Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

Keynote webinar | Spotlight on medication adherence

LIVE: Thursday 27th June 2024, 18:00-19:30 (CEST)
Join our expert panel to discover why you need to understand the drivers of non-adherence in your patients, and how you can optimize medication adherence in your clinics to drastically improve patient outcomes.
ADVANCED SEARCH
Log in
Top
European Journal of Applied Physiology
Published in: European Journal of Applied Physiology 1-2/2004

01-10-2004 | Original Article

Functional recovery of the plantarflexor muscle group after hindlimb unloading in the rat

Authors: G. L. Warren, J. L. Stallone, M. R. Allen, S. A. Bloomfield

Published in: European Journal of Applied Physiology | Issue 1-2/2004

Login to get access

Abstract

Research into skeletal muscle’s response to hindlimb unloading (HU) of the rodent has focused on that of the markedly affected slow-twitch anti-gravity muscles (e.g., soleus). However, the ability of the animal to locomote following HU should be best determined by the in vivo functional properties of the muscle groups involved and, to our knowledge, this has not been investigated. Our objective was to determine how the in vivo functional properties of the rat ankle plantarflexor group change after 28 days of HU and during a subsequent 28-day recovery. Rats (n=48) were unloaded for 28 days after which they were either tested immediately or allowed to recover for 7, 14, or 28 days before being tested. Control rats (n=61) were tested at comparable times. In vivo functional properties of the ankle plantarflexors were assessed under anesthesia using an isokinetic dynamometer and included determination of the isometric torque-frequency relationship, the concentric torque-ankle angular velocity relationship, and fatigability. Immediately after HU, plantarflexor muscle weight was reduced by 24% but isometric torque production was reduced by 7–9% only at ≥100 Hz and concentric torque production was not significantly affected. However, after 7 days of recovery, in vivo function was more adversely affected; isometric and concentric torques were reduced by 12–33% and 16–36%, respectively, relative to control levels. In vivo plantarflexor function was recovered by 14 days. In conclusion, 28 days of HU has minor adverse effects on the in vivo function of the rat ankle plantarflexors. During the first week of recovery from HU, injury apparently occurs to the plantarflexors resulting in a transient impairment of functional capacity.
Literature
Almeida-Silveira MI, Lambertz D, Perot C, Goubel F (2000) Changes in stiffness induced by hindlimb suspension in rat Achilles tendon. Eur J Appl Physiol 81:252–257CrossRefPubMed
Armstrong RB, Phelps RO (1984) Muscle fiber type composition of the rat hindlimb. Am J Anat 171:259–272PubMed
Ashton-Miller JA, He Y, Kadhiresan VA, McCubbrey DA, Faulkner JA (1992) An apparatus to measure in vivo biomechanical behavior of dorsi- and plantarflexors of mouse ankle. J Appl Physiol 72:1205–1211PubMed
Bloomfield SA, Allen MR, Hogan HA, Delp MD (2002) Site- and compartment-specific changes in bone with hindlimb unloading in mature adult rats. Bone 31:149–157CrossRefPubMed
Bloomfield SA, Girten BE, Weisbrode SE (1997) Effects of vigorous exercise training and beta-agonist administration on bone response to hindlimb suspension. J Appl Physiol 83:172–178PubMed
Booth FW, Seider MJ (1979) Recovery of skeletal muscle after 3 mo of hindlimb immobilization in rats. J Appl Physiol 47:435–439PubMed
Burke RE, Levine DN, Tsairis P, Zajac FE 3rd (1973) Physiological types and histochemical profiles in motor units of the cat gastrocnemius. J Physiol (Lond) 234:723–748
di Prampero PE, Narici MV (2003) Muscles in microgravity: from fibres to human motion. J Biomech 36:403–412CrossRefPubMed
Dodd SL, Koesterer TJ (2002) Clenbuterol attenuates muscle atrophy and dysfunction in hindlimb-suspended rats. Aviat Space Environ Med 73:635–639PubMed
Ettema GJ (1997) Gastrocnemius muscle length in relation to knee and ankle joint angles: verification of a geometric model and some applications. Anat Rec 247:1–8CrossRefPubMed
Fitts RH, Brimmer CJ (1985) Recovery in skeletal muscle contractile function after prolonged hindlimb immobilization. J Appl Physiol 59:916–923PubMed
Fitts RH, Riley DR, Widrick JJ (2000) Physiology of a microgravity environment invited review: microgravity and skeletal muscle. J Appl Physiol 89:823–839PubMed
Frenette J, St-Pierre M, Cote CH, Mylona E, Pizza FX (2002) Muscle impairment occurs rapidly and precedes inflammatory cell accumulation after mechanical loading. Am J Physiol Regul Integr Comp Physiol 282:R351–R357PubMed
Gillette PD, Fell RD (1996) Passive tension in rat hindlimb during suspension unloading and recovery: muscle/joint contributions. J Appl Physiol 81:724–730PubMed
Gorassini M, Eken T, Bennett DJ, Kiehn O, Hultborn H (2000) Activity of hindlimb motor units during locomotion in the conscious rat. J Neurophysiol 83:2002–2011PubMed
Goto K, Okuyama R, Honda M, Uchida H, Akema T, Ohira Y, Yoshioka T (2003) Profiles of connectin (titin) in atrophied soleus muscle induced by unloading of rats. J Appl Physiol 94:897–902PubMed
Herbert ME, Roy RR, Edgerton VR (1988) Influence of one-week hindlimb suspension and intermittent high load exercise on rat muscles. Exp Neurol 102:190–198CrossRefPubMed
Ingalls CP, Warren GL, Armstrong RB (1999) Intracellular Ca2+ transients in mouse soleus muscle after hindlimb unloading and reloading. J Appl Physiol 87:386–390PubMed
Ingalls CP, Warren GL, Lowe DA, Boorstein DB, Armstrong RB (1996) Differential effects of anesthetics on in vivo skeletal muscle contractile function in the mouse. J Appl Physiol 80:332–340PubMed
Kasper CE (1999) Recovery of plantaris muscle from impaired physical mobility. Biol Res Nurs 1:4–11PubMed
Kasper CE, White TP, Maxwell LC (1990) Running during recovery from hindlimb suspension induces transient muscle injury. J Appl Physiol 68:533–539PubMed
Koesterer TJ, Dodd SL, Powers S (2002) Increased antioxidant capacity does not attenuate muscle atrophy caused by unweighting. J Appl Physiol 93:1959–1965PubMed
Lowe DA, Warren GL, Ingalls CP, Boorstein DB, Armstrong RB (1995) Muscle function and protein metabolism after initiation of eccentric contraction-induced injury. J Appl Physiol 79:1260–1270PubMed
McDonald KS, Delp MD, Fitts RH (1992) Fatigability and blood flow in the rat gastrocnemius-plantaris-soleus after hindlimb suspension. J Appl Physiol 73:1135–1140PubMed
McNulty AL, Otto AJ, Kasper CE, Thomas DP (1992) Effect of recovery mode following hind-limb suspension on soleus muscle composition in the rat. Int J Sports Med 13:6–14PubMed
Mercier C, Jobin J, Lepine C, Simard C (1999) Effects of hindlimb suspension on contractile properties of young and old rat muscles and the impact of electrical stimulation on the recovery process. Mech Ageing Dev 106:305–320CrossRefPubMed
Mitchell PO, Pavlath GK (2001) A muscle precursor cell-dependent pathway contributes to muscle growth after atrophy. Am J Physiol 281:C1706–C1715
Musacchia XJ, Fagette S (1997) Weightlessness simulations for cardiovascular and muscle systems: validity of rat models. J Gravit Physiol 4:49–59PubMed
Musacchia XJ, Steffen JM, Fell RD, Dombrowski MJ (1990) Skeletal muscle response to spaceflight, whole body suspension, and recovery in rats. J Appl Physiol 69:2248–2253PubMed
Narici M, Kayser B, Barattini P, Cerretelli P (2003) Effects of 17-day spaceflight on electrically evoked torque and cross-sectional area of the human triceps surae. Eur J Appl Physiol 90:275–282CrossRefPubMed
Ohira Y, Yoshinaga T, Nomura T, Kawano F, Ishihara A, Nonaka I, Roy RR, Edgerton VR (2002) Gravitational unloading effects on muscle fiber size, phenotype and myonuclear number. Adv Space Res 30:777–781CrossRefPubMed
Pierotti DJ, Roy RR, Flores V, Edgerton VR (1990) Influence of 7 days of hindlimb suspension and intermittent weight support on rat muscle mechanical properties. Aviat Space Environ Med 61:205–210PubMed
Pottle D, Gosselin LE (2000) Impact of mechanical load on functional recovery after muscle reloading. Med Sci Sports Exerc 32:2012–2017PubMed
Riley DA, Bain JL, Thompson JL, Fitts RH, Widrick JJ, Trappe SW, Trappe TA, Costill DL (1998) Disproportionate loss of thin filaments in human soleus muscle after 17-day bed rest. Muscle Nerve 21:1280–1289CrossRefPubMed
Riley DA, Slocum GR, Bain JL, Sedlak FR, Sowa TE, Mellender JW (1990) Rat hindlimb unloading: soleus histochemistry, ultrastructure, and electromyography. J Appl Physiol 69:58–66PubMed
Riley DA, Thompson JL, Krippendorf BB, Slocum GR (1995) Review of spaceflight and hindlimb suspension unloading induced sarcomere damage and repair. Basic Appl Myol 5:139–145PubMed
Simard C, Lacaille M (1988) Contractile and histochemical properties of young and old medial gastrocnemius muscle after suspension hypokinesia/hypodynamia. Mech Ageing Dev 44:103–114CrossRefPubMed
Templeton GH, Padalino M, Manton J, Glasberg M, Silver CJ, Silver P, DeMartino G, Leconey T, Klug G, Hagler H, Sutko JL (1984) Influence of suspension hypokinesia on rat soleus muscle. J Appl Physiol 56:278–286PubMed
Thomason DB, Herrick RE, Surdyka D, Baldwin KM (1987) Time course of soleus muscle myosin expression during hindlimb suspension and recovery. J Appl Physiol 63:130–137PubMed
Toursel T, Stevens L, Granzier H, Mounier Y (2002) Passive tension of rat skeletal soleus muscle fibers: effects of unloading conditions. J Appl Physiol 92:1465–1472PubMed
Varejao AS, Cabrita AM, Meek MF, Bulas-Cruz J, Gabriel RC, Filipe VM, Melo-Pinto P, Winter DA (2002) Motion of the foot and ankle during the stance phase in rats. Muscle Nerve 26:630–635CrossRefPubMed
Warren GL, Fennessy JM, Millard-Stafford ML (2000) Strength loss after eccentric contractions is unaffected by creatine supplementation. J Appl Physiol 89:557–562PubMed
Warren GL, Hayes DA, Lowe DA, Williams JH, Armstrong RB (1994) Eccentric contraction-induced injury in normal and hindlimb-suspended mouse soleus and EDL muscles. J Appl Physiol 77:1421–1430PubMed
Warren GL, Ingalls CP, Shah SJ, Armstrong RB (1999) Uncoupling of in vivo torque production from EMG in mouse muscles injured by eccentric contractions. J Physiol (Lond) 515:609–619
Westerblad H, Bruton JD, Allen DG, Lannergren J (2000) Functional significance of Ca2+ in long-lasting fatigue of skeletal muscle. Eur J Appl Physiol 83:166–174PubMed
Winiarski AM, Roy RR, Alford EK, Chiang PC, Edgerton VR (1987) Mechanical properties of rat skeletal muscle after hind limb suspension. Exp Neurol 96:650–660CrossRefPubMed
Witzmann FA, Kim DH, Fitts RH (1982) Recovery time course in contractile function of fast and slow skeletal muscle after hindlimb immobilization. J Appl Physiol 52:677–682PubMed
Metadata
Title
Functional recovery of the plantarflexor muscle group after hindlimb unloading in the rat
Authors
G. L. Warren
J. L. Stallone
M. R. Allen
S. A. Bloomfield
Publication date
01-10-2004
Publisher
Springer-Verlag
Published in
European Journal of Applied Physiology / Issue 1-2/2004
Print ISSN: 1439-6319
Electronic ISSN: 1439-6327
DOI
https://doi.org/10.1007/s00421-004-1185-3

Other articles of this Issue 1-2/2004

European Journal of Applied Physiology 1-2/2004 Go to the issue

Original Article

Excess post-exercise oxygen consumption in spinal cord-injured men

Original Article

A wide range of baroreflex stimulation does not alter forearm blood flow

Original Article

Decreased lung capillary blood volume post-exercise is compensated by increased membrane diffusing capacity

Original Article

The relationship between exercise-induced oxidative stress and the menstrual cycle

Original Article

Passive and active floating torque during swimming

Original Article

Changes in the gain of the soleus H-reflex with changes in the motor recruitment level and/or movement speed