Dongni Ren scite author profile

Dongni Ren

4Publications

39Citation Statements Received

216Citation Statements Given

How they've been cited

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224

213

Affiliations

South China University of Technology, Medical Technologies (Czechia)

Publications

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Multi-level customized 3D printing for autogenous implants in skull tissue engineering

Chen

Zhang

et al. 2019

Biofabrication

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Three-dimensional (3D) printing of decellularized extracellular matrix (ECM) has been achieved to ensure real physiological environments for tissue engineering. However, the limited source, biocompatibility, and biosafety of decellularized ECM are deficiencies in its large clinical use. Autogenous ECM is biocompatible, bioactive, and biosafe, making it an optimal choice for future clinical applications of 3D printing. Here, we developed a multi-level customized 3D printing (MLC-3DP) strategy applying autogenous bone matrix (Auto-BM). This MLC-3DP includes shape specificity (shape), material specificity (Auto-BM), and cell specificity (autogenous cells) for true patient-specific repairs. Auto-BM (skull flaps) is readily accessible for specific patients after craniectomy, providing sufficient autogenous materials for MLC-3DP. Under mild conditions of this strategy, human-scale 3D printed samples can be fabricated using bioactive micron-sized Auto-BM particles. Multi-level customized autogenous bones (MLC-Auto-Bones) are finally obtained by combining autogenous bone marrow-derived mesenchymal stem cells (Auto-BMSCs). With autogenous materials and cells, MLC-Auto-Bones are inherently biocompatible and biosafe, providing good bioactivity for osteogenesis. In this implant, Auto-BMSCs can spontaneously differentiate into osteoblasts in vitro without additional osteogenic factors. In critical-sized skull defect models in vivo (3 months), implants integrate tightly to the defects’ margin, facilitate mineralization, and generate vascularized mature bone. This work provides not only feasibility for patient-specific implants for skull defects, but also potential patient-specific solutions for other similar clinical requirements.

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Hydroxyapatite-incorporation improves bone formation on endosseous PEEK implant in canine tibia

Geng

Ren

et al. 2020

Journal of Applied Biomaterials & Functional Materials

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Background: Poly Ether Ether Ketone (PEEK) has been considered as a potential alternative material for endosseous dental implants, for its low elastic modulus, biocompatibility, and low cost in customized device manufacture. Hydroxyapatite-incorporation is supposed to improve the poor osseointegration of PEEK. Methods: In the present study we analyzed the in vivo response of hydroxyapatite-incorporated PEEK (PEEK-HA) implants in canine tibia. PEEK-HA and PEEK implants were implanted and were examined 4 weeks and 12 weeks after implantation with radiology and histology. Commercial titanium dental implants served as controls. Results: The ratio of bone volume to tissue volume of PEEK-HA implants was higher than that of PEEK implants 4 weeks after implantation in the μ-CT analysis. The bone implant contact of PEEK and PEEK-HA implants showed no statistical difference in the histological examination, but newly-formed bone around PEEK-HA implants showed more signs of mineralization than that around PEEK implants. Conclusion: The study suggested that bone formation was improved with hydroxyapatite-incorporation in PEEK. Hydroxyapatite-incorporated PEEK implants may represent a potential material for endosseous dental implant.

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Inkjet Printing for Biofabrication

Chen

Liu

et al. 2018

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Inkjet Printing for Biofabrication

Chen

Liu

et al. 2018

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Inkjet printing is a noncontact printing technology with high resolution, high throughput, and considerable reproducibility. Instead of printing normal ink, inkjet technology is also applied in the field of biofabrication to print living cells and other biological factors. Cell viability and function were demonstrated to be sustained after printing. Besides two dimensional cell patterns, threedimensional cell-laden hydrogel structures can also be inkjet printed through cross-linking. Special phenomena such as the temporary permeability change of cell membranes were also observed during printing procedures, thus making it possible to achieve gene transfection through inkjet printing. Inkjet-printed biomolecule patterns with gradient concentration were also used to direct cell fates. Since the diversity of bioink and the capability of fabricating complex structures, inkjet bioprinting behaves as an effective tool in the field of biofabrication. The applications of inkjet printing include but not limit to drug formulation, tissue repair, and cancer research.

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Dongni Ren

Multi-level customized 3D printing for autogenous implants in skull tissue engineering

Hydroxyapatite-incorporation improves bone formation on endosseous PEEK implant in canine tibia

Inkjet Printing for Biofabrication

Inkjet Printing for Biofabrication

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