Craniofacial muscle engineering using a 3-dimensional phosphate glass fibre construct

Shah, Rishma; Sinanan, Andrea; Knowles, Jonathan C.; Hunt, NP; Lewis, Mark P.

doi:10.1016/j.biomaterials.2004.04.049

Cited by 127 publications

(99 citation statements)

References 44 publications

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“…Although several studies have addressed the development of an optimal non-biodegradable scaffold, such as Shah et al, 2005Sinanan et al, 2004Stern-Straeter et al, 2008Alessandri et al, 2004 Human Brachioradialis muscle Satellite cell Lewis et al, 2000 C3H mice C2C12 Cell line Borschel et al, 2004Dennis et al, 2000Huang et al, 2005Levenberg et al, 2005Riboldi et al, 2005Boontheekul et al, 2007Borschel et al, 2004 Rat Soleus muscle Satellite cell Larkin et al, 2006Dennis et al, 2000Huang et al, 2005Das et al, 2006Beier et al, 2004Bach et al, 2003Stern-Staeter et al, 2008Boontheekul et al, 2007Huang et al, 2005 Rat Tibialis anterior muscle Satellite cell Dennis et al, 2000Boontheekul et al, 2007Kamelger et al, 2004 Rat Latissimus dorsi muscle Satellite cell Kamelger et al, 2004 Rat phosphate-based glass (Shah et al, 2005), biodegradable scaffolds are preferred because, upon degradation, remodelling to the natural muscular ECM can occur. Both synthetic and natural scaffolds have been developed.…”

Section: Scaffoldsmentioning

confidence: 99%

“…Also, satellite cells harvested from the soleus muscle of rats are used for TE of muscle tissue (Dennis and Kosnik, 2000;Beier et al, 2004;Stern-Straeter et al, 2005;Das et al, 2006;Borschel et al, 2006;Larkin et al, 2006;Bach et al, 2006;Huang et al, 2006b;Boontheekul et al, 2007). Other muscles harvested for TE research include the latissimus dorsi and rectus femoris of rats (Kamelger et al, 2004), the flexor digitorum brevis of rats (De Coppi et al, 2005), the tibialis anterior of rats (Dennis et al, 2001;Huang et al, 2005;Boontheekul et al, 2007), the extensor digitorum longus of mice (Dennis et al, 2001), the human masseter (Lewis et al, 2000;Sinanan et al, 2004;Shah et al, 2005;Stern-Straeter et al, 2008;Brady et al, 2008a) and brachioradialis (Alessandri et al, 2004) and the iliofibularis from female Xenopus laevis frogs (Jaspers et al, 2006) (Table 2).…”

Section: Progenitor Cellsmentioning

confidence: 99%

See 1 more Smart Citation

Current opportunities and challenges in skeletal muscle tissue engineering

Koning¹,

Harmsen²,

Luyn³

et al. 2009

J Tissue Eng Regen Med

144

108

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The purpose of this article is to give a concise review of the current state of the art in tissue engineering (TE) of skeletal muscle and the opportunities and challenges for future clinical applicability. The endogenous progenitor cells of skeletal muscle, i.e. satellite cells, show a high proneness to muscular differentiation, in particular exhibiting the same characteristics and function as its donor muscle. This suggests that it is important to use an appropriate progenitor cell, especially in TE facial muscles, which have a exceptional anatomical and fibre composition compared to other skeletal muscle. Muscle TE requires an instructive scaffold for structural support and to regulate the proliferation and differentiation of muscle progenitor cells. Current literature suggests that optimal scaffolding could comprise of a fibrin gel and cultured monolayers of muscle satellite cells obtained through the cell sheet technique. Tissue-engineered muscle constructs require an adequate connection to the vascular system for efficient transport of oxygen, carbon dioxide, nutrients and waste products. Finally, functional and clinically applicable muscle constructs depend on adequate neuromuscular junctions with neural cells. To reach this, it seems important to apply optimal electrical, chemotropic and mechanical stimulation during engineering and discover other factors that influence its formation. Thus, in addition to approaches for myogenesis, we discuss the current status of strategies for angiogenesis and neurogenesis of TE muscle constructs and the significance for future clinical use.

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Section: Scaffoldsmentioning

confidence: 99%

Section: Progenitor Cellsmentioning

confidence: 99%

Current opportunities and challenges in skeletal muscle tissue engineering

Koning¹,

Harmsen²,

Luyn³

et al. 2009

J Tissue Eng Regen Med

144

108

View full text Add to dashboard Cite

show abstract

“…Ahmed et al [13] observed cell attachment and differentiation of conditionally immortal muscle precursor cells on phosphate glass fibres, with the formation of myotubes along the axis of the fibres. Shah et al [14] investigated the use of phosphate glass fibres as a poten-tial scaffold material for the in vitro engineering of craniofacial skeletal muscle. They found that a three-dimensional mesh of fi-bres enhanced the attachment and proliferation of human masse-ter-derived cells, which were also capable of migrating along the fibres.…”

Section: Introductionmentioning

confidence: 99%

Phosphate glass fibres and their role in neuronal polarization and axonal growth direction

et al. 2012

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“…Glasses can be prepared containing various metal oxides such as CuO (Abou Neel et al 2005a), Fe 2 O 3 (Yu et al 1997;Ahmed et al 2004;Abou Neel et al 2005b), Al 2 O 3 (Shah et al 2005), TiO 2 (Rajendran et al 2006;Abou Neel et al 2007; or ZnO to suit the end applications. Furthermore, Drake and Allen found that PBGs with a suitable composition dissolve in water with a zeroorder rate, and, by tailoring the composition further, it was possible to produce glasses with stabilities ranging from those that would completely degrade in water in a few hours to those that are stable for years (Drake 1985;Drake & Allen 1985).…”

Section: Introductionmentioning

confidence: 99%

Structure and properties of strontium-doped phosphate-based glasses

Neel

Chrzanowski

Pickup

et al. 2008

J. R. Soc. Interface.

139

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Owing to similarity in both ionic size and polarity, strontium (Sr 2C ) is known to behave in a comparable way to calcium (Ca 2C ), and its role in bone metabolism has been well documented as both anti-resorptive and bone forming. In this study, novel quaternary strontium-doped phosphate-based glasses, containing 1, 3 and 5 mol% SrO, were synthesized and characterized.31 P magic angle spinning (MAS) nuclear magnetic resonance results showed that, as the Sr 2C content is increased in the glasses, there is a slight increase in disproportionation of Q 2 phosphorus environments into Q 1 and Q 3 environments. Moreover, shortening and strengthening of the phosphorus to bridging oxygen distance occurred as obtained from FTIR. The general broadening of the spectral features with Sr 2C content is most probably due to the increased variation of the phosphate-cation bonding interactions caused by the introduction of the third cation. This increased disorder may be the cause of the increased degradation of the Sr-containing glasses relative to the Sr-free glass. As confirmed from elemental analysis, all Sr-containing glasses showed higher Na 2 O than expected and this also could be accounted for by the higher degradation of these glasses compared with Sr-free glasses. Measurements of surface free energy (SFE) showed that incorporation of strontium had no effect on SFE, and samples had relatively higher fractional polarity, which is not expected to promote high cell activity. From viability studies, however, the incorporation of Sr 2C showed better cellular response than Sr 2C -free glasses, but still lower than the positive control. This unfavourable cellular response could be due to the high degradation nature of these glasses and not due to the presence of Sr 2C .

show abstract

Craniofacial muscle engineering using a 3-dimensional phosphate glass fibre construct

Cited by 127 publications

References 44 publications

Current opportunities and challenges in skeletal muscle tissue engineering

Current opportunities and challenges in skeletal muscle tissue engineering

Phosphate glass fibres and their role in neuronal polarization and axonal growth direction

Structure and properties of strontium-doped phosphate-based glasses

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