2018
DOI: 10.1002/mabi.201800020
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Hemocompatible and Bioactive Heparin‐Loaded PCL‐α‐TCP Fibrous Membranes for Bone Tissue Engineering

Abstract: The combination of bioactive components such as calcium phosphates and fibrous structures are encouraging niche-mimetic keys for restoring bone defects. However, the importance of hemocompatibility of the membranes is widely ignored. Heparin-loaded nanocomposite poly(ε-caprolactone) (PCL)-α-tricalcium phosphate (α-TCP) fibrous membranes are developed to provide bioactive and hemocompatible constructs for bone tissue engineering. Nanocomposite membranes are optimized based on bioactivity, mechanical properties,… Show more

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Cited by 29 publications
(17 citation statements)
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“…PCL-based fibrous nanocomposite membranes embedded with spherical α-TCP nanopowder were engineered as a drug carrier to use as hemocompatible and bioactive substrates for bone tissue engineering. The 1 wt.% α-TCP nanopowder (PCL-1α membrane) resulted in enhanced mechanical properties, bioactivity, and hydrophilicity of PCL-based membranes [ 47 ]. Influences of the composition and porosity of FDM 3D-printed PCL/β-TCP constructs were studied for bone tissue engineering.…”
Section: Introductionmentioning
confidence: 99%
“…PCL-based fibrous nanocomposite membranes embedded with spherical α-TCP nanopowder were engineered as a drug carrier to use as hemocompatible and bioactive substrates for bone tissue engineering. The 1 wt.% α-TCP nanopowder (PCL-1α membrane) resulted in enhanced mechanical properties, bioactivity, and hydrophilicity of PCL-based membranes [ 47 ]. Influences of the composition and porosity of FDM 3D-printed PCL/β-TCP constructs were studied for bone tissue engineering.…”
Section: Introductionmentioning
confidence: 99%
“…The need for more precise control of porosity and pore size within scaffold materials has prompted the implementation of novel 3D printing systems which may offer such capabilities. 3D printing technologies such as fused deposition modeling, stereolithography, and selective laser sintering have enabled the production of scaffolds with greater spatial resolution and fidelity than traditional fabrication methods, while also offering the ability to introduce precise pore gradients which more effectively mimic the physical cues for growth found in native bone tissue (Bracaglia et al, 2017;Alehosseini et al, 2018;Malikmammadov et al, 2018;Babilotte et al, 2019). While 3D printing approaches to the design of scaffolds for bone tissue engineering are quite new and still being explored for their utility, they also offer strong potential for the 3D patterning of surface roughness and other key physical features, providing even further recapitulation of the native cues present in bone (Murphy and Atala, 2014).…”
Section: D Printingmentioning
confidence: 99%
“…[59][60][61] There are also a number of techniques for 3Dprinting polymer compounds, including fused deposition, stereolithography, and laser sintering that have enabled researchers to produce synthetic scaffolds to precisely control the architecture and mimic physical cues for bone growth found in native bone. 13,[62][63][64] These techniques have been used to produce polymer compounds with osteoconductive properties that are conducive to angiogenesis and osteogenesis both in vitro and in vivo. 65,66 One example is Hyperelastic Bone (Dimension Inx, Chicago, IL), 67 which has bone regenerative capacity and elasticity, thereby providing optimal surgical handling properties for deployment and use in the operating room.…”
Section: Future Directions: 3d-printed Composite Materialsmentioning
confidence: 99%