Philippe Korn scite author profile

Due to their characteristic resemblance of the mineral component of bone, calcium phosphates are widely accepted as optimal bone substitute materials. Recent research focused on the development of pasty calcium phosphate cement (CPC) formulations, which can be fabricated into various shapes by low-temperature extrusion-based additive manufacturing, namely 3D plotting. While it could be demonstrated that sensitive substances like growth factors can be integrated in such printed CPC scaffolds without impairment of their biological activity live cells cannot be suspended in CPC as they may not be functional when enclosed in a solid and stiff matrix. In contrast, 3D bioprinting of soft cell-laden hydrogels (bioinks) enables the fabrication of constructs with spatially defined cell distribution, which has the potential to overcome problems of conventional cell seeding techniques-but such objects lack mechanical stability. Herein, we combine 3D plotting of CPC and bioprinting of a cell-laden bioink for the first time. As model bioink, an alginate-methylcellulose blend (alg/mc) was used, previously developed by us. Firstly, a fabrication regime was established, enabling optimal setting of CPC and cell survival inside the bioink. As the cells are exposed to the chemical changes of CPC precursors during setting, we studied the compatibility of the complex system of CPC and cell-laden alg/mc for a combined extrusion process and characterized the cellular behavior of encapsulated human mesenchymal stroma cells within the bioink at the interface and in direct vicinity to the CPC. Furthermore, biphasic scaffolds were mechanically characterized and a model for osteochondral tissue grafts is proposed. The manuscript discusses possible impacts of the CPC setting reaction on cells within the bioink and illustrates the advantages of CPC in bioprinting as alternative to the commonly used thermoplasts for bone tissue engineering.

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Osseointegration of biochemically modified implants in an osteoporosis rodent model

Stadlinger

Korn

Tödtmann

et al. 2013

eCM

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The present study examined the impact of implant surface modifications on osseointegration in an osteoporotic rodent model. Sandblasted, acid-etched titanium implants were either used directly (control) or were further modified by surface conditioning with NaOH or by coating with one of the following active agents: collagen/chondroitin sulphate, simvastatin, or zoledronic acid. Control and modified implants were inserted into the proximal tibia of aged ovariectomised (OVX) osteoporotic rats (n = 32/group). In addition, aged oestrogen competent animals received either control or NaOH conditioned implants. Animals were sacrificed 2 and 4 weeks post-implantation. The excised tibiae were utilised for biomechanical and morphometric readouts (n = 8/group/readout). Biomechanical testing revealed at both time points dramatically reduced osseointegration in the tibia of oestrogen deprived osteoporotic animals compared to intact controls irrespective of NaOH exposure. Consistently, histomorphometric and microCT analyses demonstrated diminished bone-implant contact (BIC), periimplant bone area (BA), bone volume/tissue volume (BV/ TV) and bone-mineral density (BMD) in OVX animals. Surface coating with collagen/chondroitin sulphate had no detectable impact on osseointegration. Interestingly, statin coating resulted in a transient increase in BIC 2 weeks post-implantation; which, however, did not correspond to improvement of biomechanical readouts. Local exposure to zoledronic acid increased BIC, BA, BV/TV and BMD at 4 weeks. Yet this translated only into a non-significant improvement of biomechanical properties. In conclusion, this study presents a rodent model mimicking severely osteoporotic bone. Contrary to the other bioactive agents, locally released zoledronic acid had a positive impact on osseointegration albeit to a lesser extent than reported in less challenging models.

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3D Printing of Bone Grafts for Cleft Alveolar Osteoplasty – In vivo Evaluation in a Preclinical Model

Korn

Ahlfeld

Lahmeyer

et al. 2020

Front. Bioeng. Biotechnol.

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One of the most common hereditary craniofacial anomalies in humans are cleft lip and cleft alveolar bone with or without cleft palate. Current clinical practice, the augmentation of the persisting alveolar bone defect by using autologous bone grafts, has considerable disadvantages motivating to an intensive search for alternatives. We developed a novel therapy concept based on 3D printing of biodegradable calcium phosphate-based materials and integration of osteogenic cells allowing fabrication of patient-specific, tissue-engineered bone grafts. Objective of the present study was the in vivo evaluation of implants in a rat alveolar cleft model. Scaffolds were designed according to the defect's geometry with two different pore designs (60 • and 30 • rotated layer orientation) and produced by extrusion-based 3D plotting of a pasty calcium phosphate cement. The scaffolds filled into the artificial bone defect in the palate of adult Lewis rats, showing a good support. Half of the scaffolds were colonized with rat mesenchymal stromal cells (rMSC) prior to implantation. After 6 and 12 weeks, remaining defect width and bone formation were quantified histologically and by microCT. The results revealed excellent osteoconductive properties of the scaffolds, a significant influence of the pore geometry (60 • > 30 •), but no enhanced defect healing by pre-colonization with rMSC.

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Philippe Korn

Bioprinting of mineralized constructs utilizing multichannel plotting of a self-setting calcium phosphate cement and a cell-laden bioink

Osseointegration of biochemically modified implants in an osteoporosis rodent model

3D Printing of Bone Grafts for Cleft Alveolar Osteoplasty – In vivo Evaluation in a Preclinical Model

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