Sage Journals: Discover world-class research

Abstract

Skeletal muscle has a remarkable regenerative capacity; however, after volumetric muscle loss (VML) or a loss of a large portion of the tissue, this regenerative response is diminished and results in chronic functional deficits. The critical size at which muscle will not recover has not yet been established; subsequently, the response of crucial muscle components at the critically sized threshold is unknown. In this study, we set out to determine the threshold for a critically sized muscle defect by creating full-thickness VML injuries of 2, 3, or 4 mm diameter in the mouse quadriceps. The 2, 3, and 4 mm injuries resulted in a defect of 5%, 15%, or 30% of muscle mass, respectively. At 14 and 28 days after injury, histological analyses revealed injury size-dependent differences in myofiber morphology and fibrosis; the number of small myofibers and fibers with centrally located nuclei increased with increasing injury size. The results indicated that the 3 mm injury, with 15% mass loss, was at the critical threshold point, characterized by incomplete bridging of myofibers through the defect site, persistent fibrosis and inflammation, and a temporally sustained increase in myofibers with centrally located nuclei as compared with contralateral control muscle. We further investigated the 3 mm VML for nerve and vascular regeneration. Critically sized injured muscles were accompanied by a drastic increase in denervated neuromuscular junctions (NMJs), while assessment of angiogenesis through micro-CT analysis revealed a significant increase in vascular volume primarily from small diameter vessels after the VML injury. Collectively, these data indicate that the fibrotic response and neuromotor component remain dysregulated in critically sized defects, and therefore could be potential therapeutic targets for regenerative strategies.

Impact Statement

The goal of this study was to determine the threshold for a critically sized, nonhealing muscle defect by characterizing key components in the balance between fibrosis and regeneration as a function of injury size in the mouse quadriceps. There is currently limited understanding of what leads to a critically sized muscle defect and which muscle regenerative components are functionally impaired. With the substantial increase in preclinical VML models as testbeds for tissue engineering therapeutics, defining the critical threshold for VML injuries will be instrumental in characterizing therapeutic efficacy and potential for subsequent translation.

Get full access to this article

View all access options for this article.

References

Mackey

A.L.

, and Kjaer

The breaking and making of healthy adult human skeletal muscle in vivo. Skelet Muscle, 7, 24, 2017.

Webster

M.T.

, Manor

, Lippincott-Schwartz

, and Fan

C.M.

Intravital imaging reveals ghost fibers as architectural units guiding myogenic progenitors during regeneration. Cell Stem Cell, 18, 243, 2016.

Hardy

, Besnard

, Latil

, et al. Comparative study of injury models for studying muscle regeneration in mice. PLoS One, 11, e0147198, 2016.

Pollot

B.E.

, and Corona

B.T.

Volumetric Muscle Loss. In: Kyba

(ed). Skeletal Muscle Regeneration in the Mouse: Methods and Protocols, vol. 1406, no. Methods in Molecular Biology. New York: Springer Science+Business Media, 2016, pp. 19–31.

Grogan

B.F.

, and Hsu

J.R.

Volumetric Muscle Loss. Skelet. Trauma Res. Consort, 19, S35, 2011.

Corona

B.T.

, Rivera

J.C.

, Owens

J.G.

, Wenke

J.C.

, and Rathbone

C.R.

Volumetric muscle loss leads to permanent disability following extremity trauma. J Rehabil Res Dev, 52, 785, 2015.

Owens

B.D.

, Kragh

J.F.

, Wenke

J.C.

, Macaitis

, Wade

C.E.

, and Holcomb

J.B.

Combat Wounds in Operation Iraqi Freedom and Operation Enduring Freedom. J. Trauma Inj Infect Crit Care, 64, 295, 2008.

Dougherty

A.L.

, Mohrle

C.R.

, Galarneau

M.R.

, Woodruff

S.I.

, Dye

J.L.

, and Quinn

K.H.

Battlefield extremity injuries in Operation Iraqi Freedom. Injury, 40, 772, 2009.

Banerjee

, Bouillon

, Shafizadeh

, et al. Epidemiology of extremity injuries in multiple trauma patients. Injury, 44, 1015, 2013.

10.

Garg

, Ward

C.L.

, Hurtgen

B.J.

, et al. Volumetric muscle loss: persistent functional deficits beyond frank loss of tissue. J Orthop Res, 33, 40, 2015.

11.

Lepper

, Partridge

T.A.

, and Fan

C.-M.

An absolute requirement for Pax7-positive satellite cells in acute injury-induced skeletal muscle regeneration. Development, 138, 3639, 2011.

12.

Bischoff

Interaction between satellite cells and skeletal muscle fibers. Development, 109, 943, 1990.

13.

Rayagiri

S.S.

, Ranaldi

, Raven

, et al. Basal lamina remodeling at the skeletal muscle stem cell niche mediates stem cell self-renewal. Nat Commun, 9, 1075, 2018.

14.

Christov

, Chrétien

, Abou-Khalil

, et al. Muscle satellite cells and endothelial cells: close neighbors and privileged partners. Mol Biol Cell, 18, 1397, 2007.

15.

Schultz

Changes in the satellite cells of growing muscle following denervation. Anat Rec, 190, 299, 1978.

16.

de Castro Rodrigues

, and Schmalbruch

Satellite cells and myonuclei in long-term denervated rat muscles. Anat Rec, 243, 430, 1995.

17.

Liu

, Klose

, Forman

, et al. Loss of adult skeletal muscle stem cells drives age-related neuromuscular junction degeneration. Elife, 6, pii: e26464, 2017.

18.

Liu

, Wei-LaPierre

, Klose

, Dirksen

R.T.

, and Chakkalakal

J.V.

Inducible depletion of adult skeletal muscle stem cells impairs the regeneration of neuromuscular junctions. Elife, 4, 1, 2015.

19.

Barik

, Li

, Sathyamurthy

, Xiong

W.C.

, and Mei

Schwann cells in neuromuscular junction formation and maintenance. J Neurosci, 36, 9770, 2016.

20.

Joe

A.W.B.

, Yi

, Natarajan

, et al. Muscle injury activates resident fibro/adipogenic progenitors that facilitate myogenesis. Nat Cell Biol, 12, 153, 2010.

21.

Uezumi

, Fukada

S.I.

, Yamamoto

, Takeda

, and Tsuchida

Mesenchymal progenitors distinct from satellite cells contribute to ectopic fat cell formation in skeletal muscle. Nat Cell Biol, 12, 143, 2010.

22.

Roddy

, DeBaun

M.R.

, Daoud-Gray

, Yang

Y.P.

, and Gardner

M.J.

Treatment of critical-sized bone defects: clinical and tissue engineering perspectives. Eur J Orthop Surg Traumatol, 28, 351, 2018.

23.

Sicari

B.M.

, Agrawal

, Siu

B.F.

, et al. A murine model of volumetric muscle loss and a regenerative medicine approach for tissue replacement. Tissue Eng Part A, 18, 1941, 2012.

24.

Sadtler

, Estrellas

, Allen

B.W.

, et al. Developing a pro-regenerative biomaterial scaffold microenvironment requires T helper 2 cells. Science, 352, 366, 2016.

25.

Dziki

J.L.

, Sicari

B.M.

, Wolf

M.T.

, Cramer

M.C.

, and Badylak

S.F.

Immunomodulation and mobilization of progenitor cells by extracellular matrix bioscaffolds for volumetric muscle loss treatment. Tissue Eng Part A, 22, 1129, 2016.

26.

Tse

, Morsch

, Ghazanfari

, et al. The Neuromuscular Junction: measuring Synapse Size, Fragmentation and Changes in Synaptic Protein Density Using Confocal Fluorescence Microscopy. J Vis Exp, 94, 1, 2014.

27.

Jang

Y.C.

, Lustgarten

M.S.

, Liu

, et al. Increased superoxide in vivo accelerates age-associated muscle atrophy through mitochondrial dysfunction and neuromuscular junction degeneration. FASEB J, 24, 1376, 2010.

28.

Schiaffino

, Rossi

A.C.

, Smerdu

, Leinwand

L.A.

, and Reggiani

Developmental myosins: expression patterns and functional significance. Skelet Muscle, 5, 1, 2015.

29.

Feng

, Mellor

R.H.

, Bernstein

, et al. Imaging Neuronal Subsets in Transgenic Mice Expressing Multiple Spectral Variants of GFP. Neuron, 28, 41, 2000.

30.

Turner

N.J.

, and Badylak

S.F.

Regeneration of skeletal muscle. Cell Tissue Res, 347, 759, 2012.

31.

M.T.A.

, Willett

N.J.

, Uhrig

B.A.

, Guldberg

R.E.

, and Warren

G.L.

Functional analysis of limb recovery following autograft treatment of volumetric muscle loss in the quadriceps femoris. J Biomech, 47, 2013, 2014.

32.

Matthias

, Hunt

S.D.

, Wu

, et al. Volumetric muscle loss injury repair using in situ fibrin gel cast seeded with muscle-derived stem cells (MDSCs). Stem Cell Res, 27, 65, 2018.

33.

Corona

B.T.

, and Greising

S.M.

Challenges to acellular biological scaffold mediated skeletal muscle tissue regeneration. Biomaterials, 104, 238, 2016.

34.

Garg

, Ward

C.L.

, Rathbone

C.R.

, and Corona

B.T.

Transplantation of devitalized muscle scaffolds is insufficient for appreciable de novo muscle fiber regeneration after volumetric muscle loss injury. Cell Tissue Res, 358, 857, 2014.

35.

Greising

S.M.

, Rivera

J.C.

, Goldman

S.M.

, Watts

, Aguilar

C.A.

, and Corona

B.T.

Unwavering Pathobiology of Volumetric Muscle Loss Injury. Sci Rep, 7, 13179, 2017.

36.

Murphy

M.M.

, Lawson

J.A.

, Mathew

S.J.

, Hutcheson

D.A.

, and Kardon

Satellite cells, connective tissue fibroblasts and their interactions are crucial for muscle regeneration. Development, 138, 3625, 2011.

37.

San Emeterio

C.L.

, Olingy

C.E.

, Chu

, and Botchwey

E.A.

Selective recruitment of non-classical monocytes promotes skeletal muscle repair. Biomaterials, 117, 32, 2017.

38.

Aguilar

C.A.

, Greising

S.M.

, Watts

, et al. Multiscale analysis of a regenerative therapy for treatment of volumetric muscle loss injury. Cell Death Discov, 4, 33, 2018.

39.

Wehling-Henricks

, Jordan

M.C.

, Gotoh

, Grody

W.W.

, Roos

K.P.

, and Tidball

J.G.

Arginine metabolism by macrophages promotes cardiac and muscle fibrosis in mdx muscular dystrophy. PLoS One, 5, e10763, 2010.

40.

Wallace

G.Q.

, and McNally

E.M.

Mechanisms of Muscle Degeneration, Regeneration, and Repair in the Muscular Dystrophies. Annu Rev Physiol, 71, 37, 2009.

41.

Lemos

D.R.

, Babaeijandaghi

, Low

, et al. Nilotinib reduces muscle fibrosis in chronic muscle injury by promoting TNF-mediated apoptosis of fibro/adipogenic progenitors. Nat Med, 21, 786, 2015.

42.

Pizza

F.X.

, Peterson

J.M.

, Baas

J.H.

, and Koh

T.J.

Neutrophils contribute to muscle injury and impair its resolution after lengthening contractions in mice. J Physiol, 562, 899, 2005.

43.

Elabd

, Cousin

, Upadhyayula

, et al. Oxytocin is an age-specific circulating hormone that is necessary for muscle maintenance and regeneration. Nat Commun, 5, 1, 2014.

44.

Langone

, Cannata

, Fuoco

, et al. Metformin protects skeletal muscle from cardiotoxin induced degeneration. PLoS One, 9, e114018, 2014.

45.

Blau

H.M.

, Cosgrove

B.D.

, and Ho

A.T.V.

The central role of muscle stem cells in regenerative failure with aging. Nat Med, 21, 854, 2015.

46.

Kang

, Tian

, Mikesh

, Lichtman

J.W.

, and Thompson

W.J.

Terminal Schwann Cells Participate in Neuromuscular Synapse Remodeling during Reinnervation following Nerve Injury. J Neurosci, 34, 6323, 2014.

47.

Slater

C.R.

Postnatal maturation of nerve-muscle junctions in hindlimb muscles of the mouse. Dev Biol, 94, 11, 1982.

48.

Roman

, Martins

J.P.

, Carvalho

F.A.

, et al. Myofibril contraction and crosslinking drive nuclear movement to the periphery of skeletal muscle. Nat Cell Biol, 19, 1189, 2017.

49.

Han

, Yabroudi

M.A.

, Stearns-Reider

, et al. Electrodiagnostic evaluation of individuals implanted with extracellular matrix for the treatment of volumetric muscle injury: case series. Phys Ther, 96, 540, 2016.

50.

Quarta

, Cromie

, Chacon

, et al. Bioengineered constructs combined with exercise enhance stem cell-mediated treatment of volumetric muscle loss. Nat Commun, 8, 1, 2017.

51.

M.T.

, Ruehle

M.A.

, Stevens

H.Y.

, et al. * Skeletal myoblast-seeded vascularized tissue scaffolds in the treatment of a large volumetric muscle defect in the rat biceps femoris muscle. Tissue Eng Part A, 23, 989, 2017.

52.

VanDusen

K.W.

, Syverud

B.C.

, Williams

M.L.

, Lee

J.D.

, and Larkin

L.M.

Engineered skeletal muscle units for repair of volumetric muscle loss in the tibialis anterior muscle of a rat. Tissue Eng Part A, 20, 2920, 2014.

53.

Greaves

N.S.

, Ashcroft

K.J.

, Baguneid

, and Bayat

Current understanding of molecular and cellular mechanisms in fibroplasia and angiogenesis during acute wound healing. J Dermatol Sci, 72, 206, 2013.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.11 MB

0.31 MB

0.11 MB

0.02 MB

0.00 MB

Determination of a Critical Size Threshold for Volumetric Muscle Loss in the Mouse Quadriceps

Abstract

Impact Statement

Get full access to this article

References

Supplementary Material