Physical properties and cellular responses to crosslinkable poly(propylene fumarate)/hydroxyapatite nanocomposites

Lee, Kee-Won; Wang, Shanfeng; Yaszemski, Michael J.; Lu, Lichun

doi:10.1016/j.biomaterials.2008.03.030

Cited by 114 publications

(132 citation statements)

References 51 publications

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“…The SEM micrographs demonstrated morphology and microstructure of n-HA/gel and n-HA/gel/CMC composite scaffold which show optimal pore size in accordance to accommodate, infiltrate and proliferate cells. As reported compressive modulus of human trabecular bone, 33,34 our results shows that these composite scaffolds have sufficient mechanical strength and also due to their viscoelasticity in wet condition they can be cut, deform, and fit according to bone defects which allows them to use it in case of bone cyst and large defects with smaller opening. The viscoelastic property of the composites inhibits unexpected breakage of the material and formation of debris from the surface during surgical operation.…”

Section: Discussionmentioning

confidence: 56%

Influence of carboxymethyl chitin on stability and biocompatibility of 3D nanohydroxyapatite/gelatin/carboxymethyl chitin composite for bone tissue engineering

2012

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A novel three-dimensional (3D) scaffold has been developed from the unique combination of nanohydroxyapatite/gelatin/carboxymethyl chitin (n-HA/gel/CMC) for bone tissue engineering by using the solvent-casting method combined with vapor-phase crosslinking and freeze-drying. The surface morphology and physiochemical properties of the scaffold were investigated by dissolvability test, infrared absorption spectra (IR), X-ray diffraction (XRD), transmission electron microscope (TEM), scanning electron microscope (SEM), mechanical testing, and soaking in simulated body fluid (SBF). An optimized (composition and processing parameters) ratio of n-HA:gel:CMC (1:2:1), exhibited ideal porous structure with regular interconnected pores (75-250 μm) and higher mechanical strength. Result suggested that the divalent (Ca(++)), carboxyl (COO(-)), amino (NH4(+)), and phosphate (PO4(3-)) groups created favorable ionic interactions which facilitated structural stability and integrity of the composite scaffold. The SBF soaking experiment confirmed the apatite nucleation ability, induced by CMC incorporation. Furthermore, hemocompatibility (hemolysis, platelet adhesion, and protein adsorption) and biocompatibility with MG63 osteoblast cells (MTT assay, cell morphology, and confocal studies from within the 3D scaffold) indicated that the structural and dimensional stability of composite scaffold provided an optimal mechanosensory environment for enhancement of cell adhesion, proliferation, and network formation. The n-HA/gel/CMC composite, therefore, may serve as a promising composite scaffold for guided bone regeneration.

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Section: Discussionmentioning

confidence: 56%

Influence of carboxymethyl chitin on stability and biocompatibility of 3D nanohydroxyapatite/gelatin/carboxymethyl chitin composite for bone tissue engineering

2012

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“…In particular, while the surfaces of many synthetic polymers have low cell affinity, cell-friendly surface HA nanoparticles counteracted the disadvantages of the synthetic polymer PPF/DEF. Yaszemski et al studied the physical properties and cellular responses of poly (propylene fumarate)/HA nanocomposites (26). Liska et al investigated gelatin hydrolysate, which was mixed with reactive diluents, and HA to enhance mechanical strength (23).…”

Section: Stereolithography (Sl)mentioning

confidence: 99%

Solid Free-form Fabrication Technology and Its Application to Bone Tissue Engineering

2010

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The development of scaffolds for use in cell-based therapies to repair damaged bone tissue has become a critical component in the field of bone tissue engineering. However, design of scaffolds using conventional fabrication techniques has limited further advancement, due to a lack of the required precision and reproducibility. To overcome these constraints, bone tissue engineers have focused on solid free-form fabrication (SFF) techniques to generate porous, fully interconnected scaffolds for bone tissue engineering applications. This paper reviews the potential application of SFF fabrication technologies for bone tissue engineering with respect to scaffold fabrication. In the near future, bone scaffolds made using SFF apparatus should become effective therapies for bone defects.

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“…But the strength of porous scaffold is relatively low which limits its application. In order to overcome these limitations, Lee et al successfully fabricated poly(propylene fumarate)/hydroxyapatite (PPF/HA) nanocomposites by crosslinking HA nanoparticles and PPF (Lee et al 2008). The PPF/HA nanocomposites showed excellent mechanical strength and osteoconductivity and may serve as a scaffolding material for bone tissue engineering applications (Lee et al 2008).…”

Section: Introductionmentioning

confidence: 97%

“…In order to overcome these limitations, Lee et al successfully fabricated poly(propylene fumarate)/hydroxyapatite (PPF/HA) nanocomposites by crosslinking HA nanoparticles and PPF (Lee et al 2008). The PPF/HA nanocomposites showed excellent mechanical strength and osteoconductivity and may serve as a scaffolding material for bone tissue engineering applications (Lee et al 2008). However, HA may limit new bone tissue ingrowth due to its poor in vivo biodegradability (Renooij et al 1985) when PPF/HA is implanted into bone defects though HA possesses excellent biocompatibility and osteoconductive property.…”

Section: Introductionmentioning

confidence: 97%

Morphological and histological analysis on the in vivo degradation of poly (propylene fumarate)/(calcium sulfate/β-tricalcium phosphate)

Cai

Zhang

Di³

et al. 2011

Biomed Microdevices

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Poly (propylene fumarate)/(Calcium sulfate/β-tricalcium phosphate) (PPF/(CaSO(4)/β-TCP)) is a kind of biodegradable composite designed for bone tissue engineering. The in vitro degradation behavior of this composite has been investigated in our previous study. The aim of this study was to investigate the effects of PPF molecular weight and CaSO(4)/β-TCP molar ratio on the in vivo degradation of PPF/(CaSO(4)/β-TCP) composite and the bone tissue response to PPF/(CaSO(4)/β-TCP). Total 36 PPF/(CaSO(4)/β-TCP) composite samples were implanted into 15.0 mm segmental defects in tibiae of 18 Japanese rabbits, harvested at 2, 4 and 8 weeks after the operation, and analyzed using radiographic and histological analysis to assess the in vivo degradation of the composites as well as tissue response to the implants. The in vivo degradation results show that all the samples maintained their original shape. Tissues penetrated into the pores which formed by the degradation of CaSO(4)/β-TCP spheres near the surface of the composites. The rate of in vivo degradation and pore forming increased with a decrease in PPF molecular weight and an increase in CaSO(4)/β-TCP molar ratio. No inflammatory reaction was observed after implantation, and the composites are capable of in situ pore forming. In particular, the pore forming rate can be adjusted by varying the composition of the composites. These results may indicate that PPF/(CaSO(4)/β-TCP) is a promising osteogenic scaffold for its controllable degradation rate and excellent biocompatibility.

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Physical properties and cellular responses to crosslinkable poly(propylene fumarate)/hydroxyapatite nanocomposites

Cited by 114 publications

References 51 publications

Influence of carboxymethyl chitin on stability and biocompatibility of 3D nanohydroxyapatite/gelatin/carboxymethyl chitin composite for bone tissue engineering

Influence of carboxymethyl chitin on stability and biocompatibility of 3D nanohydroxyapatite/gelatin/carboxymethyl chitin composite for bone tissue engineering

Solid Free-form Fabrication Technology and Its Application to Bone Tissue Engineering

Morphological and histological analysis on the in vivo degradation of poly (propylene fumarate)/(calcium sulfate/β-tricalcium phosphate)

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