Higher bone remodeling biomarkers are related to a higher muscle function in older adults: Effects of acute exercise

Cassandra Smith; Danielle Hiam; Alexander Tacey; Xuzhu Lin; Mary N. Woessner; Navabeh Zarekookandeh; Andrew Garnham; Paul Chubb; Joshua R. Lewis; Marc Sim; Markus Herrmann; Gustavo Duque; Itamar Levinger

doi:10.1016/j.bone.2022.116545

Higher bone remodeling biomarkers are related to a higher muscle function in older adults: Effects of acute exercise

Cassandra Smith, Danielle Hiam, Alexander Tacey, Xuzhu Lin, Mary N. Woessner, Navabeh Zarekookandeh, Andrew Garnham, Paul Chubb, Joshua R. Lewis, Marc Sim, Markus Herrmann, Gustavo Duque, Itamar Levinger

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

Bone and muscle are closely linked mechanically and biochemically. Bone hormones secreted during bone remodeling might be linked to muscle mass and strength maintenance. Exercise elicits high mechanical strain and is essential for bone health. However, the relationship between commonly used bone turnover markers (BTMs) and muscle function in community dwelling older adults remains unclear. It is also unknown how acute exercise with differing mechanical strain may affect BTMs, and whether baseline muscle function alters BTM responses differently. We tested the hypothesis that BTMs are associated with muscle function, and that acute exercise could change the circulating levels of BTMs. Thirty-five older adults (25 females/10 males, 72.8 ± 6.0 years) participated. Baseline assessments included body composition (DXA), handgrip strength and a physical performance test (PPT) (gait speed, timed-up-and-go [TUG], stair ascent/descent). Leg muscle quality (LMQ) and stair climb power (SCP) were calculated. Participants performed (randomized) 30 min aerobic (AE) (cycling 70%HRPeak) and resistance (RE) (leg press 70%RM, jumping) exercise. Serum β-isomerized C-terminal telopeptides (β-CTX), procollagen of type I propeptide (P1NP), total osteocalcin (t)OC and ucOC were assessed at baseline and post-exercise. Data were analyzed using linear mixed models and simple regressions, adjusted for sex. At baseline, higher muscle strength (LMQ, handgrip) was related to higher P1NP, higher SCP was related to higher P1NP and β-CTX, and better physical performance (lower PPT) related to higher P1NP and β-CTX (p < 0.05). Exercise, regardless of mode, decreased β-CTX and tOC (all p < 0.05), while P1NP and ucOC remained unaltered. Higher baseline handgrip strength, SCP and LMQ was associated with lower post-exercise β-CTX responses, and poorer baseline mobility (increased TUG time) was associated with higher post-exercise β-CTX. Independently of exercise mode, acute exercise decreased β-CTX and tOC. Our data suggest that in older adults at baseline, increased BTM levels were linked to better muscle function. Altogether, our data strengthens the evidence for bone-muscle interaction, however, mechanisms behind this specific component of bone-muscle crostalk remain unclear.

Original language	English
Article number	116545
Journal	Bone
Volume	165
DOIs	https://doi.org/10.1016/j.bone.2022.116545
Publication status	Published - Dec 2022

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10.1016/j.bone.2022.116545

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@article{ed716a95b861483486fd0fca269a4763,

title = "Higher bone remodeling biomarkers are related to a higher muscle function in older adults: Effects of acute exercise",

abstract = "Bone and muscle are closely linked mechanically and biochemically. Bone hormones secreted during bone remodeling might be linked to muscle mass and strength maintenance. Exercise elicits high mechanical strain and is essential for bone health. However, the relationship between commonly used bone turnover markers (BTMs) and muscle function in community dwelling older adults remains unclear. It is also unknown how acute exercise with differing mechanical strain may affect BTMs, and whether baseline muscle function alters BTM responses differently. We tested the hypothesis that BTMs are associated with muscle function, and that acute exercise could change the circulating levels of BTMs. Thirty-five older adults (25 females/10 males, 72.8 ± 6.0 years) participated. Baseline assessments included body composition (DXA), handgrip strength and a physical performance test (PPT) (gait speed, timed-up-and-go [TUG], stair ascent/descent). Leg muscle quality (LMQ) and stair climb power (SCP) were calculated. Participants performed (randomized) 30 min aerobic (AE) (cycling 70%HRPeak) and resistance (RE) (leg press 70%RM, jumping) exercise. Serum β-isomerized C-terminal telopeptides (β-CTX), procollagen of type I propeptide (P1NP), total osteocalcin (t)OC and ucOC were assessed at baseline and post-exercise. Data were analyzed using linear mixed models and simple regressions, adjusted for sex. At baseline, higher muscle strength (LMQ, handgrip) was related to higher P1NP, higher SCP was related to higher P1NP and β-CTX, and better physical performance (lower PPT) related to higher P1NP and β-CTX (p < 0.05). Exercise, regardless of mode, decreased β-CTX and tOC (all p < 0.05), while P1NP and ucOC remained unaltered. Higher baseline handgrip strength, SCP and LMQ was associated with lower post-exercise β-CTX responses, and poorer baseline mobility (increased TUG time) was associated with higher post-exercise β-CTX. Independently of exercise mode, acute exercise decreased β-CTX and tOC. Our data suggest that in older adults at baseline, increased BTM levels were linked to better muscle function. Altogether, our data strengthens the evidence for bone-muscle interaction, however, mechanisms behind this specific component of bone-muscle crostalk remain unclear.",

keywords = "Aging, Biochemical markers of bone turnover, Bone-muscle interactions, Exercise, Skeletal muscle",

author = "Cassandra Smith and Danielle Hiam and Alexander Tacey and Xuzhu Lin and Woessner, {Mary N.} and Navabeh Zarekookandeh and Andrew Garnham and Paul Chubb and Lewis, {Joshua R.} and Marc Sim and Markus Herrmann and Gustavo Duque and Itamar Levinger",

note = "Funding Information: This work is supported by research funds of the primary investigators, IL and GD, and the PhD (Doctor of Philosophy) funds of CS. This trial was awarded the Tom Penrose Community Service Award from Exercise and Sport Science Australia, and a seed grant from the Australian Institute for Musculoskeletal Science ( AIMSS ). The salary of MS is supported by a Royal Perth Hospital Research Foundation Career Advancement Fellowship ( CAF 130/2020 ) and an Emerging Leader Fellowship from the Western Australian Future Health Research and Innovation Fund . The salary of JRL is supported by a National Heart Foundation of Australia Future Leader Fellowship (ID: 102817 ), and the salary of CS is supported by this fellowship of JRL. The grants awarded to this trial did not have any role in or contribution to the design of the study and the collection, analysis, or interpretation of the data; the grants awarded to this trial will not contribute to the writing of any associated manuscripts. Publisher Copyright: {\textcopyright} 2022 Elsevier Inc.",

year = "2022",

month = dec,

doi = "10.1016/j.bone.2022.116545",

language = "English",

volume = "165",

journal = "Bone",

issn = "8756-3282",

publisher = "Academic Press",

}

TY - JOUR

T1 - Higher bone remodeling biomarkers are related to a higher muscle function in older adults

T2 - Effects of acute exercise

AU - Smith, Cassandra

AU - Hiam, Danielle

AU - Tacey, Alexander

AU - Lin, Xuzhu

AU - Woessner, Mary N.

AU - Zarekookandeh, Navabeh

AU - Garnham, Andrew

AU - Chubb, Paul

AU - Lewis, Joshua R.

AU - Sim, Marc

AU - Herrmann, Markus

AU - Duque, Gustavo

AU - Levinger, Itamar

N1 - Funding Information: This work is supported by research funds of the primary investigators, IL and GD, and the PhD (Doctor of Philosophy) funds of CS. This trial was awarded the Tom Penrose Community Service Award from Exercise and Sport Science Australia, and a seed grant from the Australian Institute for Musculoskeletal Science ( AIMSS ). The salary of MS is supported by a Royal Perth Hospital Research Foundation Career Advancement Fellowship ( CAF 130/2020 ) and an Emerging Leader Fellowship from the Western Australian Future Health Research and Innovation Fund . The salary of JRL is supported by a National Heart Foundation of Australia Future Leader Fellowship (ID: 102817 ), and the salary of CS is supported by this fellowship of JRL. The grants awarded to this trial did not have any role in or contribution to the design of the study and the collection, analysis, or interpretation of the data; the grants awarded to this trial will not contribute to the writing of any associated manuscripts. Publisher Copyright: © 2022 Elsevier Inc.

PY - 2022/12

Y1 - 2022/12

N2 - Bone and muscle are closely linked mechanically and biochemically. Bone hormones secreted during bone remodeling might be linked to muscle mass and strength maintenance. Exercise elicits high mechanical strain and is essential for bone health. However, the relationship between commonly used bone turnover markers (BTMs) and muscle function in community dwelling older adults remains unclear. It is also unknown how acute exercise with differing mechanical strain may affect BTMs, and whether baseline muscle function alters BTM responses differently. We tested the hypothesis that BTMs are associated with muscle function, and that acute exercise could change the circulating levels of BTMs. Thirty-five older adults (25 females/10 males, 72.8 ± 6.0 years) participated. Baseline assessments included body composition (DXA), handgrip strength and a physical performance test (PPT) (gait speed, timed-up-and-go [TUG], stair ascent/descent). Leg muscle quality (LMQ) and stair climb power (SCP) were calculated. Participants performed (randomized) 30 min aerobic (AE) (cycling 70%HRPeak) and resistance (RE) (leg press 70%RM, jumping) exercise. Serum β-isomerized C-terminal telopeptides (β-CTX), procollagen of type I propeptide (P1NP), total osteocalcin (t)OC and ucOC were assessed at baseline and post-exercise. Data were analyzed using linear mixed models and simple regressions, adjusted for sex. At baseline, higher muscle strength (LMQ, handgrip) was related to higher P1NP, higher SCP was related to higher P1NP and β-CTX, and better physical performance (lower PPT) related to higher P1NP and β-CTX (p < 0.05). Exercise, regardless of mode, decreased β-CTX and tOC (all p < 0.05), while P1NP and ucOC remained unaltered. Higher baseline handgrip strength, SCP and LMQ was associated with lower post-exercise β-CTX responses, and poorer baseline mobility (increased TUG time) was associated with higher post-exercise β-CTX. Independently of exercise mode, acute exercise decreased β-CTX and tOC. Our data suggest that in older adults at baseline, increased BTM levels were linked to better muscle function. Altogether, our data strengthens the evidence for bone-muscle interaction, however, mechanisms behind this specific component of bone-muscle crostalk remain unclear.

AB - Bone and muscle are closely linked mechanically and biochemically. Bone hormones secreted during bone remodeling might be linked to muscle mass and strength maintenance. Exercise elicits high mechanical strain and is essential for bone health. However, the relationship between commonly used bone turnover markers (BTMs) and muscle function in community dwelling older adults remains unclear. It is also unknown how acute exercise with differing mechanical strain may affect BTMs, and whether baseline muscle function alters BTM responses differently. We tested the hypothesis that BTMs are associated with muscle function, and that acute exercise could change the circulating levels of BTMs. Thirty-five older adults (25 females/10 males, 72.8 ± 6.0 years) participated. Baseline assessments included body composition (DXA), handgrip strength and a physical performance test (PPT) (gait speed, timed-up-and-go [TUG], stair ascent/descent). Leg muscle quality (LMQ) and stair climb power (SCP) were calculated. Participants performed (randomized) 30 min aerobic (AE) (cycling 70%HRPeak) and resistance (RE) (leg press 70%RM, jumping) exercise. Serum β-isomerized C-terminal telopeptides (β-CTX), procollagen of type I propeptide (P1NP), total osteocalcin (t)OC and ucOC were assessed at baseline and post-exercise. Data were analyzed using linear mixed models and simple regressions, adjusted for sex. At baseline, higher muscle strength (LMQ, handgrip) was related to higher P1NP, higher SCP was related to higher P1NP and β-CTX, and better physical performance (lower PPT) related to higher P1NP and β-CTX (p < 0.05). Exercise, regardless of mode, decreased β-CTX and tOC (all p < 0.05), while P1NP and ucOC remained unaltered. Higher baseline handgrip strength, SCP and LMQ was associated with lower post-exercise β-CTX responses, and poorer baseline mobility (increased TUG time) was associated with higher post-exercise β-CTX. Independently of exercise mode, acute exercise decreased β-CTX and tOC. Our data suggest that in older adults at baseline, increased BTM levels were linked to better muscle function. Altogether, our data strengthens the evidence for bone-muscle interaction, however, mechanisms behind this specific component of bone-muscle crostalk remain unclear.

KW - Aging

KW - Biochemical markers of bone turnover

KW - Bone-muscle interactions

KW - Exercise

KW - Skeletal muscle

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U2 - 10.1016/j.bone.2022.116545

DO - 10.1016/j.bone.2022.116545

M3 - Article

C2 - 36108920

AN - SCOPUS:85138825808

SN - 8756-3282

VL - 165

JO - Bone

JF - Bone

M1 - 116545

ER -

Higher bone remodeling biomarkers are related to a higher muscle function in older adults: Effects of acute exercise

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