Abstract
Purpose
Disc degeneration is known to occur early in adult life, but at present there is no medical treatment to reverse or even retard the problem. Development of medical treatments is complicated by the lack of a validated long term organ culture model in which therapeutic candidates can be studied. The objective of this study was to optimize and validate an organ culture system for intact human intervertebral disc (IVD), which could be used subsequently to determine whether synthetic peptide growth factors can stimulate disc cell metabolism and initiate a repair response.
Method
Seventy lumbar IVDs, from 14 individuals, were isolated within 24 h after death. Discs were prepared for organ culture by removing bony endplates but retaining cartilaginous endplates (CEP). Discs were cultured with no external load applied. The effects of glucose and FBS concentrations were evaluated. Dulbeccos Modified Eagle Media (DMEM) was supplemented with glucose, 4.5g/L or 1g/L, referred to as high and low (physiological) glucose, and FBS, 5% or 1%, referred to as high and low FBS, respectively. After a four week culture period, samples were taken across the disc using a 4 mm biopsy punch. Cell viability was analyzed using a live/dead fluorescence assay (Live/Dead, Invitrogen) and visualized by confocal microscopy. CEP discs were also placed in long term culture for four months, and cell viability was assessed. Western bolt analysis for the G1 domain of aggrecan was also performed to assess the effect of nutritional state on disc catabolism.
Results
Cell viability in CEP isolated discs was evaluated after four weeks and four months of organ culture under high and physiological nutritional state. Previous studies have shown that high glucose levels are needed to maintain cell viability in organ culture, but in our model 96–98% live cells were present throughout the disc independent of FBS and glucose levels and the duration of culture tested. Western blot probing for the G1 domain of aggrecan showed no difference with the change of nutritional state across all regions indicating that low nutritional state had no detrimental effect on disc metabolism.
Conclusion
We have developed a novel technique for isolation and culturing of intact IVDs. The described CEP system maintained sufficient nutrient supply and high cell survival in all regions of the disc for up to four months of culture also under physiological culturing condition. As the CEP system maintains high cell viability in long term cultures, it is a suitable model in which the regenerative effect of various bioactive peptides can be studied. The availability of an intact disc organ culture system has considerable advantage over the culture of isolated disc cells, as it maintains the cells in their unique microenvironment, so making any response to catabolic or anabolic agents more physiologically relevant.
