There is an unmet clinical need for a biomaterial sealant capable of repairing small annulus fibrosus (AF) defects. Causes of these defects include painful intervertebral disc herniations, microdiscectomy procedures, morbidity associated with needle puncture injury from discography, and future nucleus replacement procedures. This study describes the enhancements of a fibrin gel through genipin crosslinking (FibGen) and the addition of the cell adhesion molecules (CAMs), fibronectin and collagen. The gel's performance as a potential AF sealant is assessed using a series of in vitro tests. FibGen gels with CAMs had equivalent adhesive strength, gene expression, cytomorphology, and cell proliferation as fibrin alone. However, FibGen gels had enhanced material behaviors that were tunable to higher shear stiffness values and approximated human annulus tissue as compared with fibrin alone, were more dimensionally stable, and had a slower in vitro degradation rate. Cytomorphology of human AF cells cultured on FibGen gels exhibited increased elongation compared with fibrin alone, and the addition of CAMs to FibGen did not significantly affect elongation. This FibGen gel offers the promise of being used as a sealant material to repair small AF defects or to be used in combination with other biomaterials as an adhesive for larger defects.
Get full access to this article
View all access options for this article.
References
1.
AnderssonG.B.Epidemiology of low back pain. Acta Orthop Scand, Suppl 281, 28, 1998.
2.
TarulliA.W., and RaynorE.M.Lumbosacral radiculopathy. Neurol Clin, 25, 387, 2007.
3.
DeyoR.A., and WeinsteinJ.N.Low back pain. N Engl J Med, 344, 363, 2001.
4.
CarrageeE.J., DonA.S., HurwitzE.L., CuellarJ.M., CarrinoJ.A., and HerzogR.2009 ISSLS Prize Winner: does discography cause accelerated progression of degeneration changes in the lumbar disc: a ten-year matched cohort study. Spine (Phila Pa 1976). 34, 2338, 2009.
5.
GuterlC., SeeE., BlanquerS., PanditA., FergusonS., BennekerL., et al. Challenges and strategies in the repair of ruptured annulus fibrosus. Eur Cells Mater, 25, 1, 2013.
6.
IatridisJ.C., NicollS.B., MichalekA.J., WalterB.A., and GuptaM.S.Role of biomechanics in intervertebral disc degeneration and regenerative therapies: what needs repairing in the disc and what are promising biomaterials for its repair?. Spine J, 13, 243, 2013.
7.
LewisG.Nucleus pulposus replacement and regeneration/repair technologies: present status and future prospects. J Biomed Mater Res Part B Appl Biomater, 100, 1702, 2012.
8.
YangX., and LiX.Nucleus pulposus tissue engineering: a brief review. Eur Spine J, 18, 1564, 2009.
9.
CostiJ.J., FreemanB.J., and ElliottD.M.Intervertebral disc properties: challenges for biodevices. Expert Rev Med Devices, 8, 357, 2011.
10.
BronJ.L., HelderM.N., MeiselH.J., Van RoyenB.J., and SmitT.H.Repair, regenerative and supportive therapies of the annulus fibrosus: achievements and challenges. Eur Spine J, 18, 301, 2009.
11.
CarrageeE.J., HanM.Y., SuenP.W., and KimD.Clinical outcomes after lumbar discectomy for sciatica: the effects of fragment type and anular competence. J Bone Joint Surg Am Vol, 85-A, 102, 2003.
12.
ChiangY.F., ChiangC.J., YangC.H., ZhongZ.C., ChenC.S., ChengC.K., et al. Retaining intradiscal pressure after annulotomy by different annular suture techniques, and their biomechanical evaluations. Clin Biomech (Bristol, Avon), 27, 241, 2012.
13.
AhlgrenB.D., LuiW., HerkowitzH.N., PanjabiM.M., and GuibouxJ.P.Effect of anular repair on the healing strength of the intervertebral disc: a sheep model. Spine (Phila Pa 1976). 25, 2165, 2000.
14.
BronJ.L., van der VeenA.J., HelderM.N., van RoyenB.J., and SmitT.H.Biomechanical and in vivo evaluation of experimental closure devices of the annulus fibrosus designed for a goat nucleus replacement model. Eur Spine J, 19, 1347, 2010.
15.
WangD.A., VargheseS., SharmaB., StrehinI., FermanianS., GorhamJ., et al. Multifunctional chondroitin sulphate for cartilage tissue-biomaterial integration. Nat Mater, 6, 385, 2007.
16.
BuserZ., KuellingF., LiuJ., LiebenbergE., ThorneK.J., CoughlinD., et al. Biological and biomechanical effects of fibrin injection into porcine intervertebral discs. Spine, 36, E1201, 2011.
17.
BuserZ., LiuJ., ThorneK.J., CoughlinD., and LotzJ.C.Inflammatory response of intervertebral disc cells is reduced by fibrin sealant scaffold in vitro. J Tissue Eng Regen Med, 8, 77, 2014.
18.
IatridisJ.C., KumarS., FosterR.J., WeidenbaumM., and MowV.C.Shear mechanical properties of human lumbar annulus fibrosus. J Orthop Res, 17, 732, 1999.
19.
SpilkerR.L., JakobsD.M., and SchultzA.B.Material constants for a finite element model of the intervertebral disk with a fiber composite annulus. J Biomech Eng, 108, 1, 1986.
20.
WalterB.A., KoreckiC.L., PurmessurD., RoughleyP.J., MichalekA.J., and IatridisJ.C.Complex loading affects intervertebral disc mechanics and biology. Osteoarthritis Cartilage, 19, 1011, 2011.
21.
GoelV.K., MonroeB.T., GilbertsonL.G., and BrinckmannP.Interlaminar shear stresses and laminae seperation in a disc. Finite element analysis of the L3-L4 motion segment subjected to axial compressive loads. Spine (Phila Pa 1976), 20, 689, 1995.
22.
DareE.V., GriffithM., PoitrasP., KauppJ.A., WaldmanS.D., CarlssonD.J., et al. Genipin cross-linked fibrin hydrogels for in vitro human articular cartilage tissue-engineered regeneration. Cells Tissues Organs, 190, 313, 2009.
23.
SchekR.M., MichalekA.J., and IatridisJ.C.Genipin-crosslinked fibrin hydrogels as a potential adhesive to augment intervertebral disc annulus repair. Eur Cells Mater, 21, 373, 2011.
24.
JiaoY., GyawaliD., StarkJ., AkcoraP., NairP., TranR., et al. A rheological study of biodegradable injectable PEGMC/HA composite scaffolds. Soft Matter, 8, 1499, 2012.
25.
MichalekA.J., Gardner-MorseM.G., and IatridisJ.C.Large residual strains are present in the intervertebral disc annulus fibrosus in the unloaded state. J Biomech, 45, 1227, 2012.
26.
MaherS.A., MauckR.L., RackwitzL., and TuanR.S.A nanofibrous cell-seeded hydrogel promotes integration in a cartilage gap model. J Tissue Eng Regen Med, 4, 25, 2010.
27.
LivakK.J., and SchmittgenT.D.Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) method. Methods, 25, 402, 2001.
28.
BruehlmannS.B., RattnerJ.B., MatyasJ.R., and DuncanN.A.Regional variations in the cellular matrix of the annulus fibrosus of the intervertebral disc. J Anat, 201, 159, 2002.
29.
ErringtonR.J., PuustjarviK., WhiteI.R., RobertsS., and UrbanJ.P.Characterisation of cytoplasm-filled processes in cells of the intervertebral disc. J Anat, 192 (Pt 3), 369, 1998.
30.
ChangY., TsaiC.C., LiangH.C., and SungH.W.Reconstruction of the right ventricular outflow tract with a bovine jugular vein graft fixed with a naturally occurring crosslinking agent (genipin) in a canine model. J Thorac Cardiovasc Surg, 122, 1208, 2001.
31.
WilkeH.J., NeefP., CaimiM., HooglandT., and ClaesL.E.New in vivo measurements of pressures in the intervertebral disc in daily life. Spine, 24, 755, 1999.
