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Abstract

Background:

Osteogenic responses induced by training under hypoxia remain unclear. We aimed to investigate whether intermittent hypoxic resistance training affects osteogenic responses.

Materials and Methods:

Sixteen male participants underwent resistance training under normoxia (NRT; n = 7) or hypoxia (HRT; O₂ = 14.4%, n = 9), twice a week for 8 weeks. The HRT group exercised and rested for 30 minutes under hypoxia, with total hypoxic exposure time in one session of ∼60 minutes. At pre- and postexperiment, bone mineral density (BMD) of the whole body and right proximal femur was measured. At the first and last training sessions, bone alkaline phosphatase (BAP), osteocalcin (OC), cross-linked N-telopeptide of type I collagen (NTx), type I collagen cross-linked C-telopeptide (ICTP), interleukin-6 (IL-6), and blood lactate (La) concentration were analyzed at rest and postexercise.

Results:

BMD did not change with training and hypoxia. Although BAP, OC, and ICTP levels at rest significantly increased with training (p < 0.01, 0.05, and 0.05, respectively), they did not change with hypoxia. NTx and IL-6 did not change. Additionally, changing patterns of bone markers and La induced by a single bout of exercise were similar among groups in both training sessions.

Conclusions:

Short-term resistance training enhanced overall bone metabolism, regardless of the oxygen level. Hypoxia has no effects on osteogenic responses.

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References

Arnett

. (2010). Acidosis, hypoxia and bone. Arch Biochem Biophys, 503:103–109.

Ashizawa

, Ouchi

, Fujimura

, Yoshida

, Tokuyama

, and Suzuki

. (1998). Effects of a single bout of resistance exercise on calcium and bone metabolism in untrained young males. Calcif Tissue Int, 62:104–108.

Banfi

, Lombardi

, Colombini

, and Lippi

. (2010). Bone metabolism markers in sports medicine. Sports Med, 40:697–714.

Basu

, Malhotra

, Pal

, Chatterjee

, Ghosh

, Haldar

, Verma

, Kumar

, Sharma

, and Sawhney

. (2013). Determination of bone mass using multisite quantitative ultrasound and biochemical markers of bone turnover during residency at extreme altitude: A longitudinal study. High Alt Med Biol, 14:150–154.

Evans

, Antczak

, Lester

, Yanovich

, Israeli

, and Moran

. (2008). Effects of 4-month recruit training program on markers of bone metabolism. Med Sci Sports Exerc, 40:S660–S670.

Feriche

, García-Ramos

, Morales-Artacho

, and Padial

. (2017). Resistance training using different hypoxic training strategies: A basis for hypertrophy and muscle power development. Sports Med Open, 3:12.

Frick

, Jiang

, and Bushinsky

. (1997). Acute metabolic acidosis inhibits the induction of osteoblastic egr-1 and type 1 collagen. Am J Physiol, 272:C1450–C1456.

Fujimura

, Ashizawa

, Watanabe

, Mukai

, Amagai

, Fukubayashi

, Hayashi

, Tokuyama

, and Suzuki

. (1997). Effect of resistance exercise training on bone formation and resorption in young male subjects assessed by biomarkers of bone metabolism. J Bone Miner Res, 12:656–662.

Gaffney-Stomberg

, Lutz

, Rood

, Cable

, Pasiakos

, Young

, and McClung

. (2014). Calcium and vitamin D supplementation maintains parathyroid hormone and improves bone density during initial military training: A randomized, double-blind, placebo controlled trial. Bone, 68:46–56.

10.

Guadalupe-Grau

, Fuentes

, Guerra

, and Calbet

. (2009). Exercise and bone mass in adults. Sports Med, 39:439–468.

11.

Herrmann

, Müller

, Scharhag

, Sand-Hill

, Kindermann

, and Herrmann

. (2007). The effect of endurance exercise-induced lactacidosis on biochemical markers of bone turnover. Clin Chem Lab Med, 45:1381–1389.

12.

Honda

, Matsumoto

, Kato

, and Umemura

. (2015). Exercise characteristics influence femoral cross-sectional geometry: A magnetic resonance imaging study in elite female athletes. Osteoporos Int, 26:1093–1098.

13.

Kato

, and Morita

. (2013). Promotion of osteoclast differentiation and activation in spite of impeded osteoblast-lineage differentiation under acidosis: Effects of acidosis on bone metabolism. Biosci Trends, 7:33–41.

14.

Kish

, Mezil

, Ward

, Klentrou

, and Falk

. (2015). Effects of plyometric exercise session on markers of bone turnover in boys and young men. Eur J Appl Physiol, 115:2115–2124.

15.

Kon

, Ikeda

, Homma

, Akimoto

, Suzuki

, and Kawahara

. (2010). Effects of acute hypoxia on metabolic and hormonal responses to resistance exercise. Med Sci Sports Exerc, 42:1279–1285.

16.

Kon

, Ohiwa

, Honda

, Matsubayashi

, Ikeda

, Akimoto

, Suzuki

, Hirano

, and Russell

. (2014). Effects of systemic hypoxia on human muscular adaptations to resistance exercise training. Physiol Rep, 2:e12033.

17.

Lester

, Urso

, Evans

, Pierce

, Spiering

, Maresh

, Hatfield

, Kraemer

, and Nindl

. (2009). Influence of exercise mode and osteogenic index on bone biomarker responses during short-term physical training. Bone, 45:768–776.

18.

Maïmoun

, and Sultan

. (2011). Effects of physical activity on bone remodeling. Metabolism, 60:373–388.

19.

Mezil

, Allison

, Kish

, Ditor

, Ward

, Tsiani

, and Klentrou

. (2015). Response of bone turnover markers and cytokines to high-intensity low-impact exercise. Med Sci Sports Exerc, 47:1495–1502.

20.

Nikander

, Kannus

, Rantalainen

, Uusi-Rasi

, Heinonen

, and Sievänen

. (2010). Cross-sectional geometry of weight-bearing tibia in female athletes subjected to different exercise loadings. Osteoporos Int, 21:1687–1694.

21.

Ravnholt

, Tybirk

, Jørgensen

, and Bangsbo

. (2018). High-intensity intermittent “5-10-15” running reduces body fat, and increases lean body mass, bone mineral density, and performance in untrained subjects. Eur J Appl Physiol, 118:1221–1230.

22.

Rogers

, Dawson

, Wang

, Thyfault

, and Hinton

. (2011). Acute response of plasma markers of bone turnover to a single bout of resistance training or plyometrics. J Appl Physiol, 111:1353–1360.

23.

Scott

, Slattery

, Sculley

, and Dascombe

. (2014). Hypoxia and resistance exercise: A comparison of localized and systemic methods. Sports Med, 44:1037–1054.

24.

Whipple

, Le

, Demers

, Chinchilli

, Petit

, Sharkey

, and Williams

. (2004). Acute effects of moderate intensity resistance exercise on bone cell activity. Int J Sports Med, 25:496–501.

25.

Woitge

, Friedmann

, Suttner

, Farahmand

, Müller

, Schmidt-Gayk

, Baertsch

, Ziegler

, and Seibel

. (1998). Changes in bone turnover induced by aerobic and anaerobic exercise in young males. J Bone Miner Res, 13:1797–1804.

Short-Term Intermittent Hypoxic Resistance Training Does Not Impair Osteogenic Response in Sea Level Residents