Visceral thermoreceptors that modify thermoregulatory responses are widely accepted in animal but not human thermoregulation models. Recently, we have provided evidence of viscerally‐mediated sweating alterations in humans during exercise brought about by warm and cool fluid ingestion. In the present study, we characterize the modification of shivering and whole‐body thermal sensation during cold stress following the administration of a graded thermal stimuli delivered to the stomach via fluid ingestion at 52, 37, 22 and 7°C. Despite no differences in core and skin temperature, fluid ingestion at 52°C rapidly decreased shivering and sensations of cold compared to 37°C, whereas fluid ingestion at 22 and 7°C led to equivalent increases in these responses. Warm and cold fluid ingestion independently modifies cold defence thermoeffector responses, supporting the presence of visceral thermoreceptors in humans. However, the cold‐defence thermoeffector response patterns differed from previously identified hot‐defence thermoeffectors.
{"title":"Evidence of viscerally‐mediated cold‐defence thermoeffector responses in man","authors":"N. Morris, D. Filingeri, M. Halaki, O. Jay","doi":"10.1113/JP273052","DOIUrl":"https://doi.org/10.1113/JP273052","url":null,"abstract":"Visceral thermoreceptors that modify thermoregulatory responses are widely accepted in animal but not human thermoregulation models. Recently, we have provided evidence of viscerally‐mediated sweating alterations in humans during exercise brought about by warm and cool fluid ingestion. In the present study, we characterize the modification of shivering and whole‐body thermal sensation during cold stress following the administration of a graded thermal stimuli delivered to the stomach via fluid ingestion at 52, 37, 22 and 7°C. Despite no differences in core and skin temperature, fluid ingestion at 52°C rapidly decreased shivering and sensations of cold compared to 37°C, whereas fluid ingestion at 22 and 7°C led to equivalent increases in these responses. Warm and cold fluid ingestion independently modifies cold defence thermoeffector responses, supporting the presence of visceral thermoreceptors in humans. However, the cold‐defence thermoeffector response patterns differed from previously identified hot‐defence thermoeffectors.","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"24 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2017-02-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"75239705","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
The lateral habenula (LHb) has been implicated in regulation of drug‐seeking behaviours through aversion‐mediated learning. In this study, we recorded neuronal activity in the LHb of rats during an operant task before and after ethanol‐induced conditioned taste aversion (CTA) to saccharin. Ethanol‐induced CTA caused significantly higher baseline firing rates in LHb neurons, as well as elevated firing rates in response to cue presentation, lever press and saccharin taste. In a separate cohort of rats, we found that bilateral LHb lesions blocked ethanol‐induced CTA. Our results strongly suggest that excitation of LHb neurons is required for ethanol‐induced CTA, and point towards a mechanism through which LHb firing may regulate voluntary ethanol consumption.
{"title":"Excitation of lateral habenula neurons as a neural mechanism underlying ethanol‐induced conditioned taste aversion","authors":"Shashank Tandon, K. Keefe, S. Taha","doi":"10.1113/JP272994","DOIUrl":"https://doi.org/10.1113/JP272994","url":null,"abstract":"The lateral habenula (LHb) has been implicated in regulation of drug‐seeking behaviours through aversion‐mediated learning. In this study, we recorded neuronal activity in the LHb of rats during an operant task before and after ethanol‐induced conditioned taste aversion (CTA) to saccharin. Ethanol‐induced CTA caused significantly higher baseline firing rates in LHb neurons, as well as elevated firing rates in response to cue presentation, lever press and saccharin taste. In a separate cohort of rats, we found that bilateral LHb lesions blocked ethanol‐induced CTA. Our results strongly suggest that excitation of LHb neurons is required for ethanol‐induced CTA, and point towards a mechanism through which LHb firing may regulate voluntary ethanol consumption.","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"40 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2017-02-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"87261114","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
D. Hwee, A. Cheng, J. Hartman, A. Hinken, Kenneth H. Lee, Nickie Durham, A. Russell, F. Malik, H. Westerblad, J. Jasper
We report that the small molecule CK‐2066260 selectively slows the off‐rate of Ca2+ from fast skeletal muscle troponin, leading to increased myofibrillar Ca2+ sensitivity in fast skeletal muscle. Rodents dosed with CK‐2066260 show increased hindlimb muscle force and power in response to submaximal rates of nerve stimulation in situ. CK‐2066260 has no effect on free cytosolic [Ca2+] during contractions of isolated muscle fibres. We conclude that fast skeletal muscle troponin sensitizers constitute a potential therapy to address an unmet need of improving muscle function in conditions of weakness and premature muscle fatigue.
{"title":"The Ca2+ sensitizer CK‐2066260 increases myofibrillar Ca2+ sensitivity and submaximal force selectively in fast skeletal muscle","authors":"D. Hwee, A. Cheng, J. Hartman, A. Hinken, Kenneth H. Lee, Nickie Durham, A. Russell, F. Malik, H. Westerblad, J. Jasper","doi":"10.1113/JP273248","DOIUrl":"https://doi.org/10.1113/JP273248","url":null,"abstract":"We report that the small molecule CK‐2066260 selectively slows the off‐rate of Ca2+ from fast skeletal muscle troponin, leading to increased myofibrillar Ca2+ sensitivity in fast skeletal muscle. Rodents dosed with CK‐2066260 show increased hindlimb muscle force and power in response to submaximal rates of nerve stimulation in situ. CK‐2066260 has no effect on free cytosolic [Ca2+] during contractions of isolated muscle fibres. We conclude that fast skeletal muscle troponin sensitizers constitute a potential therapy to address an unmet need of improving muscle function in conditions of weakness and premature muscle fatigue.","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"202 1","pages":"1657 - 1670"},"PeriodicalIF":0.0,"publicationDate":"2017-01-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"77004457","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Aalkjaer, Christian Aaucci, Angela Abbott, Stephen Ackland, Gareth Adachi-Akahane, Satomi Adams, Gregory Affourtit, Charles Aguilar, Martin Ahern, Gerard Ahmed, Zaghloul Ainslie, Philip Ajijola, Olujimi Akar, Fadi Akk, Gustav Alberici, Luciane Alexander, Barbara Alexander, Lacy Alexander, R. Todd Allen, Charles Allen, David Allen, Paul Allison, Beth Alonso, Jose Manuel Alonso-Vale, Maria Isabel Alper, Seth Altier, Christophe Alway, Stephen Amann, Markus Amarillo, Yimy Amberg, Gregory Ambudkar, Indu Amthor, Helge Andersson, Daniel Andersson, Karl-Erik Andresen, Michael Annunziato, Lucio Antunes, Vagner Apell, Hans-Juergen Apodaca, Gerard Appleyard, Suzanne Arabzadeh, Ehsan Araque, Alfonso Arendt-Nielsen, Lars Armitage, James Armstead, William Armstrong, William Arreola, Jorge Art, Jonathan Artigas, Pablo Ashmore, Jonathan Aslam, Muhammad Atherton, Philip Attwell, David Auerbach, Anthony Averina, Viktoria Avila, Guillermo Avolio, Alberto Awatramani, Gautam Baar, Keith Baccei, Mark Backx, Peter Bækgaard Nielsen, Ole Bagher, Pooneh Baker, Stuart Baker-Herman, Tracy Bakker, Erik Balemba, Onesmo Balestra, Costantino Ballanyi, Klaus Ballard, H. Balog, Edward Banach, Kathrin Bangsbo, Jens Banke, Tue Bannister, Roger Bargas, Jose Barkmeier-Kraemer, Julie Barman, Susan Barnes, Jill Barnes, Matthew Barnes, Steven Barrett-Jolley, Richard Barstow, Tom Barth, Daniel Barton, Elisabeth Barton, Matthias Bassingthwaighte, James Bastian, Amy Bates, David Bates, Jason Batten, T Batterham, Alan Bauer, Anthony Bautista, Diana Bayliss, Douglas Bean, Bruce Beard, Daniel Beart, Philip Beaudin, Andrew Beaumont, Eric Beckel, Jonathan Beckett, Elizabeth Begley, David Behm, David Behnke, Brad Behrendt, Marc Beierlein, Michael Béı̈que, Jean-Claude Belušič, Gregor Benedetti, Fabrizio Bennet, Laura Beraneck, Mathieu Berridge, Michael Bertagnolli, Mariane Bertrand, Daniel Bett, Glenna Bevensee, Mark Beyak, Michael Beyder, Arthur Beyer, Andreas Bezprozvanny, Ilya Bickel, Perry Bie, Peter Bikson, Marom Billups, Brian Binshtok, Alexander Bischofberger, Josef Blaauw, Bert Black, Christopher Blackshaw, Laurence Blain, Grégory Blazev, Ronnie Blevins, James Blikslager, Anthony Blockley, Nicholas Bloodgood, Brenda Bloomfield, Stewart Blouin, Jean-Sébastien Bodine, Sue Bodineau, Laurence Boecker, Henning Boedtkjer, Ebbe Boesmans, Werend Boets, Eef Bogdanova, Anna Boix, Fernando Boje, Trine Bollinger, Lance Bonin, Robert Boonstra, Tjeerd Booth, Frank Borges, Ricardo Boric, Mauricio Bornstein, Joel Boron, Walter Borst, Gerard Bosman, Laurens Bosutti, Alessandra Bottinelli, Roberto Botting, Kimberley Bourinet, Emmanuel Bourque, Charles Bourque, Stephane Boushel, Robert Bowen, T. Scott Bowyer, Susan Boychuk, Jeffery Boyett, Mark Bradding, Peter Brainard, George Brégeon, Jérémy Brewer, Allison Brichta, Alan Brierley, Stuart Brittain, John-Stuart Brooks, Susan
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{"title":"Thank you to our expert Referees","authors":"Christian, Aaucci, Angela, Abbott, Stephen, Ackland, Gareth, Adachi-Akahane, Satomi, Adams, Gregory, Affourtit, Charles, Aguilar, Martin, Ahern, Gérard, Ahmed, Zaghloul, Ainslie, Philip, Ajijola, Olujimi, Akar, Fadi, Akk, Gustav, Alberici, Luciane, Alexander, Barbara, Lacy, R. Todd, Allen, Paul, Allison, Beth, Alonso, José Manuel, Alonso-Vale, María Isabel, Alper, Seth, Altier, Christophe, Alway, Markus, Amarillo, Yimy, Amberg, Ambudkar, Appleyard, Lars, Armitage, James, Armstead, William, Armstrong, Arreola, Jonathan, Artigas, Pablo, Ashmore, Aslam, Muhammad, Atherton, Attwell, David, Auerbach, Anthony, Averina, Viktória, Avila, Guillermo, Avolio, Alberto, Awatramani, Keith, Baccei, Mark, Backx, Ole, Bagher, Kathrin, Bangsbo, Jens, Banke, Tue, Bannister, Matthias, Bassingthwaighte, Jason, Batten, Alan, Bauer, Bautista, Diana, Bayliss, Bruce, Beard, Beaudin, Andrew, Beaumont, Eric, Beckel, Gregor, Benedetti, Laurence, Boecker, Henning, Boedtkjer, Ebbe, Boesmans","doi":"10.1113/JP274039","DOIUrl":"https://doi.org/10.1113/JP274039","url":null,"abstract":"Aalkjaer, Christian Aaucci, Angela Abbott, Stephen Ackland, Gareth Adachi-Akahane, Satomi Adams, Gregory Affourtit, Charles Aguilar, Martin Ahern, Gerard Ahmed, Zaghloul Ainslie, Philip Ajijola, Olujimi Akar, Fadi Akk, Gustav Alberici, Luciane Alexander, Barbara Alexander, Lacy Alexander, R. Todd Allen, Charles Allen, David Allen, Paul Allison, Beth Alonso, Jose Manuel Alonso-Vale, Maria Isabel Alper, Seth Altier, Christophe Alway, Stephen Amann, Markus Amarillo, Yimy Amberg, Gregory Ambudkar, Indu Amthor, Helge Andersson, Daniel Andersson, Karl-Erik Andresen, Michael Annunziato, Lucio Antunes, Vagner Apell, Hans-Juergen Apodaca, Gerard Appleyard, Suzanne Arabzadeh, Ehsan Araque, Alfonso Arendt-Nielsen, Lars Armitage, James Armstead, William Armstrong, William Arreola, Jorge Art, Jonathan Artigas, Pablo Ashmore, Jonathan Aslam, Muhammad Atherton, Philip Attwell, David Auerbach, Anthony Averina, Viktoria Avila, Guillermo Avolio, Alberto Awatramani, Gautam Baar, Keith Baccei, Mark Backx, Peter Bækgaard Nielsen, Ole Bagher, Pooneh Baker, Stuart Baker-Herman, Tracy Bakker, Erik Balemba, Onesmo Balestra, Costantino Ballanyi, Klaus Ballard, H. Balog, Edward Banach, Kathrin Bangsbo, Jens Banke, Tue Bannister, Roger Bargas, Jose Barkmeier-Kraemer, Julie Barman, Susan Barnes, Jill Barnes, Matthew Barnes, Steven Barrett-Jolley, Richard Barstow, Tom Barth, Daniel Barton, Elisabeth Barton, Matthias Bassingthwaighte, James Bastian, Amy Bates, David Bates, Jason Batten, T Batterham, Alan Bauer, Anthony Bautista, Diana Bayliss, Douglas Bean, Bruce Beard, Daniel Beart, Philip Beaudin, Andrew Beaumont, Eric Beckel, Jonathan Beckett, Elizabeth Begley, David Behm, David Behnke, Brad Behrendt, Marc Beierlein, Michael Béı̈que, Jean-Claude Belušič, Gregor Benedetti, Fabrizio Bennet, Laura Beraneck, Mathieu Berridge, Michael Bertagnolli, Mariane Bertrand, Daniel Bett, Glenna Bevensee, Mark Beyak, Michael Beyder, Arthur Beyer, Andreas Bezprozvanny, Ilya Bickel, Perry Bie, Peter Bikson, Marom Billups, Brian Binshtok, Alexander Bischofberger, Josef Blaauw, Bert Black, Christopher Blackshaw, Laurence Blain, Grégory Blazev, Ronnie Blevins, James Blikslager, Anthony Blockley, Nicholas Bloodgood, Brenda Bloomfield, Stewart Blouin, Jean-Sébastien Bodine, Sue Bodineau, Laurence Boecker, Henning Boedtkjer, Ebbe Boesmans, Werend Boets, Eef Bogdanova, Anna Boix, Fernando Boje, Trine Bollinger, Lance Bonin, Robert Boonstra, Tjeerd Booth, Frank Borges, Ricardo Boric, Mauricio Bornstein, Joel Boron, Walter Borst, Gerard Bosman, Laurens Bosutti, Alessandra Bottinelli, Roberto Botting, Kimberley Bourinet, Emmanuel Bourque, Charles Bourque, Stephane Boushel, Robert Bowen, T. Scott Bowyer, Susan Boychuk, Jeffery Boyett, Mark Bradding, Peter Brainard, George Brégeon, Jérémy Brewer, Allison Brichta, Alan Brierley, Stuart Brittain, John-Stuart Brooks, Susan","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"21 1 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2017-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"81016639","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
The benefits of resistance training for skeletal muscle mass and strength are well characterised. Early adaptations to unaccustomed resistance exercise include increased muscle strength, whereas later adaptations include muscle hypertrophy and further improvements in muscle strength (Schoenfeld, 2010). Although these strength and hypertrophy gains following resistance training are well documented in healthy and clinical populations, the mechanisms surrounding these phenomena are less implicit. The skeletal muscle microenvironment is tightly regulated and responds rapidly to resistance exercise. A single bout of unaccustomed resistance exercise can cause damage to skeletal muscle, where the structural integrity of the myofibres is compromised. This was theorised to be a significant event which stimulates hypertrophic responses within the muscle microenvironment (Schoenfeld, 2010). However, progression through a resistance training programme is marked by an attenuation in muscle damage which is termed the ‘repeated bout effect’. These findings have lead researchers to question the role of muscle damage in muscle hypertrophy following resistance training. One key factor which has an important yet poorly understood association with muscle damage and hypertrophy following resistance exercise is muscle protein synthesis. Previous work by Damas and colleagues has demonstrated that resistance exercise is a potent stimulator of skeletal muscle protein synthesis (Damas et al. 2015). In the hours following an unaccustomed bout of resistance exercise, an increase in myofibrillar muscle protein synthesis (MyoPS) can be detected. Repeated bouts of resistance exercise cause cumulative periods of increased MyoPS where net protein synthesis is greater than protein degradation, thus favouring muscle hypertrophy (Damas et al. 2015). However, the MyoPS response to resistance exercise is not equivocal as the resistance training programme progresses. Attenuation of the MyoPS response to resistance exercise can be observed as early as 3 weeks into a training programme (Brook et al. 2015). Interestingly, the MyoPS response to initial resistance exercise bouts is not correlated with muscle hypertrophy that occurs later in the training programme (Damas et al. 2015). However, the MyoPS response to later bouts of the resistance training programme correlates strongly with muscle hypertrophy (Brook et al. 2015). The authors noted that initial bouts of unaccustomed resistance exercise cause pronounced muscle damage, which stimulates growth mechanisms and increases protein synthesis to support tissue repair. Damas therefore proposed that the lack of correlation between the MyoPS response to initial exercise bouts and subsequent muscle hypertrophy could be due to exercise-induced muscle damage, and that the early MyoPS response is focused on repairing damaged muscle. However, following resistance training the MyoPS response is a more dedicated driver of muscle hypertrophy. Conti
阻力训练对骨骼肌质量和力量的好处是很明显的。对不习惯的阻力运动的早期适应包括增加肌肉力量,而后来的适应包括肌肉肥大和肌肉力量的进一步改善(Schoenfeld, 2010)。尽管在健康和临床人群中,阻力训练后的力量和肥厚增加得到了充分的证明,但围绕这些现象的机制却不那么明确。骨骼肌微环境受到严格调控,对阻力运动反应迅速。单次不习惯的阻力运动就会对骨骼肌造成损伤,从而破坏肌纤维的结构完整性。从理论上讲,这是一个刺激肌肉微环境内肥厚反应的重要事件(Schoenfeld, 2010)。然而,通过抗阻训练计划的进步标志着肌肉损伤的衰减,这被称为“重复回合效应”。这些发现使研究人员质疑肌肉损伤在抗阻训练后肌肉肥大中的作用。肌肉蛋白合成是抗阻运动后肌肉损伤和肥厚的一个重要但鲜为人知的关键因素。Damas及其同事之前的研究表明,阻力运动是骨骼肌蛋白质合成的有力刺激物(Damas etal . 2015)。在一次不习惯的阻力运动后的几个小时内,可以检测到肌原纤维肌蛋白合成(MyoPS)的增加。反复的抗阻力运动会导致MyoPS的累积增加,此时净蛋白质合成大于蛋白质降解,从而有利于肌肉肥大(Damas et al. 2015)。然而,随着阻力训练计划的进展,MyoPS对阻力训练的反应并不是模棱两可的。早在训练计划开始3周后,就可以观察到MyoPS对阻力运动的反应衰减(Brook et al. 2015)。有趣的是,MyoPS对初始阻力运动的反应与训练计划后期发生的肌肉肥大无关(Damas et al. 2015)。然而,MyoPS对后期阻力训练计划的反应与肌肉肥大密切相关(Brook et al. 2015)。作者指出,最初不习惯的阻力运动会导致明显的肌肉损伤,从而刺激生长机制,增加蛋白质合成,以支持组织修复。因此,Damas提出,MyoPS对初始运动回合的反应与随后的肌肉肥大之间缺乏相关性可能是由于运动引起的肌肉损伤,而早期MyoPS反应主要集中在修复受损肌肉。然而,阻力训练后,MyoPS反应是肌肉肥大的一个更专门的驱动因素。因此,Damas等人在先前研究的基础上,通过测量MyoPS和肌肉损伤,研究了阻力训练期间肌肉肥大的调节。最近发表在《生理学杂志》上的一篇文章描述了这项研究(Damas et al. 2016)。作者假设MyoPS对初始阻力运动的反应与训练计划结束时的肌肉肥大无关,但在第3周和第10周时的MyoPS反应与肌肉肥大有关。这一假设意味着,对最初几次抗阻训练的急性MyoPS反应不能用于预测随后的肌肉肥大。Damas等人(2016a)采用稳健的研究设计,对健康年轻男性进行了为期10周的阻力训练干预,以评估骨骼肌损伤、MyoPS和肥厚反应。招募了10名参与者进行高强度下肢阻力训练,每周两次。在整个研究过程中,参与者在三个关键时间点进行评估:初始训练阶段、第3周和第10周的最后训练阶段。在每个时间点,收集股外侧肌的肌肉活检样本,在运动前和运动后24和48小时进行分析。研究人员通过给药氘水(D2O)检查了综合肌肉蛋白质的分数合成率。分别用z带流和全身肌酸激酶直接和间接测量肌肉损伤。通过对冰冻股外侧肌切片的纤维横截面积分析来量化肌肉肥大。主要统计分析包括多元回归分析和Pearson相关系数分析。10周的阻力训练干预成功地增加了膝关节伸展最大自主收缩(MVC),并使股外侧肌质量增加了14%。 正如预期的那样,在最初的阻力训练后24小时,肌肉损伤的直接和间接测量显着升高。在初始运动后24小时观察到MyoPS大幅升高,随后在48小时显著降低。在第3周训练后的48小时内,与初始运动相比,肌肉损伤和MyoPS反应均有所减弱。在第10周最后一次训练后的48小时内,肌肉损伤指标未高于基线;然而,MyoPS反应并没有进一步减弱。有趣的是,当MyoPS对训练的反应归一化到z带区域(肌肉损伤的直接测量)时,在任何时间点MyoPS反应都没有差异。总之,这些发现支持了作者的假设,即MyoPS对初始阻力运动的大反应部分是由于运动引起的肌肉损伤。由于反复运动后肌肉损伤的减弱,作者还假设,只有在训练干预的后期阶段,MyoPS才与肌肉肥大相关。正如预期的那样,最初阻力运动后的MyoPS与随后的肌纤维肥大无关
{"title":"An intricate balance of muscle damage and protein synthesis: the key players in skeletal muscle hypertrophy following resistance training","authors":"G. Keefe, C. Wright","doi":"10.1113/JP273235","DOIUrl":"https://doi.org/10.1113/JP273235","url":null,"abstract":"The benefits of resistance training for skeletal muscle mass and strength are well characterised. Early adaptations to unaccustomed resistance exercise include increased muscle strength, whereas later adaptations include muscle hypertrophy and further improvements in muscle strength (Schoenfeld, 2010). Although these strength and hypertrophy gains following resistance training are well documented in healthy and clinical populations, the mechanisms surrounding these phenomena are less implicit. The skeletal muscle microenvironment is tightly regulated and responds rapidly to resistance exercise. A single bout of unaccustomed resistance exercise can cause damage to skeletal muscle, where the structural integrity of the myofibres is compromised. This was theorised to be a significant event which stimulates hypertrophic responses within the muscle microenvironment (Schoenfeld, 2010). However, progression through a resistance training programme is marked by an attenuation in muscle damage which is termed the ‘repeated bout effect’. These findings have lead researchers to question the role of muscle damage in muscle hypertrophy following resistance training. One key factor which has an important yet poorly understood association with muscle damage and hypertrophy following resistance exercise is muscle protein synthesis. Previous work by Damas and colleagues has demonstrated that resistance exercise is a potent stimulator of skeletal muscle protein synthesis (Damas et al. 2015). In the hours following an unaccustomed bout of resistance exercise, an increase in myofibrillar muscle protein synthesis (MyoPS) can be detected. Repeated bouts of resistance exercise cause cumulative periods of increased MyoPS where net protein synthesis is greater than protein degradation, thus favouring muscle hypertrophy (Damas et al. 2015). However, the MyoPS response to resistance exercise is not equivocal as the resistance training programme progresses. Attenuation of the MyoPS response to resistance exercise can be observed as early as 3 weeks into a training programme (Brook et al. 2015). Interestingly, the MyoPS response to initial resistance exercise bouts is not correlated with muscle hypertrophy that occurs later in the training programme (Damas et al. 2015). However, the MyoPS response to later bouts of the resistance training programme correlates strongly with muscle hypertrophy (Brook et al. 2015). The authors noted that initial bouts of unaccustomed resistance exercise cause pronounced muscle damage, which stimulates growth mechanisms and increases protein synthesis to support tissue repair. Damas therefore proposed that the lack of correlation between the MyoPS response to initial exercise bouts and subsequent muscle hypertrophy could be due to exercise-induced muscle damage, and that the early MyoPS response is focused on repairing damaged muscle. However, following resistance training the MyoPS response is a more dedicated driver of muscle hypertrophy. Conti","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"33 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2016-12-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"73190403","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
The moment-to-moment regulation of metabolism is essential to life. It optimises conditions to keep cells working efficiently even when faced with a variety of metabolic challenges that occur constantly in both physiological and pathological situations. To respond adequately to these challenges, a well-orchestrated adjustment at the molecular, cellular, tissue and system levels is necessary. Quite recently the carotid body has been considered as a multifunctional structure. Besides its well-established role in promoting autonomic and ventilatory adjustments to changes in O2, CO2 and/or pH in arterial blood, there is a growing body of scientific evidence revealing that the carotid body can respond to other stimuli such as glucose, hormones, K+, osmolarity, proinflammatory cytokines and temperature (Kumar & Prabhakar, 2012). Because of this unique ability to accurately monitor the chemical composition of arterial blood, the carotid body may be involved in numerous physiological and pathological processes such as hypertension and heart failure. Currently, considerable attention has been paid to elucidate the role of the carotid body in the regulation of metabolism. More specifically, some studies have shown that the carotid body is essential in maintaining body homeostasis during metabolic challenges such as hypoglycaemia. In a recent study published in The Journal of Physiology, Thompson et al. (2016) highlighted that the carotid body plays an important role in a counter-regulatory response to hypoglycaemia. The authors showed that carotid body activation is crucial to match ventilation to the hypermetabolic state induced by hypoglycaemia, avoiding an increase in PaCO2 and consequently acidosis. Using an impressive range of in vivo functional studies, the new discovery was that the carotid body-mediated ventilatory adjustments to hypoglycaemia were adrenaline dependent and mediated by β-adrenoceptors. In anaesthetised Wistar rats, they showed that insulin-induced hypoglycaemia increased ventilation and CO2 sensitivity. Both effects were abolished by either adrenalectomy or propranolol administration, strongly suggesting that these adjustments during hypoglycaemia depend on adrenaline and its β-adrenoceptors. The other arm of the study was to verify the effect of adrenaline itself on ventilation and CO2 sensitivity. Through intravenous adrenaline infusion, Thompson et al. (2016) found that adrenaline mirrored the effects caused by hypoglycaemia, increasing both ventilation and CO2 sensitivity. However, when adrenaline was infused after bilateral carotid sinus nerve section, the rise in minute ventilation was significantly attenuated and PaCO2 was found to be higher compared with control, denoting a clear ventilation–metabolism mismatch. This protocol revealed that the carotid body mediates the ventilatory changes during adrenaline infusion. It is important to note that, to exclude a possible effect of blood pressure changes on ventilation, the autho
每时每刻对新陈代谢的调节是生命所必需的。它优化条件,使细胞即使在面对生理和病理情况下不断发生的各种代谢挑战时也能有效地工作。为了充分应对这些挑战,在分子、细胞、组织和系统层面进行精心安排的调整是必要的。最近,颈动脉体被认为是一个多功能结构。除了其在促进动脉血液中O2、CO2和/或pH值变化的自主和通气调节方面的公认作用外,越来越多的科学证据表明,颈动脉体可以对其他刺激做出反应,如葡萄糖、激素、K+、渗透压、促炎细胞因子和温度(Kumar & Prabhakar, 2012)。由于这种精确监测动脉血化学成分的独特能力,颈动脉体可能参与许多生理和病理过程,如高血压和心力衰竭。目前,人们对颈动脉小体在代谢调节中的作用的研究已经引起了相当大的重视。更具体地说,一些研究表明,在代谢挑战(如低血糖)期间,颈动脉体对维持体内稳态至关重要。在最近发表在《生理学杂志》(The Journal of Physiology)上的一项研究中,Thompson等人(2016)强调,颈动脉体在低血糖的反调节反应中起着重要作用。作者表明,颈动脉体激活对于将通气与低血糖引起的高代谢状态相匹配至关重要,可以避免PaCO2的增加,从而避免酸中毒。通过一系列令人印象深刻的体内功能研究,新发现颈动脉机体介导的低血糖通气调节依赖于肾上腺素,并由β-肾上腺素受体介导。在麻醉的Wistar大鼠中,他们发现胰岛素诱导的低血糖增加了通气和二氧化碳敏感性。肾上腺切除术或普萘洛尔均可消除这两种影响,这强烈表明低血糖期间的调节依赖于肾上腺素及其β-肾上腺素受体。研究的另一部分是验证肾上腺素本身对通气和二氧化碳敏感性的影响。Thompson et al.(2016)通过静脉输注肾上腺素发现肾上腺素反映了低血糖引起的影响,增加了通气和CO2敏感性。然而,当双侧颈窦神经切断术后注入肾上腺素时,分钟通气量的上升明显减弱,PaCO2高于对照组,表明明显的通气代谢失配。该方案揭示了肾上腺素输注期间颈动脉体介导通气改变。值得注意的是,为了排除血压变化对通气的可能影响,作者仔细选择了不影响动脉血压水平的肾上腺素剂量。最后,通过Ca2+成像实验,作者证明了高碳酸血症诱导的孤立颈动脉体I型细胞内Ca2+的增加是由肾上腺素增强的,支持这种激素能够直接刺激颈动脉体的观点。Thompson et al.(2016)提供的数据为颈动脉体参与代谢调节的机制提供了新的见解。值得注意的是,有证据表明肾上腺素在低血糖时刺激颈动脉体介导的过度通气中起重要作用。这一发现可以回答Bin Jaliah等人(2004)提出的一个问题;Bin Jaliah等(2004)的研究认为,低血糖时颈动脉体介导的过度通气依赖于另一种刺激,而不是低糖和胰岛素,这表明这种作用可能由其他与高代谢相关的因素触发。另一方面,Ribeiro等人(2013)得出结论,胰岛素是低血糖期间激活颈动脉体介导的过度通气的因素,因为胰岛素即使在血糖钳夹期间也会增加通气,并且在颈动脉窦神经双侧切除后这种通气反应被消除。后者的结果支持了胰岛素可能是低血糖时颈动脉体的第一个刺激,引发交感神经流出增加的假设。这种增强的交感神经活动可以激活交感肾上腺轴,增加肾上腺素的释放。肾上腺素最终又能刺激颈动脉体促进低血糖时的通气调节,进一步放大交感神经活动的反射性增加。因此,在低血糖期间,颈动脉体可能以暂时分散的方式作出反应。 然而,需要进一步的研究来验证这一建议。Thompson等人(2016)研究的另一个值得注意的贡献是,他们的研究结果指出肾上腺素和颈动脉体之间存在双向联系。众所周知,正如上文所述,颈动脉体激活会通过交感肾上腺轴增加肾上腺素释放。然而,肾上腺素对颈动脉体功能的影响大多未被探索,值得进一步研究。肾上腺素与颈动脉体之间的双向串扰可能参与其他生理和病理状况的调节。例如,有许多研究表明颈动脉体参与交感介导的疾病,如高血压、心力衰竭、睡眠呼吸暂停和最近的代谢紊乱(Paton et al. 2013)。在所有情况下,颈动脉体高压都是交感神经流出增加的重要原因。正因为如此,为了找到调节这些活动的方法,人们对实验和临床场景越来越感兴趣,以更好地了解导致颈动脉体高张力和高反射的机制。Thompson等人(2016)最近的研究进一步有助于我们理解颈动脉体异常信号的机制,因为他们表明肾上腺素可以
{"title":"Adrenaline and the carotid body during hypoglycaemia: an amplifying mechanism?","authors":"P. Katayama","doi":"10.1113/JP273238","DOIUrl":"https://doi.org/10.1113/JP273238","url":null,"abstract":"The moment-to-moment regulation of metabolism is essential to life. It optimises conditions to keep cells working efficiently even when faced with a variety of metabolic challenges that occur constantly in both physiological and pathological situations. To respond adequately to these challenges, a well-orchestrated adjustment at the molecular, cellular, tissue and system levels is necessary. Quite recently the carotid body has been considered as a multifunctional structure. Besides its well-established role in promoting autonomic and ventilatory adjustments to changes in O2, CO2 and/or pH in arterial blood, there is a growing body of scientific evidence revealing that the carotid body can respond to other stimuli such as glucose, hormones, K+, osmolarity, proinflammatory cytokines and temperature (Kumar & Prabhakar, 2012). Because of this unique ability to accurately monitor the chemical composition of arterial blood, the carotid body may be involved in numerous physiological and pathological processes such as hypertension and heart failure. Currently, considerable attention has been paid to elucidate the role of the carotid body in the regulation of metabolism. More specifically, some studies have shown that the carotid body is essential in maintaining body homeostasis during metabolic challenges such as hypoglycaemia. In a recent study published in The Journal of Physiology, Thompson et al. (2016) highlighted that the carotid body plays an important role in a counter-regulatory response to hypoglycaemia. The authors showed that carotid body activation is crucial to match ventilation to the hypermetabolic state induced by hypoglycaemia, avoiding an increase in PaCO2 and consequently acidosis. Using an impressive range of in vivo functional studies, the new discovery was that the carotid body-mediated ventilatory adjustments to hypoglycaemia were adrenaline dependent and mediated by β-adrenoceptors. In anaesthetised Wistar rats, they showed that insulin-induced hypoglycaemia increased ventilation and CO2 sensitivity. Both effects were abolished by either adrenalectomy or propranolol administration, strongly suggesting that these adjustments during hypoglycaemia depend on adrenaline and its β-adrenoceptors. The other arm of the study was to verify the effect of adrenaline itself on ventilation and CO2 sensitivity. Through intravenous adrenaline infusion, Thompson et al. (2016) found that adrenaline mirrored the effects caused by hypoglycaemia, increasing both ventilation and CO2 sensitivity. However, when adrenaline was infused after bilateral carotid sinus nerve section, the rise in minute ventilation was significantly attenuated and PaCO2 was found to be higher compared with control, denoting a clear ventilation–metabolism mismatch. This protocol revealed that the carotid body mediates the ventilatory changes during adrenaline infusion. It is important to note that, to exclude a possible effect of blood pressure changes on ventilation, the autho","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"14 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2016-12-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"82021400","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Progressive neuromuscular diseases, such as Duchenne muscular dystrophy, but also the normal ageing process, result in muscle atrophy and remodelling (including infiltration with non-contractile fat and connective tissue). These effects impair the ability of muscle to generate and maintain force and endurance. Symptoms including weakness and fatigue are first noticed in ambulatory muscles but do not spare other skeletal muscles, including the respiratory muscles (diaphragm and intercostal muscles) (Sharma & Goodwin, 2006). Respiratory and bulbar muscle weakness interferes with airway clearance, increases risk of recurrent chest infections, and ultimately leads to respiratory failure. In fact, the prognosis for people with progressive neuromuscular disorders depends primarily on the degree of respiratory muscle involvement. In people, respiratory muscle function is typically assessed indirectly by using pulmonary function indices, such as forced vital capacity, peak expiratory and inspiratory pressures, the fluoroscopic sniff test, or nerve conduction studies and electromyography (Sarwal et al. 2013). Nerve conduction studies and electromyography are challenging and uncomfortable. Pulmonary function tests may be difficult to perform and therefore less reliable in people with significant respiratory muscle weakness. In preclinical rodent models, such as the mdx mouse (a model for human Duchenne muscular dystrophy), the standard method to evaluate respiratory muscle strength is ex vivo measured isometric force developed by a small (a few millimeters in width) diaphragm strip. The limitations of this approach include: (i) the single time point of measurement (mice need to be killed to harvest the diaphragm strips), (ii) the strip may not be representative of the whole diaphragm because fibrosis, a major cause of muscle weakness, is not distributed evenly across that diaphragm, and (iii) muscle force development depends on both intrinsic and extrinsic (e.g. innervation) factors, which are not all accounted for ex vivo. In this issue of The Journal of Physiology, Whitehead et al. (2016) describe a newly developed high-frequency, high resolution ultrasonography method to evaluate diaphragm function in vivo in mice. They first validated diaphragm ultrasonography as a reliable measure of in vivo diaphragm function by measuring diaphragm movement amplitude in 8and 18-month-old wild type (WT) and mdx mice and comparing these measurements with ex vivo specific force measurements. They found that ultrasound imaging reliably detected diaphragm dysfunction in mdx mice both at 8 and 18 months of age and the ultrasound-measured diaphragm amplitude measurements correlated strongly with ex vivo-measured isometric force. They then used the ultrasound method to track (serial measure-
进行性神经肌肉疾病,如杜氏肌营养不良,以及正常的衰老过程,都会导致肌肉萎缩和重塑(包括非收缩性脂肪和结缔组织的浸润)。这些影响损害了肌肉产生和维持力量和耐力的能力。包括无力和疲劳在内的症状首先出现在活动肌中,但其他骨骼肌也不例外,包括呼吸肌(横膈膜和肋间肌)(Sharma & Goodwin, 2006)。呼吸和球肌无力干扰气道清除,增加复发性胸部感染的风险,并最终导致呼吸衰竭。事实上,进行性神经肌肉疾病患者的预后主要取决于呼吸肌受累的程度。在人类中,呼吸肌功能通常通过使用肺功能指数间接评估,如用力肺活量、呼气和吸气峰值压力、透视嗅探试验或神经传导研究和肌电图(Sarwal et al. 2013)。神经传导研究和肌电图是具有挑战性和不舒服的。肺功能检查可能难以进行,因此对有明显呼吸肌无力的人不太可靠。在临床前啮齿类动物模型中,如mdx小鼠(人类杜氏肌营养不良症模型),评估呼吸肌力量的标准方法是通过一个小的(几毫米宽)隔膜条产生的离体测量等距力。这种方法的局限性包括:(i)单一的测量时间点(需要杀死小鼠才能获得横膈膜条),(ii)横膈膜条可能不能代表整个横膈膜,因为纤维化(肌肉无力的主要原因)不是均匀分布在横膈膜上,(iii)肌肉力量的发展取决于内在和外在因素(例如神经支配),这些因素并不都是体外考虑的。Whitehead等人(2016)在本期《The Journal of Physiology》中描述了一种新开发的高频、高分辨率超声检查方法,用于评估小鼠体内隔膜功能。他们首先通过测量8个月和18个月野生型(WT)和mdx小鼠的横膈膜运动振幅,并将这些测量结果与离体比力测量结果进行比较,验证了横膈膜超声作为体内横膈膜功能的可靠测量方法。他们发现,超声成像可靠地检测出8个月和18个月大的mdx小鼠的膈肌功能障碍,超声测量的膈肌振幅测量值与离体测量的等距力测量值密切相关。然后,他们使用超声波方法跟踪(连续测量)
{"title":"Tracking diaphragm movement by using ultrasound to assess its strength","authors":"A. Connolly, B. Mittendorfer","doi":"10.1113/JP273313","DOIUrl":"https://doi.org/10.1113/JP273313","url":null,"abstract":"Progressive neuromuscular diseases, such as Duchenne muscular dystrophy, but also the normal ageing process, result in muscle atrophy and remodelling (including infiltration with non-contractile fat and connective tissue). These effects impair the ability of muscle to generate and maintain force and endurance. Symptoms including weakness and fatigue are first noticed in ambulatory muscles but do not spare other skeletal muscles, including the respiratory muscles (diaphragm and intercostal muscles) (Sharma & Goodwin, 2006). Respiratory and bulbar muscle weakness interferes with airway clearance, increases risk of recurrent chest infections, and ultimately leads to respiratory failure. In fact, the prognosis for people with progressive neuromuscular disorders depends primarily on the degree of respiratory muscle involvement. In people, respiratory muscle function is typically assessed indirectly by using pulmonary function indices, such as forced vital capacity, peak expiratory and inspiratory pressures, the fluoroscopic sniff test, or nerve conduction studies and electromyography (Sarwal et al. 2013). Nerve conduction studies and electromyography are challenging and uncomfortable. Pulmonary function tests may be difficult to perform and therefore less reliable in people with significant respiratory muscle weakness. In preclinical rodent models, such as the mdx mouse (a model for human Duchenne muscular dystrophy), the standard method to evaluate respiratory muscle strength is ex vivo measured isometric force developed by a small (a few millimeters in width) diaphragm strip. The limitations of this approach include: (i) the single time point of measurement (mice need to be killed to harvest the diaphragm strips), (ii) the strip may not be representative of the whole diaphragm because fibrosis, a major cause of muscle weakness, is not distributed evenly across that diaphragm, and (iii) muscle force development depends on both intrinsic and extrinsic (e.g. innervation) factors, which are not all accounted for ex vivo. In this issue of The Journal of Physiology, Whitehead et al. (2016) describe a newly developed high-frequency, high resolution ultrasonography method to evaluate diaphragm function in vivo in mice. They first validated diaphragm ultrasonography as a reliable measure of in vivo diaphragm function by measuring diaphragm movement amplitude in 8and 18-month-old wild type (WT) and mdx mice and comparing these measurements with ex vivo specific force measurements. They found that ultrasound imaging reliably detected diaphragm dysfunction in mdx mice both at 8 and 18 months of age and the ultrasound-measured diaphragm amplitude measurements correlated strongly with ex vivo-measured isometric force. They then used the ultrasound method to track (serial measure-","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"21 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2016-12-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"89471576","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Daniel Lazzam, B-R. Wang, Eric Jong, Pratiek N. Matkar
Cardiovascular disease is currently the leading cause of death in developed countries across the globe, with myriad risk factors that modern life has only exacerbated. As such, treatments and lifestyle changes that alleviate the risk of cardiovascular disease are of great relevance. While factors like exercise and good diet are known to have such ameliorative effects, patients at high risk of developing cardiovascular diseases are often elderly or obese, and thus may have difficulty exercising on a regular basis. Furthermore, individuals with lower incomes often cannot afford to eat healthily, or such a diet is logistically impossible for them. These factors will only be exacerbated by rapidly rising food prices and increasing populations aggravating socioeconomic phenomena such as food deserts, residential areas devoid of groceries or healthy food options (Rehm et al. 2015). Thus, medically subsidized alternatives to these options are extremely important to explore for those whom a good diet or frequent exercise may be difficult or infeasible. In recent years, several studies have examined thermal therapy as one such alternative, primarily through methods such as saunas and bathing (Imamura et al. 2001; Hu et al. 2012). While the efficacy of thermal therapy on cardiovascular health has at this point been demonstrated by multiple studies, the underlying mechanisms are less understood. However, a recent publication in The Journal of Physiology (Brunt et al. 2016) has helped to elucidate some of these mechanisms. In the paper, Brunt et al. (2016) performed an 8 week study on a cohort of 20 subjects in which the subjects either underwent heat therapy 4–5 times a week for a total of 90 min or were immersed in thermoneutral water as an osmotic and hydrostatic control. The subjects assigned to heat therapy were immersed in 40.5°C water, a temperature sufficient to maintain rectal temperature greater than 38.5°C for 60 min. In contrast, the rectal temperature of the control group remained within 0.2°C of the original temperature. Subjects in both groups were matched for sex, age, height, body mass index and weight, ensuring a representative control group. The authors of the study took a multi-pronged approach in determining the mechanism of action of heat therapy by measuring a variety of processes that they hypothesized could contribute: flow-mediated dilatation, superficial femoral dynamic arterial compliance, aortic pulse wave velocity, carotid intima media thickness, and mean arterial blood pressure. These measurements were taken at the start of the study and every 2 weeks thereafter. The literature has suggested that part of the mechanism by which heat therapy ameliorates cardiovascular health is through alleviation of arterial stiffness (Hu et al. 2012). Consequently, Brunt et al. (2016) hypothesized that flow-mediated dilatation and superficial femoral dynamic compliance would increase with regular heat therapy. Indeed, flow-mediated dilatation s
心血管疾病目前是全球发达国家的主要死亡原因,现代生活加剧了无数的风险因素。因此,减轻心血管疾病风险的治疗和生活方式的改变具有重要意义。众所周知,运动和良好的饮食习惯等因素具有改善作用,但患心血管疾病的高风险患者往往是老年人或肥胖患者,因此可能难以定期锻炼。此外,收入较低的个人往往负担不起健康饮食,或者这种饮食对他们来说在后勤上是不可能的。这些因素只会因食品价格的快速上涨和人口的增加而加剧社会经济现象,如食品沙漠、缺乏杂货或健康食品选择的居民区(Rehm et al. 2015)。因此,对于那些难以或无法实现良好饮食或经常锻炼的人来说,探索这些选择的医疗补贴替代品是极其重要的。近年来,一些研究将热疗法作为一种替代疗法,主要是通过桑拿和沐浴等方法(Imamura等人,2001;Hu et al. 2012)。虽然热疗对心血管健康的功效目前已被多项研究证明,但其潜在机制尚不清楚。然而,最近发表在《生理学杂志》(布伦特et al. 2016)上的一篇文章帮助阐明了其中的一些机制。在本文中,布伦特等人(2016)对20名受试者进行了为期8周的队列研究,其中受试者要么每周接受4-5次共90分钟的热治疗,要么浸泡在热中性水中作为渗透和静压控制。热疗组将受试者浸泡在40.5°C的水中,该温度足以使直肠温度保持在38.5°C以上60分钟,而对照组的直肠温度保持在0.2°C以内。两组受试者的性别、年龄、身高、身体质量指数和体重都是匹配的,以确保有代表性的对照组。该研究的作者采用了多管齐下的方法来确定热疗法的作用机制,通过测量他们假设可能有助于的各种过程:血流介导的扩张、股浅动态动脉顺应性、主动脉脉冲波速度、颈动脉内膜中膜厚度和平均动脉血压。这些测量在研究开始时进行,之后每两周进行一次。文献表明,热疗法改善心血管健康的部分机制是通过减轻动脉僵硬(Hu et al. 2012)。因此,布伦特等人(2016)假设,定期热疗会增加血流介导的扩张和股浅动态顺应性。事实上,与对照组相比,热疗法可以立即显著增加血流介导的扩张。虽然它在第4周似乎暂时下降,但当校正剪切应力时,这个异常值返回到前面显示的对数模式。这一趋势是非常令人鼓舞的,因为它意味着,虽然增加使用热疗法会产生更大的回报,但只需要短暂的初始治疗就能产生显著的效果。正如文章所提到的,血流介导的扩张增加2%,心血管疾病风险降低15%,仅2周后增加超过2%,表明热疗法具有直接的临床意义。虽然颈动脉顺应性对热疗法没有类似的反应,与对照组相比在统计学上没有变化,但在热疗法后,股浅动态动脉顺应性也呈现出对数模式的显著增加,强化了早期研究显示动脉僵硬度降低的结果(Hu et al. 2012;布伦特等人,2016)。作者还研究了其他评估心血管疾病风险的指标,如脉搏波速度、颈动脉和股动脉的动脉壁厚度以及血压。与第0周相比,观察到脉搏波速度明显下降,尽管与对照组相比没有明显下降,这表明需要进一步调查。然而,其他结果更有希望;而股动脉壁厚度无显著差异,颈动脉壁厚度明显下降,可能是由于动脉粥样硬化斑块的破裂,这一发现具有临床意义。虽然需要对这一效应的机制进行更详细的研究,但这是一个非常有希望的结果。此外,研究还显示平均血压和舒张压都有显著降低。 虽然这些减少仅为4毫米汞柱,但按照预防措施的标准,研究的持续时间相当短,而且结果可能会随着时间的推移而增加。最后,正如文章所述,这种减少是在健康个体中发现的;因此,如果将热疗法作为一种治疗而不是预防措施,心血管疾病患者的血压升高可能会有更大的下降(布伦特等人,2016)。布伦特等人(2016)为进一步深入研究开辟了多种途径,例如通过研究热疗法在广度上改善心血管疾病风险的机制,对上述动脉壁厚度降低的来源进行调查。然而,即使没有这样的调查,研究文章的结果在心血管疾病的预防措施方面非常有用。作者发现血流介导的扩张呈对数增长,这表明这种治疗即使在短期内对那些风险因素升高的人也是有用的。此外,一种具有非侵入性减少动脉粥样硬化斑块潜力的治疗方法可能是显著降低心血管疾病风险的有力工具
{"title":"Passive heat therapy: the next hot thing for cardiovascular health!","authors":"Daniel Lazzam, B-R. Wang, Eric Jong, Pratiek N. Matkar","doi":"10.1113/JP273213","DOIUrl":"https://doi.org/10.1113/JP273213","url":null,"abstract":"Cardiovascular disease is currently the leading cause of death in developed countries across the globe, with myriad risk factors that modern life has only exacerbated. As such, treatments and lifestyle changes that alleviate the risk of cardiovascular disease are of great relevance. While factors like exercise and good diet are known to have such ameliorative effects, patients at high risk of developing cardiovascular diseases are often elderly or obese, and thus may have difficulty exercising on a regular basis. Furthermore, individuals with lower incomes often cannot afford to eat healthily, or such a diet is logistically impossible for them. These factors will only be exacerbated by rapidly rising food prices and increasing populations aggravating socioeconomic phenomena such as food deserts, residential areas devoid of groceries or healthy food options (Rehm et al. 2015). Thus, medically subsidized alternatives to these options are extremely important to explore for those whom a good diet or frequent exercise may be difficult or infeasible. In recent years, several studies have examined thermal therapy as one such alternative, primarily through methods such as saunas and bathing (Imamura et al. 2001; Hu et al. 2012). While the efficacy of thermal therapy on cardiovascular health has at this point been demonstrated by multiple studies, the underlying mechanisms are less understood. However, a recent publication in The Journal of Physiology (Brunt et al. 2016) has helped to elucidate some of these mechanisms. In the paper, Brunt et al. (2016) performed an 8 week study on a cohort of 20 subjects in which the subjects either underwent heat therapy 4–5 times a week for a total of 90 min or were immersed in thermoneutral water as an osmotic and hydrostatic control. The subjects assigned to heat therapy were immersed in 40.5°C water, a temperature sufficient to maintain rectal temperature greater than 38.5°C for 60 min. In contrast, the rectal temperature of the control group remained within 0.2°C of the original temperature. Subjects in both groups were matched for sex, age, height, body mass index and weight, ensuring a representative control group. The authors of the study took a multi-pronged approach in determining the mechanism of action of heat therapy by measuring a variety of processes that they hypothesized could contribute: flow-mediated dilatation, superficial femoral dynamic arterial compliance, aortic pulse wave velocity, carotid intima media thickness, and mean arterial blood pressure. These measurements were taken at the start of the study and every 2 weeks thereafter. The literature has suggested that part of the mechanism by which heat therapy ameliorates cardiovascular health is through alleviation of arterial stiffness (Hu et al. 2012). Consequently, Brunt et al. (2016) hypothesized that flow-mediated dilatation and superficial femoral dynamic compliance would increase with regular heat therapy. Indeed, flow-mediated dilatation s","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"19 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2016-12-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"77167916","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
The power–time relationship for highintensity exercise is well known to be hyperbolic and generalizable to multiple exercise modalities in humans and other species. The critical power (CP) is mathematically defined as the asymptote of this hyperbola, while the curvature constant (W′) represents a fixed amount of work that can be performed above CP before reaching exhaustion. Importantly, CP is the highest intensity in which a steady state can be obtained for small muscle mass exercise, as assessed by intramuscular metabolic perturbation, and during wholebody exercise, assessed by oxygen uptake. However, experimental evidence demonstrating that CP represents a threshold for steady state ( CP) or non-steady state (> CP) intramuscular metabolic perturbation during whole-body exercise, a necessity for the validation of the CP concept, has remained elusive. In a recent article published in The Journal of Physiology, Vanhatalo and colleagues aimed to clarify the mechanistic bases of the power–time parameters (i.e. CP and W′) during whole-body exercise in relation to muscle metabolism and fibre type distribution (Vanhatalo et al. 2016). To this end, they performed two experimental protocols with multiple muscle biopsies prior to, and following, high-intensity cycling tests of varying duration. Notably, the authors present the first evidence demonstrating that CP demarcates intensities which result in steady-state ( CP) and non-steady state (> CP) intramuscular metabolic responses for wholebody exercise (i.e. phosphocreatine, creatine, pH, lactate, and glycogen). Moreover, Vanhatalo et al. (2016) documented that a greater CP was associated with a higher type I muscle fibre proportion and a lower type IIx proportion. These findings build upon previous work to further validate the CP concept and extend our understanding of the mechanisms determining the power–time relationship. The authors also determined that the size of the W′ is not proportional to any specific muscle fibre type population, further supporting the growing evidence that W′ is determined by the integration of a multitude of physiological mechanisms. Indeed, by compiling evidence from this study and several other recent publications, questions arise regarding the potential mechanistic role of the group III/IV muscle afferents in determining W′; however, little work has been performed with this focus.
众所周知,高强度运动的能量-时间关系是双曲的,可推广到人类和其他物种的多种运动方式。临界功率(CP)在数学上定义为双曲线的渐近线,而曲率常数(W’)表示在达到极限之前可以在CP以上执行的固定工作量。重要的是,CP是在小肌肉量运动中可以获得稳定状态的最高强度,通过肌内代谢扰动来评估,在全身运动中,通过摄氧量来评估。然而,实验证据表明,在全身运动过程中,CP代表了稳态(CP)或非稳态(> CP)肌内代谢扰动的阈值,这是验证CP概念的必要条件,但仍然难以捉摸。在最近发表在《生理学杂志》上的一篇文章中,Vanhatalo及其同事旨在阐明全身运动过程中与肌肉代谢和纤维类型分布相关的动力时间参数(即CP和W ')的机制基础(Vanhatalo et al. 2016)。为此,他们在不同持续时间的高强度循环测试之前和之后进行了两项实验方案,分别进行了多次肌肉活检。值得注意的是,作者提出了第一个证据,证明CP区分了导致全身运动(即磷酸肌酸、肌酸、pH、乳酸和糖原)的稳态(CP)和非稳态(> CP)肌内代谢反应的强度。此外,Vanhatalo等人(2016)证明,较大的CP与较高的I型肌纤维比例和较低的ix型肌纤维比例相关。这些发现建立在先前工作的基础上,进一步验证了CP概念,并扩展了我们对决定权力-时间关系的机制的理解。作者还确定,W '的大小与任何特定肌肉纤维类型的人群不成比例,这进一步支持了越来越多的证据,即W '是由多种生理机制的综合决定的。事实上,通过汇编本研究和其他一些近期出版物的证据,出现了关于III/IV组肌肉传入事件在决定W '中的潜在机制作用的问题;然而,围绕这一重点开展的工作很少。
{"title":"The mechanistic basis of the power–time relationship: potential role of the group III/IV muscle afferents","authors":"T. Hureau, R. Broxterman, J. Weavil","doi":"10.1113/JP273333","DOIUrl":"https://doi.org/10.1113/JP273333","url":null,"abstract":"The power–time relationship for highintensity exercise is well known to be hyperbolic and generalizable to multiple exercise modalities in humans and other species. The critical power (CP) is mathematically defined as the asymptote of this hyperbola, while the curvature constant (W′) represents a fixed amount of work that can be performed above CP before reaching exhaustion. Importantly, CP is the highest intensity in which a steady state can be obtained for small muscle mass exercise, as assessed by intramuscular metabolic perturbation, and during wholebody exercise, assessed by oxygen uptake. However, experimental evidence demonstrating that CP represents a threshold for steady state ( CP) or non-steady state (> CP) intramuscular metabolic perturbation during whole-body exercise, a necessity for the validation of the CP concept, has remained elusive. In a recent article published in The Journal of Physiology, Vanhatalo and colleagues aimed to clarify the mechanistic bases of the power–time parameters (i.e. CP and W′) during whole-body exercise in relation to muscle metabolism and fibre type distribution (Vanhatalo et al. 2016). To this end, they performed two experimental protocols with multiple muscle biopsies prior to, and following, high-intensity cycling tests of varying duration. Notably, the authors present the first evidence demonstrating that CP demarcates intensities which result in steady-state ( CP) and non-steady state (> CP) intramuscular metabolic responses for wholebody exercise (i.e. phosphocreatine, creatine, pH, lactate, and glycogen). Moreover, Vanhatalo et al. (2016) documented that a greater CP was associated with a higher type I muscle fibre proportion and a lower type IIx proportion. These findings build upon previous work to further validate the CP concept and extend our understanding of the mechanisms determining the power–time relationship. The authors also determined that the size of the W′ is not proportional to any specific muscle fibre type population, further supporting the growing evidence that W′ is determined by the integration of a multitude of physiological mechanisms. Indeed, by compiling evidence from this study and several other recent publications, questions arise regarding the potential mechanistic role of the group III/IV muscle afferents in determining W′; however, little work has been performed with this focus.","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"216 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2016-12-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"77890187","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Satellite cells (SCs), the skeletal muscle stem cells, are essential for muscle regeneration in genetic or autoimmune muscle diseases as well as after ischaemic, chemical or mechanical trauma to the myofibres. Furthermore, SCs are the primary source to supply new myonuclei to growing myofibres during non-traumatic mechanical overload. Thus, when SCs are conditionally ablated using a tamoxifen inducible Cre-LoxP system, the addition of myonuclei during overload is abrogated (McCarthy et al. 2011). However, despite the lack of myonuclei addition, substantial hypertrophy could be induced in SC-ablated mice (McCarthy et al. 2011). More recent evidence, however, indicates that the ability of SC-depleted muscles to hypertrophy could be compromised during the later stages of muscle hypertrophy (Fry et al. 2014). Thus, while myonuclei addition, due to the fusion of muscle progenitors, may not be a prerequisite for initial muscle hypertrophy, a functional pool of SCs still play a key role during muscle hypertrophy. In contrast, less is known concerning the role of SCs and myonuclei turnover (e.g. myonuclei loss through apoptosis) during myofibre atrophy. Previous studies indicate that myofibre atrophy, for instance during immobilization or disease (cachexia), is generally not associated with a loss of myonuclei or an increase of DNA damage and apoptosis (Bruusgaard et al. 2012; Suetta et al. 2012). In an intriguing recent paper published in The Journal of Physiology, Fry and colleagues (Fry et al. 2016) explore the potential involvement of SCs and myonuclei apoptosis in young burn patients, a condition characterized by hyper-metabolism and extreme muscle wasting. Biopsies of vastus lateralis muscle were collected from patients (children between 8 and 18 years), with burns encompassing more than 30% of their total body area, during the flow phase of their recovery (characterized by hyper-metabolic demand). Biopsies were also collected from vastus lateralis muscles in a healthy control group, including males between 18 and 29 years of age, for comparison purposes. Through extensive immunohistochemical analyses, the authors collected information on myonuclei apoptosis (deoxynucleotidyl transferase dUTP nick end labelling (TUNEL) and caspase-3 positive myonuclei), SC content and activity Ki67/Myogenic differentiation 1 (MyoD) expression, SC apoptosis (TUNEL positive satellite cells), muscle regeneration by analysing embryonic myosin heavy chain (embMHC) expression and levels of connective tissue content (by wheat germ agglutinin staining). The authors hypothesized that severe burn trauma could induce myonuclear apoptosis along with increased SC activation, in order to counteract the loss of myonuclei. In brief, the major findings by Fry and colleagues were (summarized in Table 1): (1) burn trauma induces myonuclear and SC apoptosis, (2) SC content is decreased although the content of active SCs is increased in burn patients, and (3) the latter two are associa
卫星细胞(SCs)是骨骼肌干细胞,对于遗传性或自身免疫性肌肉疾病以及肌纤维缺血、化学或机械损伤后的肌肉再生至关重要。此外,在非创伤性机械负荷期间,SCs是向生长的肌纤维提供新肌核的主要来源。因此,当使用他莫昔芬诱导的Cre-LoxP系统有条件地消融SCs时,在过载期间取消了myonuclei的添加(McCarthy et al. 2011)。然而,尽管缺乏髓核添加,sc消融小鼠仍可诱导大量肥大(McCarthy et al. 2011)。然而,最近的证据表明,sc耗尽的肌肉在肌肉肥大的后期阶段可能会受到损害(Fry et al. 2014)。因此,尽管肌祖细胞融合导致的肌核增加可能不是初始肌肉肥大的先决条件,但SCs的功能池仍然在肌肉肥大过程中发挥关键作用。相比之下,在肌纤维萎缩过程中,对SCs和肌核转换(如通过细胞凋亡导致的肌核丢失)的作用知之甚少。先前的研究表明,肌纤维萎缩,例如在固定或疾病(恶病质)期间,通常与肌核丢失或DNA损伤和细胞凋亡的增加无关(Bruusgaard等,2012;Suetta et al. 2012)。在最近发表在《生理学杂志》(The Journal of Physiology)上的一篇有趣的论文中,Fry及其同事(Fry et al. 2016)探讨了sc和肌核凋亡在年轻烧伤患者中的潜在作用,烧伤患者的特征是高代谢和极度肌肉萎缩。从患者(8 - 18岁的儿童)收集股外侧肌活检,烧伤面积超过其全身面积的30%,在其恢复的流动阶段(特征是高代谢需求)。为了进行比较,还对健康对照组(包括18至29岁的男性)的股外侧肌进行了活检。通过广泛的免疫组织化学分析,作者收集了肌核凋亡(deoxynucleotidyl transferase dUTP nick end labelling (TUNEL)和caspase-3阳性肌核)、SC含量和活性Ki67/Myogenic differentiation 1 (MyoD)表达、SC凋亡(TUNEL阳性卫星细胞)、通过分析胚胎肌球蛋白重链(embMHC)表达和结缔组织含量水平(小麦胚芽凝集素染色)的信息。作者推测,严重的烧伤创伤可以诱导髓核凋亡,同时增加SC激活,以抵消髓核的损失。简而言之,Fry及其同事的主要发现如下(表1总结):(1)烧伤创伤诱导髓核和SC凋亡;(2)烧伤患者中SC含量减少,但活性SC含量增加;(3)烧伤患者中后两者与广泛的再生反应(中心核和embMHC阳性纤维增加)有关。先前的研究报道,肌纤维萎缩的情况下会发生肌核凋亡,可能是为了保持相对恒定的肌核结构域大小(肌纤维横截面面积/肌核),尽管最近的研究对这一观点提出了质疑(Bruusgaard等人,2012)。因此,Fry等人(2016)等报道的关于肌核和SC凋亡的数据表明,固定和烧伤引起的恶病质诱导肌肉萎缩的情况不同。为了证实在TUNEL+ myonuclei上的发现,Fry等(2016)通过caspase-3/dystrophin染色证实了这些结果,确实表明在严重烧伤患者中myonuclei被诱导凋亡。总体而言,Fry等人(2016)的结果表明,不同的肌肉萎缩模型本质上是不同的,尽管一种萎缩模型(例如固定)没有诱导肌核凋亡,但它可能是其他模型(例如烧伤诱导的恶病质)萎缩过程的一部分。上述两项研究尚未对这些差异背后的机制进行调查;然而,这些知识对于理解不同情况下肌肉萎缩的内在差异是高度相关的。除了细胞凋亡外,Fry等人(2016)还观察到一种再生反应,其特征是中央有核肌纤维、SC活性和embMHC表达的增加,这与烧伤损伤的程度有关。有趣的是,与健康对照组相比,严重烧伤患者的总SC含量较低。如上所述,这可能与SC凋亡的增加有关,或者,也可能是由于分化SC数量的增加,其中配对盒转录因子7 (Pax7)下调。 后者因此可以补偿由于细胞凋亡而造成的核损失。SC含量的降低可能与SC自我更新的减少有关,相反,SC激活似乎被增强,导致这些细胞进入肌生成程序并分化。有趣的是,白细胞介素-6 (IL-6)的增加和下游信号转导和转录激活因子3 (STAT3)信号的激活最近被证明可以增加MyoD的表达和SC的分化(Tierney et al. 2014)。为了支持这一推测,Fry等人(2016)观察到基底膜下明显数量的myod阳性细胞(即可能激活的SCs),这可能是由于IL-6-STAT3途径的激活。虽然IL-6可以从成熟的肌纤维中分泌,但组织浸润性巨噬细胞或常驻纤维脂肪生成祖细胞(FAPs)也可能有助于这种细胞因子的产生。因此,解剖骨骼肌中炎症细胞或间质细胞(即FAPs)在萎缩状态(如烧伤引起的萎缩)中的作用可以揭示
{"title":"Skeletal muscle stem cell defects in burn‐induced cachexia","authors":"J. Farup, A. Torcinaro, L. Madaro","doi":"10.1113/JP273095","DOIUrl":"https://doi.org/10.1113/JP273095","url":null,"abstract":"Satellite cells (SCs), the skeletal muscle stem cells, are essential for muscle regeneration in genetic or autoimmune muscle diseases as well as after ischaemic, chemical or mechanical trauma to the myofibres. Furthermore, SCs are the primary source to supply new myonuclei to growing myofibres during non-traumatic mechanical overload. Thus, when SCs are conditionally ablated using a tamoxifen inducible Cre-LoxP system, the addition of myonuclei during overload is abrogated (McCarthy et al. 2011). However, despite the lack of myonuclei addition, substantial hypertrophy could be induced in SC-ablated mice (McCarthy et al. 2011). More recent evidence, however, indicates that the ability of SC-depleted muscles to hypertrophy could be compromised during the later stages of muscle hypertrophy (Fry et al. 2014). Thus, while myonuclei addition, due to the fusion of muscle progenitors, may not be a prerequisite for initial muscle hypertrophy, a functional pool of SCs still play a key role during muscle hypertrophy. In contrast, less is known concerning the role of SCs and myonuclei turnover (e.g. myonuclei loss through apoptosis) during myofibre atrophy. Previous studies indicate that myofibre atrophy, for instance during immobilization or disease (cachexia), is generally not associated with a loss of myonuclei or an increase of DNA damage and apoptosis (Bruusgaard et al. 2012; Suetta et al. 2012). In an intriguing recent paper published in The Journal of Physiology, Fry and colleagues (Fry et al. 2016) explore the potential involvement of SCs and myonuclei apoptosis in young burn patients, a condition characterized by hyper-metabolism and extreme muscle wasting. Biopsies of vastus lateralis muscle were collected from patients (children between 8 and 18 years), with burns encompassing more than 30% of their total body area, during the flow phase of their recovery (characterized by hyper-metabolic demand). Biopsies were also collected from vastus lateralis muscles in a healthy control group, including males between 18 and 29 years of age, for comparison purposes. Through extensive immunohistochemical analyses, the authors collected information on myonuclei apoptosis (deoxynucleotidyl transferase dUTP nick end labelling (TUNEL) and caspase-3 positive myonuclei), SC content and activity Ki67/Myogenic differentiation 1 (MyoD) expression, SC apoptosis (TUNEL positive satellite cells), muscle regeneration by analysing embryonic myosin heavy chain (embMHC) expression and levels of connective tissue content (by wheat germ agglutinin staining). The authors hypothesized that severe burn trauma could induce myonuclear apoptosis along with increased SC activation, in order to counteract the loss of myonuclei. In brief, the major findings by Fry and colleagues were (summarized in Table 1): (1) burn trauma induces myonuclear and SC apoptosis, (2) SC content is decreased although the content of active SCs is increased in burn patients, and (3) the latter two are associa","PeriodicalId":22512,"journal":{"name":"The Japanese journal of physiology","volume":"1 1","pages":""},"PeriodicalIF":0.0,"publicationDate":"2016-12-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"88317004","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
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