Characterization of the foreign body response to common surgical biomaterials in a murine model
Tóm tắt
Từ khóa
Tài liệu tham khảo
Sprugel KH, McPherson JM, Clowes AW, Ross R (1987) Effects of growth factors in vivo. I. Cell ingrowth into porous subcutaneous chambers. Am J Pathol 129:601–613
Anderson JM, Rodriguez A, Chang DT (2008) Foreign body reaction to biomaterials. Semin Immunol 20:86–100
Avula M, Rao AN, McGill LD, Grainger DW, Solzbacher F (2014) Foreign body response to subcutaneous biomaterial implants in a mast cell-deficient Kit(w-Sh) murine model. Acta Biomater 10(5):1856–1863
Nichols SP, K Ahyeon, LB Nga, et al (2012) The effect of nitric oxide surface flux on the foreign body response to subcutaneous implants. Biomaterials 33:6305–6312
McNally AK, Jones JA, Macewan SR, Colton E, Anderson JM (2008) Vitronectin is a critical protein adhesion substrate for IL-4-induced foreign body giant cell formation. J Biomed Mater Res A 86:535–543
Xie Z1, Paras CB, Weng H et al (2013) Dual growth factor releasing multi-functional nanofibers for wound healing. Acta Biomater 9:9351–9359
Alfaro MP, Vincent A, Saraswati S et al (2010) sFRP2 suppression of bone morphogenic protein (BMP) and Wnt signaling mediates mesenchymal stem cell (MSC) self-renewal promoting engraftment and myocardial repair. J Biol Chem 285:35645–35653
Andrade SP, Ferreira MA (2009) The sponge implant model of angiogenesis. Methods Mol Biol 467:295–304
Walluscheck KP, Bierkandt S, Brandt M, Cremer J (2005) Infrainguinal ePTFE vascular graft with bioactive surface heparin bonding. First clinical results. J Cardiovasc Surg 46:425–430
Adzick NS, Harrison MR, Glick PL et al (1985) Comparison of fetal, newborn, and adult wound healing by histologic, enzyme-histochemical, and hydroxyproline determinations. J Pediatr Surg 20:315–319
Goodson WH 3rd, Hunt TK (1986) Wound collagen accumulation in obese hyperglycemic mice. Diabetes 35:491–495
Goodson WH, Lopez SA, Jensen JA et al (1987) The influence of a brief preoperative illness on postoperative healing. Ann Surg 205:250–255
Orenstein SB, Saberski ER, Kreutzer DL, Novitsky YW (2012) Comparative analysis of histopathologic effects of synthetic meshes based on material, weight, and pore size in mice. J Surg Res 176:423–429
Junge K, Binnebösel M, von Trotha KT et al (2012) Mesh biocompatibility: effects of cellular inflammation and tissue remodelling. Langenbeck’s archives of surgery/Deutsche Gesellschaft fur Chirurgie 397:255–270
Rassaert CL, Dipasquale G, O’Donoghue S (1975) The evaluation of cotton twine as a new anti-inflammatory assay. Agents and actions 5:128–132
Heggers JP, Kossovsky N, Parsons RW et al (1983) Biocompatibility of silicone implants. Ann Plast Surg 11:38–45
Franca DC, de Castro AL, Soubhia AM, de Aguiar SM, Goiato MC (2013) Evaluation of the biocompatibility of silicone gel implants— histomorphometric study. Acta Inform Med 21:93–97
França DC, de Castro AL, Soubhia AM et al (2011) Biocompatibility evaluation of 3 facial silicone elastomers. J Craniofac Surg 22:837–840
Olbrich KC, Meade R, Bruno W et al (2005) Halofuginone inhibits collagen deposition in fibrous capsules around implants. Ann Plast Surg 54:293–296 discussion 296
Morehead JM, Holt GR (1994) Soft-tissue response to synthetic biomaterials. Otolaryngol Clin North Am 27:195–201
Ziats NP, Miller KM, Anderson JM (1988) In vitro and in vivo interactions of cells with biomaterials. Biomaterials 9:5–13
Tang L, Jennings TA, Eaton JW (1998) Mast cells mediate acute inflammatory responses to implanted biomaterials. Proc Natl Acad Sci U S A 95:8841–8846
Zdolsek J, Eaton JW, Tang L (2007) Histamine release and fibrinogen adsorption mediate acute inflammatory responses to biomaterial implants in humans. J Transl Med 5:31
Carr BJ, Ochoa L, Rankin D, Owens BD (2009) Biologic response to orthopedic sutures: a histologic study in a rabbit model. Orthopedics 32:828
Ratner BD (2002) Reducing capsular thickness and enhancing angiogenesis around implant drug release systems. J Control Release 78:211–218