Olli-Matti Aho,Petri Lehenkari,  Jukka Ristiniemi, Siri Lehtonen

Juha Risteli, Hannu-Ville Leskelä

Background:

Inducement of foreign-body granulation tissue is a relatively novel therapeutic modality in bone repair. A two-stage bone reconstruction method, known as the Masquelet technique, combines inducement of a granulation tissue membrane and subsequent bone autografting as a biphasic technique allowing reconstruction of large bone defects. In light of their already well-characterized osteogenesis-improving capabilities in animals, we performed this translational study to investigate these membranes in patients.

Methods:

Fourteen patients with complicated fractures and bone defects were randomly selected for this study. Biopsy samples of foreign-body-induced membranes were collected at different time points during scheduled surgical procedures. The membranes were co-cultured with mesenchymal stromal cells, and differentiation into the osteoblastic lineage was assessed by measuring alkaline phosphatase activity, aminoterminal propeptide of type-I procollagen (PINP) production, and Ca²⁺ concentration. Histological characteristics were evaluated with image analysis. Quantitative reverse transcription polymerase chain reaction was used to measure vascular endothelial growth factor (VEGF), interleukin-6 (IL-6), and type-I collagen (Col-1) expression.

Results:

The induced membranes were characterized histologically by maturating vascularized fibrous tissue. The vascularization was greatest in one-month-old samples and decreased to <60% in three-month-old samples. One-month-old membrane samples had the highest expression of VEGF, IL-6, and Col-1, whereas two-month-old membranes expressed <40% of the levels of the one-month-old membranes. Specific alkaline phosphatase activity, PINP production, and Ca²⁺ concentration were increased in co-cultures when a membrane sample was present. In cultures of one-month-old membranes, PINP production was more than two times and Ca²⁺ deposition was four times higher than that in cultures of two-month-old membranes.

Conclusions:

The induced membranes have osteogenesis-improving capabilities. These capabilities, however, appear to decrease over time. We speculate that the optimal time for performing second-stage surgery may be within a month after implantation of foreign material.