸に与えた侵害刺激によって中枢神経系を介して大腸運動が亢進すること、3)この反応に脊髄排便中枢のドパミンおよびセロトニンが関与すること、が明らかになった。これらのことから、大腸における侵害刺激が脳からの下行性ドパミンおよびセロトニン経路を活性化することで、大腸運動を促進することが示された。本稿では、私たちの研究結果とそこから見えてくる中枢神経系による排便制御メカニズムについて概説する。(著者抄録)

  • シリアンハムスターにおける冬眠特異的なcold-inducible RNA-binding proteinの発現調節

    佐野 有希, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武

    日本病態生理学会雑誌   24 ( 3 )   18 - 25   2015.12

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    Language:Japanese   Publisher:日本病態生理学会  

  • Inhibitory actions of hydrogen sulfide on contractions of the esophageal striated muscle

    Takahiko Shiina, Kiyotada Naitou, Hiroyuki Nakamori, Yasutake Shimizu

    NITRIC OXIDE-BIOLOGY AND CHEMISTRY   39   S31 - S31   2014.5

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    Language:English   Publishing type:Research paper, summary (international conference)   Publisher:ACADEMIC PRESS INC ELSEVIER SCIENCE  

    DOI: 10.1016/j.niox.2014.03.099

    Web of Science

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Presentations

  • 俣野 拓友、植田 大海、Jannatul Ferdous、髙木 隆太、藤本 佳万、白石 光也、内藤 清惟   ラット脊髄腰仙髄部に投与したコレシストキニンが大腸運動を活性化する  

    第167回日本獣医学会学術集会   2024.9  日本獣医学会

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    Event date: 2024.9

    Language:Japanese   Presentation type:Oral presentation (general)  

    Venue:帯広市(帯広畜産大学)  

  • Jannatul FERDOUS, Kiyotada NAITOU, Mitsuya SHIRAISHI   Comparison of in vitro differentiation protocols for heavy metal-induced cytotoxicity in human neuroblastoma SH-SY5Y cells  

    第51回日本毒性学会年会   2024.7  日本毒性学会

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    Event date: 2024.7

    Presentation type:Poster presentation  

    Venue:福岡市(福岡国際会議場 )  

  • 俣野 拓友、髙木 隆太、植田 大海、藤本 佳万、白石 光也、内藤 清惟   脊髄排便中枢におけるコレシストキニン8の作用の検討  

    第101回日本生理学会大会  2024.3  日本生理学会

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    Event date: 2024.3

    Language:English   Presentation type:Poster presentation  

    Venue:北九州市(北九州国際会議場)  

  • Ferdous Jannatul、内藤 清惟、白石 光也   MARCKS-related peptide induced neurite outgrowth in SH-SY5Y cells   International coauthorship

    第166回 日本獣医学会学術会議  2023.9 

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    Event date: 2023.9

    Language:Japanese   Presentation type:Oral presentation (general)  

  • 内藤 清惟、児島 一州、植田 大海、白石 光也、奥谷 公亮、 小澤 真、正谷 達謄   腰仙髄部脊髄における1型メラノコルチン受容体の発現および局在の検討  

    第32回 日本病態生理学会大会  2023.8 

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    Event date: 2023.8

    Language:Japanese   Presentation type:Oral presentation (general)  

  • Natsufu Yuki, Tomoya Sawamura, Kazuhiro Horii, Kiyotada Naitou, Hiroshi Yamaguchi, Akihiro Yamanaka, Takahiko Shiina, Yasutake Shimizu   Glutamatergic Stimulation of The Dorsomedial Hypothalamus Enhances Colorectal Motility By Activating Descending Serotonergic And Dopaminergic Neurons In Rats   International conference

    ISAN2022 (International Society for Autonomic Neuroscience)  2022.9  International Society for Autonomic Neuroscience

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    Event date: 2022.9

    Language:English   Presentation type:Poster presentation  

    Country:Australia  

  • Tomoya Sawamura, Kazuhiro Horii, Natsufu Yuki, Kiyotada Naitou, Hiroshi Yamaguchi, Akihiro Yamanaka, Takahiko Shiina, Yasutake Shimizu   Role of Descending Monoaminergic Neurons From The A11 Region And Medullary Raphe Nuclei In Regulation of Colorectal Motility In Rats   International conference

    ISAN2022 (International Society for Autonomic Neuroscience)  2022.9  International Society for Autonomic Neuroscience

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    Event date: 2022.9

    Language:English   Presentation type:Poster presentation  

    Country:Australia  

  • Yasutake Shimizu, Kazuhiro Horii, Tomoya Sawamura, Natsufu Yuki, Kiyotada Naitou, Takahiko Shiina   Female-Specific Gabaergic Inhibition of The Lumbosacral Defecation Center In Rats   International conference

    ISAN2022 (International Society for Autonomic Neuroscience)  2022.9  International Society for Autonomic Neuroscience

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    Event date: 2022.9

    Language:English   Presentation type:Poster presentation  

    Country:Australia  

  • Kiyotada Naitou, Honoka Iwashita, Hiromi H Ueda, Mitsuya Shiraishi, Yoshikazu Fujimoto, Kazuhiro Horii, Tomoya Sawamura, Takahiko Shiina, Yasutake Shimizu   Spinal Substance P Related To Defecation Reflexes And Enhanced Colorectal Motility   International conference

    ISAN2022 (International Society for Autonomic Neuroscience)  2022.9  International Society for Autonomic Neuroscience

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    Event date: 2022.9

    Language:English   Presentation type:Poster presentation  

    Country:Australia  

  • 植田 大海, 内藤 清惟, 白石 光也, 児島 一州, 正谷 達謄, 椎名 貴彦, 志水 泰武   脊髄排便中枢においてα-MSHは1型メラノコルチン受容体(MC1R)を介して大腸運動を促進する  

    日本病態生理学会  2022.8  日本病態生理学会

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    Event date: 2022.8

    Language:Japanese   Presentation type:Oral presentation (general)  

    Venue:岐阜  

  • 内藤 清惟   感染症の病態生理 研究におけるウイルスの利用 排便制御メカニズムの解明を目指して   Invited

    日本病態生理学会  2022.8  日本病態生理学会

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    Event date: 2022.8

    Language:Japanese   Presentation type:Public lecture, seminar, tutorial, course, or other speech  

    Venue:岐阜  

  • 内藤清惟、岩下朋乃樺、植田大海、白石光也、藤本佳万、椎名貴彦、志水泰武   脊髄排便中枢におけるサブスタンスPの大腸運動促進作用  

    第164回日本獣医学会学術集会  2021.9  日本獣医学会

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    Event date: 2021.9

    Language:Japanese   Presentation type:Oral presentation (general)  

    Venue:酪農学園大学(オンライン開催)   Country:Japan  

  • 内藤清惟   排便制御に関わる中枢神経系の神経回路の解明   Invited

    第164回日本獣医学会学術集会  2021.9  日本獣医学会

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    Event date: 2021.9

    Language:Japanese   Presentation type:Oral presentation (invited, special)  

    Venue:酪農学園大学(オンライン開催)   Country:Japan  

  • 児島一州、尾野本浩司、内藤清惟、岡島美鈴、奧谷公亮、伊藤直人、杉山誠、小澤真、米山光俊、藤田尚志、正谷達謄   狂犬病ウイルスM蛋白質95位のアミノ酸はストレス顆粒形成に関与する  

    第164回日本獣医学会学術集会  2021.9  日本獣医学会

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    Event date: 2021.9

    Language:Japanese   Presentation type:Oral presentation (general)  

    Venue:酪農学園大学(オンライン開催)   Country:Japan  

  • 岡島美鈴、児島一州、内藤清惟、小澤真、須田遊人、梁瀬徹、正谷達謄   生後感染型アカバネウイルスの神経病原性におけるNSs蛋白質の役割  

    第164回日本獣医学会学術集会  2021.9  日本獣医学会

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    Event date: 2021.9

    Language:Japanese   Presentation type:Oral presentation (general)  

    Venue:酪農学園大学(オンライン開催)   Country:Japan  

  • 牧野遥、正谷達謄、藤本佳万、内藤清惟、白石光也   未分化型および分化型ヒト由来培養神経細胞におけるウイルス感受性の比較  

    第164回日本獣医学会学術集会  2021.9  日本獣医学会

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    Event date: 2021.9

    Language:Japanese   Presentation type:Oral presentation (general)  

    Venue:酪農学園大学(オンライン開催)   Country:Japan  

  • 内藤清惟   排便制御に関わる中枢神経系の神経回路の解明   Invited

    第164回日本獣医学会学術集会  2021.9 

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    Event date: 2021.9

    Presentation type:Oral presentation (invited, special)  

  • 内藤清惟、植田大海、白石光也、正谷逹謄、中森裕之、堀井和広、椎名貴彦、志水泰武   1型メラノコルチン受容体を介した脊髄排便中枢の活性化作用  

    第98回日本生理学会大会  2021.3 

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    Event date: 2021.3

    Language:English   Presentation type:Poster presentation  

  • 植田大海、内藤清惟、白石光也、中森裕之、椎名貴彦、志水泰武   in vivo大腸運動記録を用いたα-MSHによる排便促進作用メカニズムの検討  

    第10回 名古屋大学医学系研究科・生理学研究所合同シンポジウム 

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    Event date: 2020.9

    Language:Japanese   Presentation type:Oral presentation (general)  

  • 植田 大海、白石 光也、中森 裕之、椎名 貴彦、志水 泰武、内藤 清惟   alpha-melanocyte-stimulating hormone(alpha-MSH)の脊髄内投与による排便促進作用の解析  

    第97回日本生理学会大会 

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    Event date: 2020.3

    Language:English   Presentation type:Poster presentation  

    Venue:大分県別府市(別府国際コンベンションセンター)  

  • 植田大海、白石光也、中森裕之、椎名貴彦、志水泰武、内藤清惟   脊髄排便中枢におけるα-MSHによる大腸運動促進メカニズムの検討  

    第162回日本獣医学会学術集会 

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    Event date: 2019.9

    Language:Japanese   Presentation type:Oral presentation (general)  

    Venue:つくば国際会議場(茨城県つくば市)  

  • Horii Kazuhiro, Ehara Yuka, Naitou Kiyotada, Nakamori Hiroyuki, Shiina Takahiko, Shimizu Yasutake   ラットにおける侵害刺激による結腸直腸運動性の性的二形性反応に関するメカニズム(The mechanism of sexually dimorphic responses of colorectal motility by noxious stimulation in rats)  

    The Journal of Physiological Sciences  2019.6  (一社)日本生理学会

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    Event date: 2019.6

  • Kazuhiro Horii, Yuka Ehara, Kiyotada Naitou, Hiroyuki Nakamori, Takahiko Shiina, Yasutake Shimizu   The mechanism of sexually dimorphic responses of colorectal motility by noxious stimulation in rats.   International conference

    9th Federation of the Asian and Oceanian Physiological Societies Congress (FAOPS2019)  日本生理学会

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    Event date: 2019.3

    Language:English   Presentation type:Poster presentation  

    Venue:神戸市  

  • Kazuhiro Horii, Yuka Ehara, Kiyotada Naitou, Hiroyuki Nakamori, Takahiko Shiina, Yasutake Shimizu   Sexually dimorphic regulation of colorectal motility by descending pain inhibitory pathways in rats.   International conference

    10th Joint Symposium of Veterinary Research in East Asia 

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    Event date: 2019.2

    Language:English   Presentation type:Poster presentation  

    Venue:岐阜市  

  • 堀井 和広, 江原 優花, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   ラットの下行性疼痛抑制系を介した大腸運動制御における雌雄差  

    日本生理学雑誌  2019.2  (一社)日本生理学会

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    Event date: 2019.2

  • 堀井和広、江原優花、内藤清惟、中森裕之、椎名貴彦、志水泰武   ラットの下行性疼痛抑制経路を介した大腸運動制御における雌雄差  

    第65回中部日本生理学会 

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    Event date: 2018.11

    Language:Japanese   Presentation type:Oral presentation (general)  

    Venue:名古屋大学(愛知・名古屋)  

  • 堀井和広, 江原優花, 内藤清惟, 中森裕之, 椎名貴彦, 志水泰武   侵害刺激による大腸運動の促進反応に性差がみられるメカニズムの解明  

    第161回日本獣医学会学術集会 

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    Event date: 2018.9

    Language:Japanese   Presentation type:Oral presentation (general)  

  • 中森 裕之, 内藤 清惟, 堀井 和広, 椎名 貴彦, 志水 泰武   ラットのモノアミン関連神経核による脊髄排便中枢を介した大腸運動制御  

    第28回日本病態生理学会大会 

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    Event date: 2018.8

    Language:Japanese   Presentation type:Oral presentation (general)  

  • 堀井 和広, 江原 優花, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   侵害刺激による大腸運動の促進反応に性差がみられるメカニズムの解明  

    日本獣医学会学術集会講演要旨集  2018.8  (公社)日本獣医学会

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    Event date: 2018.8

  • 堀井 和広, 江原 優花, 中森 裕之, 内藤 清惟, 椎名 貴彦, 志水 泰武   ラットの痛みによる大腸運動制御における脊髄内伝達物質の性差  

    日本病態生理学会雑誌  2018.7  日本病態生理学会

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    Event date: 2018.7

  • 中森 裕之, 内藤 清惟, 堀井 和広, 椎名 貴彦, 志水 泰武   ラットのモノアミン関連神経核による脊髄排便中枢を介した大腸運動制御  

    日本病態生理学会雑誌  2018.7  日本病態生理学会

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    Event date: 2018.7

  • Naitou Kiyotada, Shiina Takahiko, Nakamori Hiroyuki, Horii Kazuhiro, Shimizu Yasutake   Colokinetic effect of somatostatin on the spinal cord in anesthetized rats.  

    第95回日本生理学会大会 

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    Event date: 2018.3

    Language:English   Presentation type:Poster presentation  

  • Shiina Takahiko, Horii Kazuhiro, Naitou Kiyotada, Nakamori Hiroyuki, Shimizu Yasutake   Regulation of esophageal motility by purinergic signaling in rats  

    第95回日本生理学会大会 

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    Event date: 2018.3

    Language:English   Presentation type:Poster presentation  

  • Horii Kazuhiro, Ehara Yuka, Naitou Kiyotada, Nakamori Hiroyuki, Shiina Takahiko, Shimizu Yasutake   Sex-specific regulation of colorectal motility via descending inhibitory pathway in rats  

    第95回日本生理学会大会 

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    Event date: 2018.3

    Language:English   Presentation type:Poster presentation  

  • Horii Kazuhiro, Ehara Yuka, Naitou Kiyotada, Nakamori Hiroyuki, Shiina Takahiko, Shimizu Yasutake   ラットの性別特異的な大腸運動制御には下行性抑制経路が介在する(Sex-specific regulation of colorectal motility via descending inhibitory pathway in rats)  

    The Journal of Physiological Sciences  2018.3  (一社)日本生理学会

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    Event date: 2018.3

  • Naitou Kiyotada, Shiina Takahiko, Nakamori Hiroyuki, Horii Kazuhiro, Shimizu Yasutake   Somatostatinが麻酔下ラット脊髄において大腸運動に与える作用(Colokinetic effect of somatostatin on the spinal cord in anesthetized rats)  

    The Journal of Physiological Sciences  2018.3  (一社)日本生理学会

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    Event date: 2018.3

  • Shiina Takahiko, Horii Kazuhiro, Naitou Kiyotada, Nakamori Hiroyuki, Shimizu Yasutake   プリン作動性シグナル伝達によるラットの食道運動の制御(Regulation of esophageal motility by purinergic signaling in rats)  

    The Journal of Physiological Sciences  2018.3  (一社)日本生理学会

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    Event date: 2018.3

  • 堀井 和広, 中森 裕之, 内藤 清惟, 椎名 貴彦, 志水 泰武   ラットの食道蠕動を解析できるin vivo実験法の確立  

    日本生理学雑誌  2018.2  (一社)日本生理学会

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    Event date: 2018.2

  • 内藤 清惟, 中森 裕之, 堀井 和広, 椎名 貴彦, 志水 泰武   脊髄排便中枢におけるソマトスタチンによる大腸運動亢進メカニズムの検討  

    日本獣医学会学術集会講演要旨集  2017.8  (公社)日本獣医学会

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    Event date: 2017.8

  • 堀井 和広, 中森 裕之, 内藤 清惟, 椎名 貴彦, 志水 泰武   カリウムチャネルを介するラット食道横紋筋の運動制御  

    日本獣医学会学術集会講演要旨集  2017.8  (公社)日本獣医学会

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    Event date: 2017.8

  • 中森 裕之, 内藤 清惟, 堀井 和広, 椎名 貴彦, 志水 泰武   ラットにおける脊髄のセロトニン受容体を介した延髄縫線核群による大腸運動制御  

    日本獣医学会学術集会講演要旨集  2017.8  (公社)日本獣医学会

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    Event date: 2017.8

  • Naitou Kiyotada, Nakamori Hiroyuki, Shiina Takahiko, Sano Yuuki, Shimaoka Hiroki, Horii Kazuhiro, Shimizu Yasutake   ラットの脊髄排便中枢に作用する神経伝達物質の同定(Identification of neurotransmitters acting on the spinal defecation center in rats)  

    日本自律神経学会総会プログラム・抄録集  2017.8  日本自律神経学会

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    Event date: 2017.8

  • Nakamori Hroyuki, Naitou Kiyotada, Sano Yuuki, Shimaoka Hiroki, Horii Kazuhiro, Shiina Takahiko, Shimizu Yasutake   ラットの腰仙髄排便中枢のセロトニンが結腸直腸運動を制御する(Serotonin in the lumbosacral defecation center regulates colorectal motility in rats)  

    日本自律神経学会総会プログラム・抄録集  2017.8  日本自律神経学会

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    Event date: 2017.8

  • 澤田 梨花, 内藤 清惟, 中森 裕之, 堀井 有希, 島岡 弘樹, 堀井 和広, 椎名 貴彦, 志水 泰武   ラット結直腸における部位間相互作用による蠕動運動調節  

    日本獣医学会学術集会講演要旨集  2017.8  (公社)日本獣医学会

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    Event date: 2017.8

  • 椎名 貴彦, 嶋 剛士, 堀井 和広, 大橋 錬, 内藤 清惟, 中森 裕之, 堀井 有希, 島岡 弘樹, 志水 泰武   ラット食道横紋筋運動の制御におけるカプサイシン感受性内在神経回路の役割  

    日本獣医学会学術集会講演要旨集  2017.8  (公社)日本獣医学会

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    Event date: 2017.8

  • Horii Kazuhiro, Shiina Takahiko, Naitou Kiyotada, Nakamori Hiroyuki, Sano Yuuki, Shimaoka Hiroki, Shimizu Yasutake   ラット食道蠕動の中枢メカニズムを調べるために有用な新しいin vivo手法(A novel in vivo method is useful for investigating central mechanisms of esophageal peristalsis in rats)  

    日本自律神経学会総会プログラム・抄録集  2017.8  日本自律神経学会

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    Event date: 2017.8

  • 内藤 清惟, 中森 裕之, 堀井 和広, 椎名 貴彦, 志水 泰武   脊髄排便中枢に着目した排便障害の病態メカニズムの解明  

    日本病態生理学会雑誌  2017.7  日本病態生理学会

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    Event date: 2017.7

  • 椎名 貴彦, 嶋 剛士, 堀井 和広, 大橋 錬, 内藤 清惟, 中森 裕之, 堀井 有希, 島岡 弘樹, 志水 泰武   カプサイシン感受性局所神経回路によるラット食道横紋筋運動の調節  

    日本病態生理学会雑誌  2017.7  日本病態生理学会

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    Event date: 2017.7

  • 中森 裕之, 内藤 清惟, 堀井 和広, 椎名 貴彦, 志水 泰武   ラット延髄縫線核群による脊髄排便中枢を介した大腸運動制御機構  

    日本病態生理学会雑誌  2017.7  日本病態生理学会

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    Event date: 2017.7

  • 堀井 和広, 中森 裕之, 内藤 清惟, 椎名 貴彦, 志水 泰武   ラット食道横紋筋の運動制御に対するカリウムチャネルの関与  

    日本病態生理学会雑誌  2017.7  日本病態生理学会

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    Event date: 2017.7

  • Sawada Rika, Naitou Kiyotada, Nakamori Hiroyuki, Sano Yuuki, Shimaoka Hiroki, Shiina Takahiko, Shimizu Yasutake   結直腸の糞塊は、ラットにおいてその上下の部位の運動に異なる影響を与える(Fecal pellet at a specific part of the colorectum may differentially affect propulsive motility in upstream and downstream segments in rats)  

    The Journal of Physiological Sciences  2017.3  (一社)日本生理学会

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    Event date: 2017.3

  • Shimaoka Hiroki, Kawaguchi Takayuki, Sasaki Kahori, Sano Yuuki, Naitou Kiyotada, Nakamori Hiroyuki, Shiina Takahiko, Shimizu Yasutake   ラットにおける冬眠様低体温誘導法の確立(Establishment of methods for inducing hibernation-like hypothermia in rats)  

    The Journal of Physiological Sciences  2017.3  (一社)日本生理学会

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    Event date: 2017.3

  • Horii Kazuhiro, Shiina Takahiko, Naitou Kiyotada, Nakamori Hiroyuki, Sano Yuuki, Shimaoka Hiroki, Shimizu Yasutake   ラット食道蠕動運動を評価するための新規in vivo実験法の開発(A novel method for evaluating esophageal peristalsis in vivo in rats)  

    The Journal of Physiological Sciences  2017.3  (一社)日本生理学会

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    Event date: 2017.3

  • 佐野 有希, 島岡 弘樹, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   非冬眠動物におけるcold-inducible RNA-binding proteinの発現調節  

    日本生理学雑誌  2017.2  (一社)日本生理学会

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    Event date: 2017.2

  • 内藤 清惟, 中森 裕之, 佐野 有希, 島岡 弘樹, 椎名 貴彦, 志水 泰武   中枢神経系による排便制御における下行性モノアミン神経経路の関与  

    日本生理学雑誌  2017.2  (一社)日本生理学会

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    Event date: 2017.2

  • 松山 勇人, 内藤 清惟, 和田 善明, 永野 宏, 齋藤 正一郎, 酒井 洋樹, 棚橋 靖行, 北澤 多喜雄, 小森 成一, 海野 年弘   ムスカリン受容体を介した胃粘膜細胞の分化・増殖制御  

    日本獣医学会学術集会講演要旨集  2016.8  (公社)日本獣医学会

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    Event date: 2016.8

    Language:Japanese  

  • 堀井 和広, 内藤 清惟, 中森 裕之, 佐野 有希, 島岡 弘樹, 椎名 貴彦, 志水 泰武   食物移送様式を評価できる新規in vivo実験系によるラット食道蠕運動の制御機構の解析  

    日本獣医学会学術集会講演要旨集  2016.8  (公社)日本獣医学会

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    Event date: 2016.8

    Language:Japanese  

  • 佐野 有希, 島岡 弘樹, 服部 峻佑, 吉田 侑真, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   非冬眠動物におけるcold-inducible RNA-binding protein(CIRP)の冬眠様スプライシング調節の誘導  

    日本獣医学会学術集会講演要旨集  2016.8  (公社)日本獣医学会

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    Event date: 2016.8

    Language:Japanese  

  • 服部 峻佑, 佐野 有希, 島岡 弘樹, 内藤 清惟, 中森 裕之, 中川 賢人, 岡田 和真, 伊藤 直人, 杉山 誠, 椎名 貴彦, 志水 泰武   狂犬病ウイルス感染マウスの症状に対する低体温の効果  

    日本獣医学会学術集会講演要旨集  2016.8  (公社)日本獣医学会

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    Event date: 2016.8

    Language:Japanese  

  • 島岡 弘樹, 内藤 清惟, 中森 裕之, 佐野 有希, 椎名 貴彦, 志水 泰武   哺乳動物の低体温耐性に対するTRPV1の関与  

    日本獣医学会学術集会講演要旨集  2016.8  (公社)日本獣医学会

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    Event date: 2016.8

    Language:Japanese  

  • 江原 優花, 中森 裕之, 内藤 清惟, 佐野 有希, 島岡 弘樹, 椎名 貴彦, 志水 泰武   侵害刺激によるラット大腸運動の亢進作用における性差  

    日本獣医学会学術集会講演要旨集  2016.8  (公社)日本獣医学会

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    Event date: 2016.8

    Language:Japanese  

  • 中森 裕之, 内藤 清惟, 佐野 有希, 島岡 弘樹, 椎名 貴彦, 志水 泰武   ラット脊髄排便中枢におけるモノアミン神経伝達物質の相互作用  

    日本獣医学会学術集会講演要旨集  2016.8  (公社)日本獣医学会

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    Event date: 2016.8

    Language:Japanese  

  • 中森 裕之, 内藤 清惟, 佐野 有希, 島岡 弘樹, 椎名 貴彦, 志水 泰武   ラット大腸運動制御における脊髄モノアミン神経伝達物質の相互作用  

    日本病態生理学会雑誌  2016.7  日本病態生理学会

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    Event date: 2016.7

    Language:Japanese  

  • 堀井 和広, 内藤 清惟, 中森 裕之, 佐野 有希, 島岡 弘樹, 椎名 貴彦, 志水 泰武   食道蠕動運動における、食物移送機能の制御機構解析  

    日本病態生理学会雑誌  2016.7  日本病態生理学会

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    Event date: 2016.7

    Language:Japanese  

  • 佐野 有希, 島岡 弘樹, 服部 峻佑, 吉田 侑真, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   非冬眠動物におけるcold-inducible RNA-binding proteinの冬眠様発現調節の誘導  

    日本病態生理学会雑誌  2016.7  日本病態生理学会

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    Event date: 2016.7

    Language:Japanese  

  • 島岡 弘樹, 佐野 有希, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   哺乳動物における低体温誘導法の確立  

    日本病態生理学会雑誌  2016.7  日本病態生理学会

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    Event date: 2016.7

    Language:Japanese  

  • 椎名 貴彦, 嶋 剛士, 内藤 清惟, 中森 裕之, 佐野 有希, 堀井 和広, 志水 泰武   ATPによるラット食道運動の調節機構  

    日本生理学雑誌  2016.3  (一社)日本生理学会

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    Event date: 2016.3

    Language:Japanese  

  • Horii Kazuhiro, Shiina Takahiko, Naitou Kiyotada, Nakamori Hiroyuki, Sano Yuuki, Shimizu Yasutake   カリウムチャネルによるラット食道横紋筋運動の制御(Potassium channels contribute to motor regulation of esophageal striated muscle in rats)  

    The Journal of Physiological Sciences  2016.3  (一社)日本生理学会

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    Event date: 2016.3

    Language:English  

  • 佐野 有希, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   シリアンハムスターにおけるcold-inducible RNA-binding proteinの発現調節機構  

    日本生理学雑誌  2016.3  (一社)日本生理学会

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    Event date: 2016.3

    Language:Japanese  

  • 内藤 清惟, 中森 裕之, 佐野 有希, 椎名 貴彦, 志水 泰武   ノルアドレナリンによる脊髄排便中枢の制御メカニズム  

    日本生理学雑誌  2016.3  (一社)日本生理学会

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    Event date: 2016.3

    Language:Japanese  

  • Nakamori Hiroyuki, Naitou Kiyotada, Sano Yuuki, Shiina Takahiko, Shimizu Yasutake   脊髄のセロトニンによるラット大腸運動制御の作用機序(Mechanism of the colokinetic effect of spinal serotonin in rats)  

    The Journal of Physiological Sciences  2016.3  (一社)日本生理学会

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    Event date: 2016.3

    Language:English  

  • Shiina Takahiko, Gurung Yam, Naitou Kiyotada, Nakamori Hiroyuki, Sano Yuuki, Horii Kazuhiro, Shimizu Yasutake   消化管の修復と再生 大腸における炎症の発生と回復に伴う神経筋伝達機構の変化(Restoration and Regeneration of the Gastrointestinal Tract Alteration of neuromuscular transmissions in the colon following the onset and resolution of inflammation)  

    The Journal of Physiological Sciences  2016.3  (一社)日本生理学会

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    Event date: 2016.3

    Language:English  

  • Sano Yuuki, Naitou Kiyotada, Nakamori Hiroyuki, Shiina Takahiko, Shimizu Yasutake   冬眠中のシリアンハムスターにおけるcold-inducible RNA-binding protein(CIRP) mRNAのスプライシング調節(Splicing regulation of cold-inducible RNA-binding protein(CIRP) mRNA in hibernating Syrian hamsters)  

    The Journal of Physiological Sciences  2016.3  (一社)日本生理学会

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    Event date: 2016.3

    Language:English  

  • 佐野 有希, 吉田 侑真, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   シリアンハムスターにおける低温ショックタンパク質遺伝子の冬眠時特異的な発現調節機構  

    日本獣医学会学術集会講演要旨集  2015.8  (公社)日本獣医学会

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    Event date: 2015.8

    Language:Japanese  

  • 加戸 くるみ, 内藤 清惟, 中森 裕之, 佐野 有希, 椎名 貴彦, 志水 泰武   ラット大腸管腔内カプサイシン投与による大腸運動亢進反応と下行性疼痛抑制系の関連  

    日本獣医学会学術集会講演要旨集  2015.8  (公社)日本獣医学会

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    Event date: 2015.8

    Language:Japanese  

  • 志水 泰武, 内藤 清惟, 中森 裕之, 佐野 有希, 椎名 貴彦   摂食・代謝・エネルギー調整機構研究の新たな展開 中枢を介する消化管運動の制御機構  

    日本獣医学会学術集会講演要旨集  2015.8  (公社)日本獣医学会

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    Event date: 2015.8

    Language:Japanese  

  • 吉田 侑真, 佐野 有希, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   冬眠動物であるシリアンハムスターの持つ低温耐性は冬眠時特有のものなのか  

    日本獣医学会学術集会講演要旨集  2015.8  (公社)日本獣医学会

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    Event date: 2015.8

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  • 椎名 貴彦, 嶋 剛士, 内藤 清惟, 中森 裕之, 佐野 有希, 志水 泰武   ラット食道運動に対するプリン作動性調節機構  

    日本獣医学会学術集会講演要旨集  2015.8  (公社)日本獣医学会

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    Event date: 2015.8

    Language:Japanese  

  • 佐野 有希, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   シリアンハムスターにおける冬眠特異的なcold-inducible RNA-binding proteinの発現調節  

    日本病態生理学会雑誌  2015.7  日本病態生理学会

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    Event date: 2015.7

    Language:Japanese  

  • 椎名 貴彦, 嶋 剛士, 内藤 清惟, 中森 裕之, 佐野 有希, 志水 泰武   プリン作動性機構によるラット食道運動の調節  

    日本病態生理学会雑誌  2015.7  日本病態生理学会

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    Event date: 2015.7

    Language:Japanese  

  • 椎名 貴彦, 内藤 清惟, 中森 裕之, 志水 泰武   スンクス食道平滑筋運動におけるセロトニンの関与  

    日本生理学雑誌  2015.5  (一社)日本生理学会

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    Event date: 2015.5

    Language:Japanese  

  • Siina Takahiko, Naitou Kiyotada, Nakamori Hiroyuki, Sano Yuuki, Ikeda Azusa, Hirayama Haruko, Shimizu Yasutake   ペプチドとアミンを介した脳腸相関 脊髄を介した結腸直腸運動の調節におけるペプチドとアミンの役割(Brain-gut association via peptides and amines Roles of peptides and amines in the regulation of the colorectal motility via the spinal cord)  

    The Journal of Physiological Sciences  2015.3  (一社)日本生理学会

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    Event date: 2015.3

    Language:English  

  • Shiina Takahiko, Naitou Kiyotada, Nakamori Hiroyuki, Shimizu Yasutake   ラットにおいて硫化水素は食道横紋筋の運動活性を阻害する(Hydrogen sulfide inhibits motor activity of esophageal striated muscle in rats)  

    The Journal of Physiological Sciences  2015.3  (一社)日本生理学会

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    Event date: 2015.3

    Language:English  

  • Naitou Kiyotada, Kato Kurumi, Nakamori Hiroyuki, Sano Yuuki, Shiina Takahiko, Shimizu Yasutake   ラットにおいてcapsaicinの髄腔内投与は大腸運動を促進する(Intrathecal administration of capsaicin enhances the colorectal motility in rats)  

    The Journal of Physiological Sciences  2015.3  (一社)日本生理学会

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    Event date: 2015.3

    Language:English  

  • 椎名 貴彦, 内藤 清惟, 中森 裕之, 志水 泰武   スンクス食道運動に対するセロトニンの役割  

    日本獣医学会学術集会講演要旨集  2014.8  (公社)日本獣医学会

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    Event date: 2014.8

    Language:Japanese  

  • 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   脊髄腰仙髄部における大腸運動制御メカニズムへのノルアドレナリンの関与  

    日本獣医学会学術集会講演要旨集  2014.8  (公社)日本獣医学会

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    Event date: 2014.8

    Language:Japanese  

  • 佐野 有希, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   冬眠時のシリアンハムスターにおける低温ショックタンパク質遺伝子の発現  

    日本獣医学会学術集会講演要旨集  2014.8  (公社)日本獣医学会

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    Event date: 2014.8

    Language:Japanese  

  • 中森 裕之, 内藤 清惟, 椎名 貴彦, 志水 泰武   ラット脊髄排便中枢を介した大腸運動制御に関するセロトニンの作用機序  

    日本獣医学会学術集会講演要旨集  2014.8  (公社)日本獣医学会

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    Event date: 2014.8

    Language:Japanese  

  • 野末 祐大, 池田 あずさ, 中森 裕之, 内藤 清惟, 椎名 貴彦, 志水 泰武   ドパミンによる脊髄排便中枢を介したラット大腸運動亢進の作用経路  

    日本獣医学会学術集会講演要旨集  2014.8  (公社)日本獣医学会

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    Event date: 2014.8

    Language:Japanese  

  • 佐野 有希, 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   シリアンハムスターにおける冬眠特異的な遺伝子発現  

    日本病態生理学会雑誌  2014.7  日本病態生理学会

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    Event date: 2014.7

    Language:Japanese  

  • 内藤 清惟, 中森 裕之, 椎名 貴彦, 志水 泰武   脊髄排便中枢におけるノルアドレナリンの作用  

    日本病態生理学会雑誌  2014.7  日本病態生理学会

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    Event date: 2014.7

    Language:Japanese  

  • 中森 裕之, 内藤 清惟, 椎名 貴彦, 志水 泰武   ラットの脊髄排便中枢に存在するセロトニン応答性神経の作用経路  

    日本病態生理学会雑誌  2014.7  日本病態生理学会

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    Event date: 2014.7

    Language:Japanese  

  • Nakamori Hiroyuki, Naitou Kiyotada, Shiina Takahiko, Shimizu Yasutake   セロトニンはラット腰仙部排便中枢の活性化を介して結腸直腸運動性を増大させる(Serotonin enhances colorectum motility through an activation of lumbosacral defecation center in rats)  

    The Journal of Physiological Sciences  2014.3  (一社)日本生理学会

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    Event date: 2014.3

    Language:English  

  • 椎名 貴彦, 内藤 清惟, 中森 裕之, 志水 泰武   ラット食道横紋筋運動の制御における硫化水素の役割  

    日本生理学雑誌  2014.3  (一社)日本生理学会

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    Event date: 2014.3

    Language:Japanese  

  • Naitou Kiyotada, Sugita Riko, Nakamori Hiroyuki, Shiina Takahiko, Shimizu Yasutake   ラット結腸直腸運動性の促進に関与する腰仙部排便中枢におけるグレリン感受性ニューロンの特性(Characterization of ghrelin-sensitive neurons in the lumbosacral defecation center that are associated with facilitation of colorectal motility in rats)  

    The Journal of Physiological Sciences  2014.3  (一社)日本生理学会

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    Event date: 2014.3

    Language:English  

  • Shiina Takahiko, Shima Takeshi, Naitou Kiyotada, Nakamori Hiroyuki, Shimizu Yasutake   ラットにおける食道蠕動はカプサイシン感受性神経回路により調節される(Esophageal peristalsis is regulated by capsaicin-sensitive intrinsic neural circuit in rats)  

    The Journal of Physiological Sciences  2014.3  (一社)日本生理学会

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    Event date: 2014.3

    Language:English  

  • 志水 泰武, 池田 あずさ, 中森 裕之, 内藤 清惟, 椎名 貴彦   ドパミンによる脊髄排便中枢を介したラット大腸運動の制御  

    日本生理学雑誌  2014.3  (一社)日本生理学会

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    Event date: 2014.3

    Language:Japanese  

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Awards

  • ベストティーチャー賞

    2023.8   鹿児島大学  

  • 2021-2022年度日本獣医学会 生理学・生化学分科会奨励賞

    2021.9   日本獣医学会生理学・生化学分科会  

  • 獣医学奨励賞

    2021.9   日本獣医学会  

  • 奨励賞

    2017.8   日本病態生理学会  

  • 研究科長表彰

    2016.9   岐阜大学大学院連合獣医学研究科  

Research Projects

  • 神経科学的アプローチによる狂犬病の病態の「本質」の解明

    2024.4 - 2028.3

    日本学術振興会  科学研究費助成事業   基盤研究(B)

    伊藤直人

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    Authorship:Coinvestigator(s)  Grant type:Competitive

  • 匂いによる排便制御メカニズムの解明

    Grant number:23K18081  2023.6 - 2025.3

    日本学術振興会  科学研究費助成事業   挑戦的研究(萌芽)

    内藤 清惟

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    Authorship:Principal investigator  Grant type:Competitive

  • 脳と大腸を機能連関させる神経回路のリモデリングとその排便異常への関与

    Grant number:23H00360  2023.4 - 2027.3

    日本学術振興会  科学研究費助成事業   基盤研究(A)

    志水 泰武

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    Authorship:Coinvestigator(s)  Grant type:Competitive

    Grant amount:\46800000 ( Direct Cost: \36000000 、 Indirect Cost:\10800000 )

  • カイコ昆虫工場モダリティによる低価格な純国産組換えワクチンに関する研究開発

    2022.12

    国立研究開発法人日本医療研究開発機構  ワクチン・新規モダリティ研究開発事業 

    日下部 宜宏

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    Authorship:Coinvestigator(s)  Grant type:Competitive

  • Developing a Novel Eating Vaccine with Silkworms

    Grant number:22H02501  2022.4 - 2027.3

    Japan Society for the Promotion of Science  Grants-in-Aid for Scientific Research  Grant-in-Aid for Scientific Research (B)

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    Authorship:Coinvestigator(s)  Grant type:Competitive

    Grant amount:\17160000 ( Direct Cost: \13200000 、 Indirect Cost:\3960000 )

  • 狂犬病ウイルスと組織透明化を用いた排便制御に関わる中枢神経の網羅的解析

    Grant number:22H02523  2022.4 - 2025.3

    日本学術振興会  科学研究費助成事業   基盤研究(B)

    内藤 清惟

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    Authorship:Principal investigator  Grant type:Competitive

    Grant amount:\17550000 ( Direct Cost: \13500000 、 Indirect Cost:\4050000 )

  • 経口ワクチンの実用化に向けた食品化学と消化器生理学の融合研究

    2021.11 - 2022.3

    鹿児島大学  異分野融合研究プロジェクト創出研究助成事業 

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    Authorship:Principal investigator  Grant type:Competitive

    Grant amount:\1000000 ( Direct Cost: \1000000 )

  • アンヒドロフルクトースとでん粉鍼を用いた畜産における生産性向上と品質向上技術の開発

    2021.6 - 2022.3

    九州オープンイノベーションセンター(KOIC)  JKA「自転車等機械振興事業に関する補助金」 

  • 生後感染型アカバネウイルスの神経病原性におけるNSs蛋白質の役割

    2020.4

  • 中枢神経系による排便制御に関わる脳領域および神経回路の特定とその機能の解析

    Grant number:20K16120  2020.4 - 2023.3

    日本学術振興会  科学研究費助成事業   若手研究

    内藤 清惟

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    Authorship:Principal investigator  Grant type:Competitive

    Grant amount:\4160000 ( Direct Cost: \3200000 、 Indirect Cost:\960000 )

    近年、ストレスによる排便障害が大きな問題となっているが、その病態は明らかになっていない。その理由として、中枢神経系による排便制御の仕組みが解明されていないことが挙げられる。特に、脳の「どの領域」の神経が「どのような神経回路」によって排便を制御しているのか、という基礎的な情報が圧倒的に不足している。そこで本研究では、これまで脊髄に対して行ってきた研究によって得られた知見を基に、排便制御に関わる脳領域と、脳と脊髄をつなぐ神経回路の特定を行い、中枢神経系による排便制御システムの解明を目指す。本研究によって、これまで脳または大腸に対して行われていた研究を、「脳-脊髄-大腸」という制御システム全体としてとらえ、この分野の研究を飛躍的に進展に貢献したい。
    本年度は、本研究の基盤となる逆行性トレーサーを用いた排便制御に関わる脳領域の特定を行なった。感染した神経に蛍光タンパク質を発現させるアデノ随伴ウイルスベクターを、脊髄の排便中枢が存在する腰仙髄部に投与し、脊髄排便中枢に投射する神経を蛍光タンパク質で標識した。組織切片を作成し、蛍光タンパク質で標識された神経が存在する脳の領域を検索した。さらに、免疫蛍光染色を行うことで、蛍光タンパク質で標識された神経の性質を検討した。また、脊髄で作用する神経伝達物質の検索およびその作用メカニズムの検討を行なった。これらの結果を、英文の科学論文および国内学会にて発表した。

  • 中枢神経による大腸運動制御機構と排便異常に認められる性差のメカニズム解明

    Grant number:20H03148  2020.4 - 2023.3

    日本学術振興会  科学研究費助成事業   基盤研究(B)

    志水 泰武, 内藤 清惟, 山中 章弘

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    Authorship:Coinvestigator(s)  Grant type:Competitive

    Grant amount:\17680000 ( Direct Cost: \13600000 、 Indirect Cost:\4080000 )

    ストレスに起因する過敏性腸症候群(IBS)において、症状に性差が認められ、男性は下痢、女性は便秘が多いことが知られている。このような性差が認められる理由は不明である。研究代表者は、脊髄の排便中枢が大腸運動の制御に重要であること、脳と脊髄の連絡に下行性疼痛抑制経路が関与することを明らかにしてきた。これらの成果を基盤として、本研究ではストレス性の排便異常に明確な性差(男性は下痢、女性は便秘)が発生する機序を解明することを目的とする。この目的を達成するための課題として、1)正常な状態で、大腸運動を調節する神経回路に性差があるか解明する、2)痛覚過敏を誘発し、大腸運動制御系に起こる変化に性差があるか解明する、3)特定の神経の活性化/沈静化が、大腸運動異常を是正するか雌雄それぞれで明確にする、の3つを設定している。初年度は、主に1)の課題を追究した。
    実験にはラットを用い、大腸運動の評価には研究代表者らが確立したin vivoの実験系を用いた。オスでは大腸内にカプサイシンを投与して痛み刺激を与えると、脳から脊髄に投射する下行性疼痛抑制経路が活性化され、脊髄に放出されるドパミンやセロトニンが骨盤神経を介して大腸運動を亢進さた。一方、メスでは同様の刺激を加えても大腸運動が亢進しなかった。この性差の機序を検討した結果、メスにおいて大腸への痛み刺激に応答する下行性神経は、セロトニン神経とGABA神経であることが明らかとなった。脊髄で放出されるGABAが骨盤神経を活性化するモノアミンの作用に拮抗するために、メスでは大腸運動の亢進に至らないことが示された。この結果は、アデノ随伴ウイルスベクターによるチャネルロドプシンあるいは人工受容体の導入実験によってもサポートされ、正常な状態で大腸運動を調節する神経回路に性差があることを証明できた。第1段階の目標が達成できたと言える。

  • 狂犬病ウイルスM蛋白質95位のアミノ酸はストレス顆粒形成に関与する

    2020.4 - 2022.9

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    Authorship:Coinvestigator(s) 

  • 匂いによる排便促進作用の生理的メカニズムの解明

    2020.3

    民間財団等  公益財団法人ロッテ財団第7回(2020年度)研究助成事業「奨励研究助成(A)」 

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    Grant type:Competitive

  • 中枢神経による排便制御における脊髄の神経回路の解析

    2020.3 - 2021.3

    民間財団等  上原記念生命科学財団 2019年度研究奨励金 

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    Grant type:Competitive

  • Searches for neurotransmitters in the spinal defecation center

    Grant number:17K15557  2017.4 - 2020.3

    Japan Society for the Promotion of Science  Grants-in-Aid for Scientific Research   Grant-in-Aid for Young Scientists (B)

    Naitou Kiyotada

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    Authorship:Principal investigator  Grant type:Competitive

    Grant amount:\4160000 ( Direct Cost: \3200000 、 Indirect Cost:\960000 )

    In this study, searches for the neurotransmitter, which acts in the spinal defecation center, were performed. As results, we found that serotonin, somatostatin, GABA and alpha-melanocyte-stimulating hormone act in the spinal cord and affect colorectal motility. We performed further investigations about effects of serotonin, somatostatin and alpha-melanocyte-stimulating hormone. These results were published as scientific papers and presented at academic conferences.

  • 下降性モノアミン神経による排便制御メカニズムの解明

    Grant number:16J03278  2016.4 - 2018.3

    日本学術振興会  科学研究費助成事業   特別研究員奨励費

    内藤 清惟

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    Authorship:Principal investigator  Grant type:Competitive

    Grant amount:\1300000 ( Direct Cost: \1300000 )

    これまでの研究から、大腸管腔内に投与したカプサイシンによって大腸運動が亢進することが明らかとなり、この反応が脊髄と脳を介していること、大腸管腔内においてTRPV1を介して作用すること、脊髄排便中枢にあるドパミンおよびセロトニン作動性神経を介していることを示してきた。
    本年度は、脊髄排便中枢においてモノアミン神経伝達物質の分泌量が増加しているかを、マイクロダイアリシス法を用いて検討した。脊髄腰仙髄部における麻酔下および意識下でのマイクロダイアリシスを行う方法を確立し、大腸管腔内へのカプサイシン投与によって、セロトニンの量が増加することを見出した。
    また、脳幹部の下行性疼痛抑制系に関わるモノアミン神経核を電気刺激し、大腸運動が亢進するかを検討し、延髄縫線核群の電気刺激によって大腸運動が亢進し、この反応がセロトニン受容体の拮抗薬の脊髄排便中枢への投与によって阻害されることを確かめた。
    本年度は、研究成果を公表するために、英文科学論文を専門分野の科学雑誌に投稿するとともに、学会に積極的に参加した。延髄縫線核群の電気刺激によって大腸運動亢進に関する実験結果をAmerican journal of physiology. Gastrointestinal and liver physiology誌において、英文の原著論文として発表している。また、カプサイシンによる大腸運動亢進メカニズムに関する研究の実験結果についても、英文の原著論文として現在投稿中である。さらに、本研究の結果を第27回日本病態生理学会大会とThe Internationnal Society for Autonomic Neuroscience 2017にて発表し、本研究が第27回日本病態生理学会大会において奨励賞を受賞した。

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Teaching Experience

  • 情報リテラシー演習

    2021.4
    Institution:鹿児島大学

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    Level:Undergraduate (specialized) 

  • 動物の病気

    2020.4
    Institution:鹿児島大学

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    Level:Undergraduate (liberal arts) 

  • 野生動物学

    2019.4
    Institution:鹿児島大学

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    Level:Undergraduate (specialized) 

  • 生物学実験

    2019.4
    Institution:鹿児島大学

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    Level:Undergraduate (specialized) 

  • 実験動物機能学実習

    2019.4

  • 獣医生理学A

    2018.4
    Institution:鹿児島大学

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    Level:Undergraduate (specialized) 

  • 専攻演習

    2018.4
    Institution:鹿児島大学

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    Level:Undergraduate (specialized) 

  • 獣医生理学B

    2017.11
    Institution:鹿児島大学

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    Level:Undergraduate (specialized) 

  • 獣医生理学実習

    2017.11
    Institution:鹿児島大学

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    Level:Undergraduate (specialized) 

  • 家畜生理学

    2017.11
    Institution:鹿児島大学

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    Level:Undergraduate (specialized) 

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Social Activities

  • 研究におけるウイルスの利用 ―排便制御メカニズムの解明を目指してー

    Role(s): Appearance, Lecturer

    日本病態生理学会  市民公開講座「感染症の病態生理」  2022.8

  • 第1回秋季市民公開講座 病気とは何か? ー生理学からみた病気の捉え方ー

    Role(s): Appearance

    鹿児島大学共同獣医学部  第1回秋季市民公開講座  2021.9 - 2021.10

  • 病気とはなにか? -生理学からみた病気の捉え方-

    Role(s): Appearance

    鹿児島大学共同獣医学部  第一回秋季市民公開講座  2021.9 - 2021.10

  • Studies on Regulatory Mechanisms of Colorectal Motility through the Spinal Defecation Center

    Role(s): Appearance, Lecturer, Advisor

    2020.8 - 2020.9

  • 令和2年度岐阜大学大学院共同獣医学研究科学際領域特別演習(特別講演)

    Role(s): Lecturer, Advisor

    2020.8 - 2020.9

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    Audience: Graduate students

    Type:Lecture

  • 2019年度共同獣医学部オープンキャンパス体験授業

    Role(s): Lecturer, Demonstrator

    2019.9

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    Audience: High school students, Guardians

    Type:University open house

  • 2018年度共同獣医学部オープンキャンパス体験授業

    Role(s): Lecturer, Demonstrator

    2018.9

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    Audience: High school students, Guardians

    Type:Visiting lecture

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