Endurance exercise generates CO2 via aerobic metabolism; however, its role remains unclear. Exogenous CO2 by transcutaneous delivery promotes muscle fibre-type switching to increase endurance power in skeletal muscles. Here we determined the performance of rats running in activity wheels with/without transcutaneous CO2 exposure to clarify its effect on endurance exercise and recovery from muscle fatigue. Rats were randomised to control, training and CO2 groups. Endurance exercise included activity-wheel running with/without transcutaneous CO2 delivery. Running performance was measured after exercise initiation. We also analysed changes in muscle weight and muscle fibres in the tibialis anterior muscle. Running performance improved over the treatment period in the CO2 group, with a concomitant switch in muscle fibres to slow-type. The mitochondrial DNA content and capillary density in the CO2 group increased. CO2 was beneficial for performance and muscle development during endurance exercise: it may enhance recovery from fatigue and support anabolic metabolism in skeletal muscles.
All animals generate energy by consuming oxygen (O2) and releasing carbon dioxide (CO2). Aerobic metabolism is performed with O2 for energy production in the mitochondria [1, 2] using not only carbohydrates but also amino acids and fatty acids [1, 3]. CO2 generated during aerobic metabolism is not merely a waste product but serves other important functions.
One role of CO2 is vasodilation, with important implications in central nervous system function  and physiology . CO2 also exerts the Bohr effect on haemoglobin in red blood cells [6, 7], which have high levels of carbonic anhydrase that ionises CO2 to carbonate and hydrogen ions . Accumulating hydrogen ions dissociate O2 from oxyhaemoglobin. Thus, tissues with increased CO2 content can acquire necessary O2 via the Bohr effect. Importantly, the Bohr effect can be achieved via exogenous CO2 . Moreover, we previously showed that transcutaneous CO2 delivery to the hind limbs of rats upregulated peroxisome proliferator-activated receptor-gamma coactivator-1α (PGC-1α) and vascular endothelial growth factor (VEGF) expression as well as the number of mitochondria. Furthermore, this approach promoted a change in muscle fibre type from IIB to IIA, similar to that observed in tibialis anterior (TA) muscles after aerobic exercise . A recent study also suggested that carbonate ion-mediated PGC-1α upregulation might promote a fast-to-slow fibre-type shift in muscle cells .
Aerobic exercise is an actively performed exercise that utilises aerobic metabolism [2, 12]; endurance exercise is typically referred to as aerobic exercise [12, 13]. Repeated performance of endurance exercise increases aerobic metabolism via a positive-feedback loop along with transformation of muscle fibres and subsequent muscle endurance . Studies show that the upregulation of PGC-1α gene expression plays a major role in muscle fibre transformation [14,15,16]. PGC-1α in muscles not only increases the transcriptional activity of the mitochondrial transcriptional factor A (TFAM) but also induces capillary density by activating VEGF. As a result, slow-twitch muscle fibres shift, in order, to type IIB, IID, IIA and I fibres; consequently, muscle endurance is increased and endurance exercise performance is enhanced [17, 18].
The responses to exogenous CO2 and endurance exercise are similar, and include changes, such as mitochondrial biogenesis, in muscle fibers following increase in PGC-1α, and increase in capillary density by activating VEGF. However, the relationship between endurance exercise and exogenous CO2 remains unclear. Therefore, we hypothesised that the application of exogenous CO2 may support exercise endurance and evaluated whether transcutaneous CO2 application after endurance exercise increased endurance performance and aerobic capacity in rats. Supplementing CO2 therapy during endurance exercise may be beneficial for long-distance runners as well as patients with reduced muscle capacity for endurance who might require postoperative rehabilitation.
Materials and methods
Animal care and experimental design
The use of animals was approved by the Animal Care and Use Committee of Kobe University Graduate School of Medicine (approval number, P100408). A total of 24 male Wistar rats that were 5 weeks old (CLEA Japan, Tokyo, Japan) were used for all experiments. Animals were fed ad libitum and housed in a thermostatic environment at 21 °C under a 12-h light/12-h dark cycle.
As depicted in Fig. 1a, rats were initially divided into two groups, exercise (n = 16) and no exercise (control group; n = 8), and further divided according to average body weight. All rats were pre-trained using a 5-day programme that comprised activity-wheel running for 30 min every day. On the 6th day, rats in the exercise group were then randomly assigned to one of the two experimental groups: CO2 treatment (CO2 group, n = 8) and no treatment (training group, n = 8). Both experimental groups were subdivided according to average running distance and body weight.
Measurement of running distance
We measured the total running distance during exercise every day to analyse running performance. Data for the running distance were expressed as a percentage of running distance during pre-training.
To evaluate time-dependent change, we recorded the distance run at 5-min intervals on the final day (day 28). Data were presented as average in the CO2 group compared with those in the training group.
Activity wheels were purchased from Hoei Kinzoku Kogyo (Aichi, Japan), as previously described [19, 20]. The wheels measured 1 m in circumference and 14 cm in depth. We measured the initial torques using torque-measuring equipment (Sugisaki Meter Co., Ltd, Ibaraki, Japan); the initial torque was less than 1 mN (Fig. 1b). The wheels had a magnetic counting system that recorded the number of rotations to determine the running distance.
Transcutaneous CO2 absorption-enhancing hydrogel was provided by NeoChemir Inc. (Kobe, Japan) as previously described [9, 10, 21]. Briefly, all animals in the three groups were anaesthetised with diethyl ether (Wako Pure Chemical Industries, Osaka, Japan), hair on their hind limbs was shaved, and CO2 hydrogel was applied to their hind limbs. The area of skin covered with the CO2 hydrogel was sealed with an adaptor. In only the CO2 group rats, 100% CO2 gas (Kobe Sanso KK, Kobe, Japan) was flowed into the area for 10 min, as previously described [10, 21]. The CO2 group underwent this treatment every time after the training.
The expected mechanism of the transcutaneous CO2 application was as follows. Because of its relatively high solubility, CO2 gas dissolves in the hydrogel. The dissolved CO2 then permeates the skin, moving down its concentration gradient when the maximum solubility in the hydrogel is reached. Our previous study showed that CO2 penetrated human tissue by this system .
Muscle isolation and preparation
Animals were sacrificed with an overdose of the anaesthetic pentobarbital at 24 h after final exercise and/or treatment, followed by decapitation and dissection of intact TA muscles in order to analyse changes in muscle fibre types. Muscles were then weighed with an electronic balance (A&D, Japan) after removing excess connective tissue, immediately frozen in isopentane precooled with liquid nitrogen and stored at −80 °C. Serial 10-μm-thick transverse sections were prepared from each block. Muscle weight ratio was calculated by the following equation: muscle weight ratio = muscle weight/body weight × 100.
Isolation of myosin heavy chain
Protein was isolated from 10-mg transverse slices of the mid-belly of TA muscles using urea buffer, and 5–20 μl of homogenates were analysed for the expression of myosin heavy chain (MHC) isoforms by two-dimensional electrophoresis, as previously described [10, 22, 23]. After electrophoresis, gels were stained using the Wako Silver Stain Kit (Wako Pure Chemical Industries), and images of MHC bands were captured with a LAS-3000 imager to quantify band intensities using ImageJ software (https://imagej.nih.gov/ij/). Changes in MHC isoform expression among the three groups were presented as percent changes from pre-training values.
Mitochondrial DNA copy number
Genomic DNA was isolated from 10-mg transverse slices of mid-belly TA muscles using a GenElute™ Mammalian Genomic DNA Miniprep Kit (Sigma-Aldrich, St. Louis, MO, USA). Mitochondrial DNA (mtDNA) content relative to the β-actin gene copy number was measured using real-time PCR, as previously described [10, 23].
Quantitative real-time PCR
Quantification of mtDNA was performed using a StepOne™ Real-Time PCR System (Applied Biosystems). Real-time PCR reactions (20 μl) contained 0.5 μM each of forward and reverse primers, 1 μl genomic DNA template from the reverse transcription reaction and 10 μl Power SYBER Green PCR Master Mix (Applied Biosystems). Reaction conditions were 10 min at 95 °C, followed by 40 cycles at 95 °C (15 s) and 60 °C (1 min). mtDNA copy numbers were normalised to nuclear DNA copy numbers and compared among groups (∆∆Ct method; Applied Biosystems), as previously described [10, 24]. The following forward and reverse primers were used to determine mtDNA copy numbers: 5′-ACA CCA AAA GGA CGA ACC TG-3′ and 5′-ATG GGG AAG AAG CCC TAG AA-3′, respectively. Nuclear DNA (β-actin) forward and reverse primers were 5′-GCG GTG ACC ATA GCC CTC TTT-3′ and 5′-TGC CAC TCC CAA AGT AAA GGG TCA-3′, respectively. Primers were purchased from Invitrogen (Carlsbad, CA, USA).
Morphometric evaluation of capillary density
Skeletal muscle tissues cut into slices along the axial plane were washed in phosphate-buffered saline and incubated in MitoTracker Deep Red FM (Molecular Probes, Thermo Fisher Scientific, Carlsbad, CA, USA) and isolectin B4 (Vector Laboratories, Burlingame, CA, USA) at 37 °C for 1 h according to the manufacturer’s protocol. Images from stained slices were captured using a BZ-8100 microscope (Keyence, Osaka, Japan), as previously described [25, 26]. All morphometric studies were performed by an examiner blind to the treatments. Capillary density was measured by quantification of isolectin B4 staining (green fluorescence) in randomly selected fields (250 × 250 μm) of muscle specimens using Image J software, as previously described [25, 26].
The level of statistical significance was set at p < 0.05. Data were expressed as mean ± standard deviation. Significance was determined via analysis of variance (ANOVA) and the two-tailed Mann–Whitney U test.
As shown in Fig. 2a, although the running distance was longer in the CO2 group than in the training group after 1 week, the difference was not statistically significant. However, rats that received transcutaneous CO2 ran significantly longer distances than those in the training group at 2, 3 and 4 weeks after treatment (p < 0.05, n = 8 in each group).
Figure 2b shows the running distances and speeds at 5-min intervals over 30 min on the final day. In the first stage (0–10 min), the running performance did not differ between the training and CO2 groups. However, the CO2 group had progressively increased speed and ran a longer distance, and the running performance of this group was significantly higher than that of the training group in the last stage (25–30 min, p < 0.05, n = 8 in each group).
The muscle weight and muscle weight ratio tended to be higher in both exercise groups than those in the control group. After the 4 weeks of training, the TA muscle weight and muscle weight ratio in the CO2, training and control groups were as follows: 0.464 ± 0.026 g and 0.171 ± 0.007, 0.464 ± 0.056 g and 0.173 ± 0.008, 0.443 ± 0.016 g and 0.161 ± 0.005, respectively. Therefore, activity-wheel running exercise for 30 min for 5 days/week for 4 weeks led to increased muscle weight; however, there were no significant differences between the groups (p = 0.08, n = 8 in each group).
Muscle fibre type
The mean percentage of type IIB fibres decreased while that of type IID and/or IIA fibres increased in both the CO2 and training groups. There were significant differences in the percentages of IIA, IID and IIB fibres between the control and CO2 groups (Figs. 3, 4a, b; p < 0.01, n = 6 in each group). These results indicated that in comparison with non-transcutaneous CO2 delivery, transcutaneous CO2 delivery following pre-training led to the change of a significantly higher percentage of muscle fibres from type IIB to type IIA.
Capillary density and mitochondrial number in muscle
The mean capillary density in the CO2 group was significantly higher than that in the control group (Fig. 5a, b; p < 0.05, n = 4 in each group). Moreover, the amount of mitochondrial DNA in the CO2 group was significantly higher than that in the control group, as determined by real-time PCR (Fig. 6; p < 0.05, n = 4 in each group). The results showed that although there were differences in the number of muscle mitochondria and the capillary density between the training and the control groups as well as between the CO2 and the training groups, these were not statistically significant.
In the present study, running performance evaluated at 2, 3 and 4 weeks after intervention was significantly higher in rats that received transcutaneous CO2 than that in rats that were trained but did not receive treatment. This difference might be due to an increase in muscle weight, change in muscle fibre type from IIB to IIA and/or IID and increase in capillary density and mitochondrial number within the muscle as a result of CO2 treatment. Muscle fibres usually switch from type IIB to type IID and/or IIA fibres as a result of training . However, in the present study, training after transcutaneous CO2 treatment resulted in a higher percentage of TA muscle fibres changing to type IIA and/or IID when compared with animals that were trained without CO2 application. Type IIA, IID and IIB fibres differ in ATP production, mitochondrial number and capillary density. In general, in skeletal muscles, type IIA and IID fibres have a higher capacity for ATP production and higher mitochondrial numbers and capillary density compared with type IIB fibres [22, 23]. Transcutaneous CO2 delivery led to increased mitochondrial number and capillary density, providing evidence that this therapeutic approach might potentially aid in the performance of endurance exercise.
Gaseous molecules control various cellular signalling pathways in the body [27,28,29]. CO2 is an important gaseous molecule with well-defined roles [6, 30], including those related to nitric oxide . In addition, CO2 therapies, including carbonate spa and artificial CO2-enriched water, are used in many medical conditions, such as cardiac, ischaemic diseases [31, 32], and Raynaud’s phenomenon . However, the mechanism and potential of CO2 as a therapeutic modality are not well known. Moreover, CO2 concentration of saturated CO2-enriched water is only 0.1%, and there is little evidence of CO2 absorption into the human body. Therefore, we previously used near-infrared spectroscopy to demonstrate that a novel transcutaneous application of CO2 upregulated O2 pressure in the local tissue and showed, for the first time, that our transcutaneous CO2 system could cause absorption of CO2 and the Bohr effect in the human body  and suggested that these results might be applicable in human cases.
Our findings suggest that CO2 enhances the performance of endurance exercise in rats. Moreover, we previously demonstrated that CO2 activated PGC-1α gene expression and increased the endurance potential in skeletal muscles . Together with the results presented herein, these findings strongly suggest that CO2 therapy might improve endurance. Moreover, several studies demonstrated that endurance exercise induced PGC-1α gene expression via Ca2+ influx and AMPK pathway activation [11, 34]. Based on our previous study showing that transcutaneous CO2 delivery induced Ca2+ influx into cells, these results altogether suggest that endurance exercise improves performance by CO2-mediated PGC-1α upregulation and Ca2+ influx.
Aerobic metabolism occurs in mitochondria . The number of mitochondria increases as a result of upregulation of PGC-1α and skeletal muscle activity during aerobic exercise or recovery from muscle injury [35, 36]. Skeletal muscle includes fast (white) muscle fibres that provide instant power and slow (red) muscle fibres that provide endurance. Exercise training was extensively shown to increase the mitochondrial content of skeletal muscles [11, 35, 36]; however, the underlying mechanisms directing this adaptive response are incompletely understood. Increases in mitochondrial function require complex coordination of genes encoded by nuclear and mitochondrial DNA [37, 38]. PGC-1α appears to play an integral role in regulating the transcription of mitochondrial and nuclear genes [37, 38]. Our previous results suggested that transcutaneous CO2 application increased nuclear PGC-1α protein and induced mitochondrial biogenesis [10, 38]. Therefore, an increase in mitochondrial number by transcutaneous CO2 delivery might lead to a significant increase in aerobic capacity.
CO2 therapy is supported by some scientific evidence. One is that CO2 increases blood flow, and our transcutaneous CO2 application has shown increased blood flow in the deep tissue [9, 21]. There is a relationship between blood flow volume and muscle fatigue, and increased blood flow reduced muscle fatigue . Therefore, there may be a possibility that transcutaneous CO2 application might increase the performance of endurance exercise via the reduction of muscle fatigue. Another piece of evidence is that this model of CO2 therapy accelerates muscle injury repair in rat models . This research was able to explain that this form of CO2 therapy may increase next-day performance via muscle injury repair.
This study includes several limitations. First, our experimental design did not include a group that received CO2 but no training. However, in our previous study, we demonstrated that transcutaneous CO2 in the absence of exercise training upregulated PGC-1α gene expression and promoted muscle fibre changing to increase endurance in skeletal muscles . Therefore, the present study focused on whether CO2 enhanced endurance exercise performance. Second, only TA muscle was analysed at the end of the 4-week experiment. Most studies investigating endurance exercise in rat models use longer durations such as 45 days  and 10 weeks . Because the duration of our study was shorter than those of previous studies, there was little change in muscle fibres of the training group. However, this research aimed to assess the role of the CO2 effect. Compared with the control group, the CO2 group showed the most transformation in muscle fibres, followed by the training group. We could not show effects on human performance in this study. Ishida et al. have reported the lack of an effect of CO2 on human exercise performance . However, another study did find an effect . Overall, the CO2 effect on exercise performance is not well understood. We have previously described CO2 permeation of rat skin  and that the Bohr effect increased and pH decreased following transcutaneous CO2 application in humans . Therefore, we propose further study of transcutaneous CO2 application in animals and humans.
Based on the findings of the current study, we suggest that CO2 regulation might enhance performance in endurance exercise. Moreover, transcutaneous CO2 delivery should be considered as a potential therapeutic approach in patients recovering from injury or in those with damaged tissue that requires O2 and energy.
Alberts B, Johnson A, Lewis J, Morgan D, Raff M, Roberts K, Walter P (2014) Molecular biology of the cell. Garland Science, New York, pp 753–812
Boyadjiev N, Delchev S, Hristova M (1997) Changes in the aerobic capacity and ultrastructure of skeletal muscles and myocardium of endurance training rats induced by specialized food supplements with different compositions. Folia Med 39:20–30
Alberts B, Bray D, Hopkin K, Johnson A, Lewis J, Raff M, Roberts K, Walter P (2013) Essential cell biology. Garland Science, New York, pp 425–494
Sato K, Sadamoto T, Hirasawa A, Oue A, Subudhi AW, Miyazawa T, Ogoh S (2012) Differential blood flow responses to CO2 in human internal and external carotid and vertebral arteries. J Physiol 590:3277–3290
Mador MJ, Tobin MJ (1992) The effect of inspiratory muscle fatigue on breathing pattern and ventilatory response to CO2. J Physiol 455:17–32
Bohr C, Hasselbach K, Krogh A (1904) Concerning a biologically important relationship—the influence of the carbon dioxide content of blood on its oxygen binding. Skand Arch Physiol 16:402–412
Jensen FB (2004) Red blood cell pH, the Bohr effect, and other oxygenation-linked phenomena in blood O2 and CO2 transport. Acta Physiol Scand 182:215–227
Swietach P, Tiffert T, Mauritz JM, Seear R, Esposito A, Kaminski CF, Lew VL, Vaughan-Jones RD (2010) Hydrogen ion dynamics in human red blood cells. J Physiol 588:4995–5014
Sakai Y, Miwa M, Oe K, Ueha T, Koh A, Niikura T, Iwakura T, Lee SY, Tanaka M, Kurosaka M (2011) A novel system for transcutaneous application of carbon dioxide causing an “artificial Bohr effect” in the human body. PLoS One 6:e24137
Oe K, Ueha T, Sakai Y, Niikura T, Lee SY, Koh A, Hasegawa T, Tanaka M, Miwa M, Kurosaka M (2011) The effect of transcutaneous application of carbon dioxide (CO2) on skeletal muscle. Biochem Biophys Res Commun 407:148–152
Yamaguchi T, Suzuki T, Arai H, Tanabe S, Atomi Y (2010) Continuous mild heat stress induces differentiation of mammalian myoblasts, shifting fiber type from fast to slow. Am J Physiol Cell Physiol 298:C140–C148
Rowe GC, Safdar A, Arany Z (2014) Running forward: new frontiers in endurance exercise biology. Circulation 129:798–810
Ju JS, Jeon SI, Park JY, Lee JY, Lee SC, Cho KJ, Jeong JM (2016) Autophagy plays a role in skeletal muscle mitochondrial biogenesis in an endurance exercise-trained condition. J Physiol Sci 66:417–430
Popov DV, Bachinin AV, Lysenko EA, Miller TF, Vinogradova OL (2014) Exercise-induced expression of peroxisome proliferator-activated receptor γ coactivator-1α isoforms in skeletal muscle of endurance-trained males. J Physiol Sci 64:317–323
Iwabu M, Yamauchi T, Okada-Iwabu M, Sato K, Nakagawa T, Funata M, Yamaguchi M, Namiki S, Nakayama R, Tabata M, Ogata H, Kubota N, Takamoto I, Hayashi YK, Yamauchi N, Waki H, Fukayama M, Nishino I, Tokuyama K, Ueki K, Oike Y, Ishii S, Hirose K, Shimizu T, Touhara K, Kadowaki T (2010) Adiponectin and AdipoR1 regulate PGC-1alpha and mitochondria by Ca2+ and AMPK/SIRT1. Nature 464:1313–1319
Scarpulla RC (2008) Nuclear control of respiratory chain expression by nuclear respiratory factors and PGC-1-related coactivator. Ann N Y Acad Sci 1147:321–334
Yan Z, Lira VA, Greene NP (2012) Exercise training-induced regulation of mitochondrial quality. Exerc Sport Sci Rev 40:159–164
Baar K (2014) Nutrition and the adaptation to endurance training. Sports Med 44:5–12
Masaki T, Nakajima S (2008) Forward conditioning with wheel running causes place aversion in rats. Behav Processes 79:43–47
Masaki T, Nakajima S (2006) Taste aversion in rats induced by forced swimming, voluntary running, forced running, and lithium chloride injection treatments. Physiol Behav 88:411–416
Koga T, Niikura T, Lee SY, Okumachi E, Ueha T, Iwakura T, Sakai Y, Miwa M, Kuroda R, Kurosaka M (2014) Topical cutaneous CO2 application by means of a novel hydrogel accelerates fracture repair in rats. J Bone Joint Surg Am 96:2077–2084
Wada M, Inashima S, Yamada T, Matsunaga S (1985) Endurance training-induced changes in alkali light chain patterns in type IIB fibers of the rat. J Appl Physiol 94:923–929
Ennion S, Sant’ana Pereira J, Sargeant AJ, Young A, Goldspink G (1995) Characterization of human skeletal muscle fibres according to the myosin heavy chains they express. J Muscle Res Cell Motil 16:35–43
Onishi Y, Ueha T, Kawamoto T, Hara H, Toda M, Harada R, Minoda M, Kurosaka M, Akisue T (2014) Regulation of mitochondrial proliferation by PGC-1α induces cellular apoptosis in musculoskeletal malignancies. Sci Rep 4:3916
Tei K, Matsumoto T, Mifune Y, Ishida K, Sasaki K, Shoji T, Kubo S, Kawamoto A, Asahara T, Kurosaka M, Kuroda R (2008) Administrations of peripheral blood CD34-positive cells contribute to medial collateral ligament healing via vasculogenesis. Stem Cells 26:819–830
Okumachi E, Lee SY, Niikura T, Iwakura T, Dogaki Y, Waki T, Takahara S, Ueha T, Sakai Y, Kuroda R, Kurosaka M (2015) Comparative analysis of rat mesenchymal stem cells derived from slow and fast skeletal muscle in vitro. Int Orthop 39:569–576
Kajimura M, Fukuda R, Bateman RM, Yamamoto T, Suematsu M (2010) Interactions of multiple gas-transducing systems: hallmarks and uncertainties of CO, NO, and H2S gas biology. Antioxid Redox Signal 13:157–192
Kajimura M, Nakanishi T, Takenouchi T, Morikawa T, Hishiki T, Yukutake Y, Suematsu M (2012) Gas biology: tiny molecules controlling metabolic systems. Respir Physiol Neurobiol 184:139–148
Kashiba M, Kajimura M, Goda N, Suematsu M (2002) From O2 to H2S: a landscape view of gas biology. Keio J Med 51:1–10
Irie H, Tatsumi T, Takamiya M, Zen K, Takahashi T, Azuma A, Tateishi K, Nomura T, Hayashi H, Nakajima N, Okigaki M, Matsubara H (2005) Carbon dioxide-rich water bathing enhances collateral blood flow in ischemic hindlimb via mobilization of endothelial progenitor cells and activation of NO-cGMP system. Circulation 111:1523–1529
Savin E, Bailliart O, Bonnin P, Bedu M, Cheynel J, Coudert J, Martineaud JP (1995) Vasomotor effects of transcutaneous CO2 in stage II peripheral occlusive arterial disease. Angiology 46:785–791
Toriyama T, Kumada Y, Matsubara T, Murata A, Ogino A, Hayashi H, Nakashima H, Takahashi H, Matsuo H, Kawahara H (2002) Effect of artificial carbon dioxide foot bathing on critical limb ischemia (Fontaine IV) in peripheral arterial disease patients. Int Angiol 21:367–373
Calegari VC, Zoppi CC, Rezende LF, Silveira LR, Carneiro EM, Boschero AC (2011) Endurance training activates AMP-activated protein kinase, increases expression of uncoupling protein 2 and reduces insulin secretion from rat pancreatic islets. J Endocrinol 208:257–264
Holloszy JO (1975) Adaptation of skeletal muscle to endurance exercise. Med Sci Sports 7:155–164
Holloszy JO, Booth FW (1976) Biochemical adaptations to endurance exercise in muscle. Annu Rev Physiol 38:273–291
Scarpulla RC (2006) Nuclear control of respiratory gene expression in mammalian cells. J Cell Biochem 97:673–683
Onishi Y, Kawamoto T, Ueha T, Kishimoto K, Hara H, Fukase N, Toda M, Harada R, Minoda M, Sakai Y, Miwa M, Kurosaka M, Akisue T (2012) Transcutaneous application of carbon dioxide (CO2) induces mitochondrial apoptosis in human malignant fibrous histiocytoma in vivo. PLoS One 7:e49189
Legerlotz K, Elliott B, Guillemin Smith HK (2008) Voluntary resistance running wheel activity pattern and skeletal muscle growth in rats. Exp Physiol 93:754–762
Sugaya M, Sakamaki M, Ozaki H, Ogasawara R, Sato Y, Yasuda T, Abe T (2011) Influence of decreased muscular blood flow induced by external compression on muscle activation and maximal strength after a single bout of low-intensity exercise. Jpn J Phys Educ Health Sport Sci 56:481–489. https://www.jstage.jst.go.jp/article/jjpehss/56/2/56_10027/_article
Akahane S, Sakai Y, Ueha T, Nishimoto H, Inoue M, Niikura T, Kuroda R (2017) Transcutaneous carbon dioxide application accelerates muscle injury repair in rat models. Int Orthop 41(5):1007–1015 (Epub ahead of print)
Malek MH, Olfert IM, Esposito F (2010) Detraining losses of skeletal muscle capillarization are associated with vascular endothelial growth factor protein expression in rats. Exp Physiol 95:359–368
Termin A, Staron RS, Pette D (1989) Myosin heavy chain isoforms in histochemically defined fiber types of rat muscle. Histochemistry 92:453–457
Ishida K, Hiruta S, Miyamura M (1988) Effects of CO2 inhalation prior to maximal exercise on physical performance. Jpn J Physiol 38:929–933
Graham T, Wilson BA, Sample M, Van Dijk J, Bonen A (1980) The effects of hypercapnia on metabolic responses to progressive exhaustive work. Med Sci Sports Exerc 12:278–284
The authors wish to express their sincere gratitude to Professor Masanobu Wada (Graduate School of Integrated Arts and Sciences, Hiroshima University) for his excellent technical assistance in ATPase staining and myosin heavy chain isolation, and Professor Sadahiko Nakajima and Dr. Takahisa Masaki (Graduate School of Department of Literature, Psychology, Kanseigakuin University) for their excellent technical assistance in the activity-wheel running programme.
Conflict of interest
The CO2 hydro-gel used in this study was provided by NeoChemir Inc.; it is patented by NeoChemir Inc. (international publication number WO2004/002393; publication date, 8 January, 2004). In addition, the use of CO2 delivery for muscle strengthening is patented by National University Corporation Kobe University and NeoChemir Inc. (international publication number WO2009/054501; date, 30 April 2009).
This study was supported by grants from the Division of Rehabilitation Medicine and Department of Orthopaedic Surgery, Kobe University Graduate School of Medicine, and a Grant-in-Aid for Scientific Research (C) from the Japan Society for the Promotion of Science (25350814 to YS).
All procedures performed in studies involving animals were in accordance with the ethical standards of the institution or practice at which the studies were conducted.
About this article
Cite this article
Ueha, T., Oe, K., Miwa, M. et al. Increase in carbon dioxide accelerates the performance of endurance exercise in rats. J Physiol Sci 68, 463–470 (2018). https://doi.org/10.1007/s12576-017-0548-6
- Activity wheel
- Carbon dioxide
- Endurance exercise
- Running performance