Autografts containing bone marrow (BM) are current gold standard in the treatment of critical size bone defects, delayed union and bone nonunion defects. Although reaching unprecedented healing rates in bone reconstruction, the mode of action and cell-cell interactions of bone marrow mononuclear cell (BM-MNC) populations have not yet been described. BM-MNCs consist of a heterogeneous mixture of hematopoetic and non-hematopoetic lineage fractions. Cell culture in a 3D environment is necessary to reflect on the complex mix of these adherend and non-adherend cells in a physiologically relevant context. Therefore, the main aim of this approach was to establish conditions for a stable 3D BM-MNC culture to assess cellular responses on fracture healing strategies.

BM samples were obtained from residual material after surgery with positive ethical vote and informed consent of the patients. BM-MNCs were isolated by density gradient centrifugation, and cellular composition was determined by flow cytometry to obtain unbiased data sets on contained cell populations. Collagen from rat tail and human fibrin was used to facilitate a 3D culture environment for the BM-MNCs over a period of three days. Effects on cellular composition that could improve the regenerative potential of BM-MNCs within the BM autograft were assessed using flow cytometry. Cell-cell-interactions were visualized using confocal microscopy over a period of 24 hours. Cell localization and interaction partners were characterized using immunofluorescence labeled paraffin sectioning.

Main BM-MNC populations like Monocytes, Macrophages, T cells and endothelial progenitor cells were determined and could be conserved in 3D culture over a period of three days. The 3D cultures will be further treated with already clinically available reagents that lead to effects even within a short-term exposure to stimulate angiogenic, osteogenic or immunomodulatory properties. These measures will help to ease the translation from “bench to bedside” into an intraoperative protocol in the end.

Introduction and Objective

The early pro-inflammatory hematoma phase of bone healing is characterized by platelet activation followed by growth factor release. Bone marrow mesenchymal stromal cells (MSC) play a critical role in bone regeneration. However, the impact of the pro-inflammatory hematoma environment on the function of MSC is not fully understood. We here applied platelet-rich plasma (PRP) hydrogels to study how platelet-derived factors modulate functional properties of MSC in comparison to a non-inflammatory control environment simulated by fibrin (FBR) hydrogels.

Angiogenesis is a key factor in early stages of wound healing and is crucial for tissue regeneration. Gold standard for large bone defect treatment is the transplantation of autologous bone grafts, but is not entirely satisfying (e.g. limited amount). Cell therapies and tissue engineering approaches may overcome these problems by using cells and autologous blood components obtainable by less invasive procedures. Pre-clinical studies previously showed promising results combining endothelial progenitor cells (EPCs) and mesenchymal stem cell (MSCs) in polyurethane scaffolds in presence of PRP (1). A systemic investigation of the chemical and mechanical characteristics of different PRP gels formulations suggested their potential use as sustained autologous growth factor delivery system (2). Here we investigate PRP hydrogels as autologous injectable cell delivery systems for EPCs and MSCs and their efficacy in promoting fast neo-vascularization for bone repair applications.

PRP hydrogel and corresponding platelet lysate (PL) were produced from platelet concentrates as described before (3). MSCs were isolated by Ficoll-Paque centrifugation from human bone marrow (EK_regensburg12-101-0127), and cultured in alpha MEM containing 10% FCS and 5 ng/mL basic-FGF (GIBCO). EPCs (CD133+/CD34+) were isolated from MSC fractions using magnetic-activated cell sorting (MACS®) and further cultured in IMDM (GIBCO) containing 5% FCS and 5% PL. GFP positive HUVECs are from Angio-Proteomie, (Boston, USA). Prior to gel encapsulation, MSC and EPCs were pre-stained using PKH26-red® and PKH67-green® respectively. Cells in different proportions were encapsulated in 3D PRP gels, in FDA approved Fibrin gels and in Matrigel®. The gels were cultured in Ibidi microwells placed in an onstage incubator linked to an EVOS Auto Cell Imaging System. The cellular network formation capacity of HUVEC or EPCs and MSC in different proportions was analyzed for the 3 types of hydrogels using time lapse movies recorded over a period of 14 days. Parallel cultures were performed in a classical cell culture CO₂ incubator and sample gels were taken at different time points for additional immunostaining and gene expression analysis.

Preliminary results indicate high cell viability in all of the three tested gels. PRP hydrogels present a favorable environment for the formation of a 3 dimensional cellular network in cell co-culture. The formation of these networks was apparent as early as 4 days after seeding. Networks increase in complexity and branching over time. The same was observed when cells were embedded in Matrigel®, which is known for its pro-angiogenic properties. Further experiments are currently in process looking at the involvement of MSCs in this process and the effect of PRP 3D co-culture on their differentiation.

PRP was previously shown as a potent growth factor delivery system for tissue engineering. In the present work, the high cell viability together with the 3 dimensional capillary-like networks observed at early time points suggest that PRP can also be used as an autologous cell delivery and pro-angiogenic system for bone tissue repair.

Deficiencies of folate and vitamin B6 and B12 as well as increased methionine serum concentrations have been indicated to disturb bone metabolism, most probably due to an induction of hyperhomocysteinemia (HHCY). However, there is a complete lack of information on whether these metabolic changes affect fracture healing.

Therefore, the aim of this study was to analyze the impact of a methionine-enriched (n=13) and a B vitamin-deficient diet (n=14) on bone repair in mice. Controls were fed by the accordant standard diet (n=12 and n=13). Four weeks after stable fixation of a closed femoral fracture, animals were sacrificed to prepare bones for histomorphometric and biomechanical analyses. In addition, blood samples were obtained to evaluate serum concentrations of homocysteine (HCY), folate, and vitamin B12.

Quantitative analysis of blood samples revealed significantly increased serum concentrations of HCY associated with significantly decreased serum concentrations of folate and vitamin B12 in animals fed with the methionine-enriched diet or the B vitamin-deficient diet when compared to controls. Biomechanical evaluation showed no significant differences in bending stiffness between bones of the experimental and those of the control groups. In accordance, the histomorphometric analysis demonstrated a comparable size and tissue composition of the callus in all groups analyzed.

We conclude that a methionine-enriched and a B vitamin-deficient diet leads to HHCY, however, without affecting bone repair in mice.