Browsing by Author "Chan, RTH"

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    Application of polyethylene glycol to promote cellular biocompatibility of polyhydroxybutyrate films
    (Hindawi Publishing Corporation, 2011-08-22) Chan, RTH; Marçal, H; Russell, RA; Holden, PJ; Foster, LJR
    Polyhydroxybutyrate (PHB) is a biomaterial with potential for applications in biomedical and tissue engineering; however, its brittle nature and high crystallinity limit its potential. Blending PHB with a variety of PEGs produced natural-synthetic composite films composed of FDA-approved polymers with significant reductions in crystallinity, from 70.1% for PHB films to 41.5% for its composite with a 30% (w/w) loading of PEG2000. Blending also enabled manipulation of the material properties, increasing film flexibility with an extension to break of 2.49±1.01% for PHB films and 8.32±1.06% for films containing 30% (w/w) PEG106. Significant changes in the film surface properties, as measured by porosity, contact angles, and water uptake, were also determined as a consequence of the blending process, and these supported greater adhesion and proliferation of neural-associated olfactory ensheathing cells (OECs). A growth rate of 7.2×105 cells per day for PHB films with 30% (w/w) PEG2000 loading compared to 2.5×105 for PHB films was observed. Furthermore, while cytotoxicity of the films as measured by lactate dehydrogenase release was unaffected, biocompatibility, as measured by mitochondrial activity, was found to increase. It is anticipated that fine control of PEG composition in PHB-based composite biomaterials can be utilised to support their applications in medicinal and tissue engineering applications. Copyright © 2011 Rodman T. H. Chan et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
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    BioPEGylation of polyhydroxybutyrate promotes nerve cell health and migration
    (ACS Publications, 2013-12-03) Chan, RTH; Russell, RA; Marçal, H; Lee, TH; Holden, PJ; Foster, LJR
    This study reports on the superior suitability of Polyhydroxybutyrate-polyethylene glycol hybrid polymers biosynthesised by Cupriavidus necator over PHB as biomaterials for tissue engineering. Incorporation of PEG106 (DEG) during PHB biosynthesis reduced crystallinity, molecular weight, and hydrophobicity while improving mechanical properties. In vitro olfactory ensheathing cell (OEC) proliferation was enhanced by cultivation on PHB-b-DEG films. Cultivation on PHB and PHB-b-DEG films showed no cytotoxic responses and cell viability and membrane integrity was sustained. PHB-b-DEG films promoted OECs entering into the DNA replication (S) phase and mitotic (G2-M) phase during the cell growth cycle and apoptosis was low. This study also confirmed an association between the level of neurite-outgrowth inhibitory protein (Nogo) and receptor pair Ig-like receptor B (PirB) expression and cell proliferation, both being down-regulated in cells grown on hybrid films when compared with PHB and asynchronous growth. Thus, DEG-terminated PHB-based biomaterials have great potential as biological scaffolds supporting nerve repair. © 2013 American Chemical Society.
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    Manipulation of polyhydroxybutyrate properties through blending with ethyl-cellulose for a composite biomaterial
    (Hindawi Publishing Corporation, 2011-05-30) Chan, RTH; Garvey, CJ; Marçal, H; Russell, RA; Holden, PJ; Foster, LJR
    Polyhydroxybutyrate (PHB) is widely used as a biomaterial in medical and tissue-engineering applications, a relatively high crystallinity limits its application. Blending PHB with ethyl-cellulose (EtC) was readily achieved to reduce PHB crystallinity and promote its degradation under physiological conditions without undue influence on biocompatibility. Material strength of composite films remained unchanged at 6.5 ± 0.6 MPa with 40% (w/w) EtC loadings. Phase separation between the two biopolymers was determined with PHB crystallinity decreasing from 63% to 47% for films with the same loading. This reduction in crystallinity supported an increase in the degradation rates of composite films from 0.39 to 0.81% wk−1 for PHB and its composite, respectively. No significant change in morphology and proliferation of olfactory ensheathing cells were observed with the composites despite significant increases in average surface roughness (Ra) of the films from 2.90 to 3.65 μm for PHB and blends with 80% (w/w) EtC, respectively. Copyright © 2011 Rodman T. H. Chan et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
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    Poly(ethylene glycol)-modulated cellular biocompatibility of polyhydroxyalkanoate films
    (Wiley-Blackwell, 2013-06-01) Chan, RTH; Marçal, H; Ahmed, T; Russell, RA; Holden, PJ; Foster, LJR
    Polyhydroxybutyrate (PHB) and its copolymer with hydroxyvalerate, P(HB-co-HV), are widely used biomaterials. In this study, improvements of their biological properties of degradability and compatibility were achieved by blending with low-molecular-weight poly(ethylene glycol) (PEG106) approved for medical use. Surface morphology and chemistry are known to support cell attachment. Attachment and proliferation of neural olfactory ensheathing cells increased by 17.0 and 32.2% for PHB and P(HB-co-HV) composite films. Cell attachment was facilitated by increases in surface hydrophilicity, water contact angles decreased by 26 ± 2° and water uptake increased by 23.3% depending upon biopolymer and PEG loading. Cells maintained high viability (>95%) on the composite films with no evidence of cytotoxic effects. Assays of mitochondrial function and cell leakage showed improved cell health as a consequence of PEG loading. The PEG component was readily solubilised from composite films, allowing control of degradation profiles in the cell growth medium. Promotion of biopolymer compatibility and degradability was not at the expense of material properties, with the extension to break of the composites increasing by 5.83 ± 1.06%. Similarly, crystallinity decreased by 36%. The results show that blending of common polyhydroxyalkanoate biomaterials with low-molecular-weight PEG can be used to promote biocompatibility and manipulate physiochemical and material properties as well as degradation. © 2013, Wiley-Blackwell.
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    Using humidity to control the morphology and properties of electrospun bioPEGylated polyhydroxybutyrate scaffolds
    (American Chemical Society (ACS), 2020-10-05) Foster, LJR; Chan, RTH; Russell, RA; Holden, PJ
    Electrospinning produces nanofibrous scaffolds with potential for tissue engineering and wound repair. Spinning parameters control scaffold morphology and properties. BioPEGylation of polyhydroxybutyrate (PHB) introduces terminal hydrophilic groups into the hydrophobic chain, making this natural-synthetic hybrid copolymer more susceptible to humidity. Varying the humidity from 10 to 50% RH during electrospinning had a relatively little effect on polyhydroxybutyrate (PHB) average fiber and pore diameters, which remained around 3.0 and 8.7 μm, respectively. In contrast, fiber and pore diameters for electrospun bioPEGylated PHB scaffolds varied significantly with humidity, peaking at 30% RH (5.5 and 14.1 μm, respectively). While scaffolds showed little change, hydrophobicity decreased linearly with humidity during electrospinning. Compared to solvent-cast films, electrospun scaffolds showed significantly greater average cell spread. A 108% increase for olfactory ensheathing cells (OECs) cultivated on bioPEGylated PHB scaffolds was proportionally greater than their counterparts on electrospun PHB scaffolds, (70%). OECS grown on bioPEGylated PHB scaffolds were over twice the size, 260 ± 20 μm diameter, than those on PHB electrospun scaffolds, 110 ± 18 μm diameter. Electrospun scaffolds also promoted cell health compared to their solvent-cast counterparts, with increases in the mitochondrial activity of 165 ± 13 and 196 ± 13% for PHB and bioPEGylated PHB, respectively. OECS cultivated on electrospun scaffolds of bioPEGylated PHB had significantly better membrane integrities compared to their counterparts on solvent-cast films, 47 ± 5% reducing to 17 ± 6%. The combination of bioPEGylation and humidity during electrospinning permitted significant controllable changes to scaffold morphology and properties. These changes resulted in the significantly greater promotion of cell growth on electrospun bioPEGylated PHB scaffolds compared to their solvent-cast counterparts and electrospun PHB. © 2020 American Chemical Society. This is an open access article published under an ACS AuthorChoice License, which permits copying and redistribution of the article or any adaptations for non-commercial purposes.