Abstract
Introduction: The treatment of bone defects that occurs following fractures, the excision of bone tumours and at revision arthroplasty surgery, often involves the use of either autologous or allogenous bone grafts. However, both grafts have limitations. The aim of tissue engineering is to produce cells within an extracellular matrix that resembles tissue, which can be implanted into a patient to heal a tissue defect. The potential to engineer bone tissue grafts from patients’ autologous cells would improve the treatment of bone defects.
Bone marrow contains cells, known as mesenchymal stem cells (MSCs), which have the ability to differentiate into osteoblasts. To create a 3-dimensional structure necessary for the reconstruction of tissue, cells need to be grown on a scaffold, for which hydroxyapatite (HA) was used, as it is osteoconductive. In living bone, increased extravascular perfusion increases new bone formation. Thus, these physiological conditions were reproduced in our novel bioreactor by perfusing MSCs seeded on porous HA scaffolds at a rate of 6ml/hr. Hypotheses: 1. Culture in this bioreactor improves cell penetration through a HA scaffold. 2. MSCs cultured on HA in this bioreactor differentiated into osteoblasts.
Method: MSCs were isolated from 8 bone marrow aspirates, which were taken from patients during orthopaedic procedures following informed consent. For each experiment, MSCs from each patient were seeded onto 2 x 1cm3 scaffolds. To test cell penetration, the HA scaffolds were cultured for 7 days, then sectioned longitudinally and the number of cells were counted at increasing depths. Observations of MSCs on HA were compared under scanning (SEM) and transmission (TEM) electron microscopy. The HA scaffolds were cultured with MSCs in the bioreactor for 5, 10 & 15 days, after which time alkaline phosphatase (ALP) and type I pro-collagen protein levels were measured.
Results: Penetration of cells through the porous HA scaffold was significantly greater when the cells had been cultured in the bioreactor (P< 0.05). Observing MSCs after 7 days in bioreactor culture under SEM, adherent fibroblastic cells formed a network over the HA. However, by 14 days the HA was covered with cuboidal cells, consistent with osteoblasts. TEM results showed that MSCs cultured on HA in the bioreactor produced organised collagen matrix after 28 days. Osteoblastic protein levels were significantly greater at each time point when MSCs were cultured in bioreactor conditions: ALP (P< 0.005) and type I pro-collagen (P< 0.05).
Discussion and Conclusions: These results show that when cultured in our novel bioreactor, MSCs penetrated uniformly through the porous HA scaffold, whereas few cells penetrated in static culture conditions. Thus, our bio-reactor significantly improves the 3-dimensional growth of cells, resembling tissue. Moreover, in this study MSCs grown on HA in the bioreactor produced significantly larger amounts of ALP and type I pro-collagen, indicating that the MSCs differentiated into osteoblasts. Observations under TEM showed extracellular collagen matrix production which, when mineralized, produces bone.
Therefore, this culture method could potentially be used to convert MSCs, isolated from patients’ bone marrow, into tissue-engineered bone.
Correspondence should be addressed to Carlos Widgerowitz, Honorary Secretary BORS, Division of Surgery and Oncology, Section of Orthopaedic and Trauma Surgery, Ninewells Hospital and Medical School, Tort Centre, Dundee DD1 9SY, Scotland.
