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Mesenchymal stem cells (MSC), also referred to as marrow stromal cells, maintain the capacity to differentiate into multiple mesenchymal lineages such as osteoblasts, chondrocytes, adipocytes, myoblasts, stromal, neural and endothelial cells. The use of autologous MSC has generated widespread interest due to their developing application in regenerative medicine and tissue engineering in orthopedic surgery. They have become an indispensable cell source for successful implementation in many bone reconstruction procedures. In addition to their multipotency and selfrenewal capacity, they are easily harvested, have demonstrated a homing mechanism and can be efficiently expanded in vitro, thus providing a safe and costefficient tissue replacement for patients with skeletal injury or disease. Little information is currently available concerning donor characteristics for tissue engineering growth of osseous tissue. This study examines the influences of such donor characteristics, including injury pattern, gender, age, and site of harvest on the quantity, quality and osteogenic differentiation of MSC. The goal is to evaluate whether certain patient groups are practically suitable for an ex vivo expansion and therapeutic reimplantation of MSC. The effect of injury pattern on the reservoir and proliferative capacity of MSC in human bone marrow is clearly demonstrated in this analysis. Age and gender were also shown to influence MSC number and proliferation, as in previous studies. A total of 53 participants (46 patients and 7 healthy volunteers ranging from 18 to 64 years of age), who were scheduled to undergo operative procedures on the pelvis, vertebrae, tibia or hip as well as cancellous bone autografts for reconstruction of various bone defects, were included in the study. Participants were divided into 4 groups for each gender: single fracture, multiple trauma, atrophic nonunion and healthy volunteers. A minimum of 6 ml bone marrow samples were aspirated intraoperatively and processed immediately according to protocol. Following cultivation and expansion for 14 days, the cells were then stained for the colony forming unit-fibroblast (CFU-F) assay and each culture flask was photographed, digitized and converted to an 8 bit grey level TIF-format. Using the digitized CFU-F assay, the mean colony number, mean colony area and mean cell number per microscopic field of view (cell density) could be determined. In addition, confirmation of MSC phenotype was established using fluorescent activated cell sorting (FACS). MSC potential for osteogenic differentiation was quantified by von Kossa, alkaline phosphatase and alizarin staining. Furthermore, serum from a total of 39 randomly chosen participants was collected and tested for hormone levels of 17β-estradiol, testosterone and prolactin as well as the cytokine interleukin-6. These analyses demonstrate several significant trauma-related modifications in MSC reservoir and proliferation, in both male and female patients. In multiple trauma patients, the highest MSC frequency was found, independent of gender and age. Proliferative capacity was also highest in male multiple trauma patients. In the case of atrophic nonunion, the lowest MSC reservoir was detected, independent of gender. Furthermore, MSC frequency in male patients was significantly higher than in female, although analyses of hormone and interleukin-6 levels provided no correlation. Agerelated changes in MSC reservoir could also be observed, whereas the proliferative capacity produced only a tendency toward decreasing values with increasing age. Concerning the site of cell harvest, MSC isolated from the proximal extremity of the tibia, greater trochanter and vertebral body did not proliferate sufficiently enough to be included in statistical analysis, supporting the use of the iliac crest for efficient expansion of MSC. This data suggests the interaction of yet to be identified processes in bone marrow in multiple trauma situations which stimulate the activation and mobilization of MSC. Moreover, in the case of atrophic nonunion, the concentration in bone marrow is depleted and the absence of systemic stimulation present in multiple trauma results in reduced activation of proliferative capacity. Such patients, with severe injury or atrophic nonunion, represent a group of patients with an especially acute necessity for effective and successful bone reconstruction. This data can be used to determine the applicability of MSC from various patient groups for osseous tissue replacement procedures. Especially in such medically challenging situations, further research is essential not only to delineate the factors involved in MSC regulation but also to develop methods to stimulate MSC expansion and proliferation.