In terms of large bone defect reconstructions, massive bone allografts may sometimes be the only solution. However, they are still burdened with a high postoperative complication rate. Our hypothesis is that the immunogenicity of residual cells in the graft is involved in this issue. Decellularization by perfusion might therefore be the answer to process and create more biologically effective massive bone allografts. Seventy-two porcine bones were used to characterize the efficiency of our sodium hydroxide-based decellularization protocol. A sequence of solvent perfusion through each nutrient artery was set up to ensure the complete decellularization of whole long bones. Qualitative (histology and immunohistochemistry [IHC]) and quantitative (fluoroscopic absorbance and enzyme-linked immunosorbent assay) evaluations were performed to assess the decellularization and the preservation of the extracellular matrix in the bone grafts. Cytotoxicity and compatibility were also tested. Comparatively to nontreated bones, our experiments showed a very high decellularization quality, demonstrating that perfusion is mandatory to achieve an entire decellularization. Moreover, results showed a good preservation of the bone composition and microarchitecture, Haversian systems and vascular network included. This protocol reduces the human leukocyte antigen antigenic load of the graft by >50%. The majority of measured growth factors is still present in the same amount in the decellularized bones compared to the nontreated bones. Histology and IHC show that the bones were cell compatible, noncytotoxic, and capable of inducing osteoblastic differentiation of mesenchymal stem cells. Our decellularization/perfusion protocol allowed to create decellularized long bone graft models, thanks to their inner vascular network, ready for in vivo implantation or to be further used as seeding matrices.
Impact statement
This study lays the foundation for a multitude of other experiments on the subject of bone tissue engineering (in vitro, in vivo, biomechanical, preclinical, and human in vitro). The vascular approach to bone redefines tissue more as an organ. The results presented here bring us closer to a major improvement in the biological integration of massive bone allografts. We expect clinical transposition in <5 years.
Get full access to this article
View all access options for this article.
References
1.
BlaudezF, IvanovskiS, HamletS, et al.An overview of decellularisation techniques of native tissues and tissue engineered products for bone, ligament and tendon regeneration. Methods San Diego Calif, 2020; 171:28–40; doi: 10.1016/j.ymeth.2019.08.002.
2.
CravediP, FaroukS, AngelettiA, et al.Regenerative immunology: The immunological reaction to biomaterials. Transpl Int Off J Eur Soc Organ Transplant, 2017; 30(12):1199–1208; doi: 10.1111/tri.13068.
3.
DePaulaCA, TruncaleKG, GertzmanAA, et al.Effects of hydrogen peroxide cleaning procedures on bone graft osteoinductivity and mechanical properties. Cell Tissue Bank, 2005; 6(4):287–298; doi: 10.1007/s10561-005-3148-2.
4.
PereiraAR, RudertM, HerrmannM. Decellularized human bone as a 3D model to study skeletal progenitor cells in a natural environment. Methods Cell Biol, 2020; 157:123–141; doi: 10.1016/bs.mcb.2019.11.018.
5.
RothrauffBB, TuanRS. Decellularized bone extracellular matrix in skeletal tissue engineering. Biochem Soc Trans, 2020; 48(3):755–764; doi: 10.1042/BST20190079.
6.
TaylorB, IndanoS, YankannahY, et al.Decellularized cortical bone scaffold promotes organized neovascularization in vivo. Tissue Eng Part A, 2019; 25(13–14):964–977; doi: 10.1089/ten.TEA.2018.0225.
7.
CrapoPM, GilbertTW, BadylakSF. An overview of tissue and whole organ decellularization processes. Biomaterials, 2011; 32(12):3233–3243; doi: 10.1016/j.biomaterials.2011.01.057.
8.
PoornejadN, MomtahanN, SalehiASM, et al.Efficient decellularization of whole porcine kidneys improves reseeded cell behavior. Biomed Mater, 2016; 11:025003; doi: 10.1088/1748-6041/11/2/025003.
9.
EivazkhaniF, AbtahiNS, TavanaS, et al.Evaluating two ovarian decellularization methods in three species. Mater Sci Eng C Mater Biol Appl, 2019; 102:670–682; doi: 10.1016/j.msec.2019.04.092.
10.
CortiellaJ, NilesJ, CantuA, et al.Influence of acellular natural lung matrix on murine embryonic stem cell differentiation and tissue formation. Tissue Eng Part A, 2010; 16(8):2565–2580; doi: 10.1089/ten.tea.2009.0730.
11.
ShupeT, WilliamsM, BrownA, et al.Method for the decellularization of intact rat liver. Organogenesis, 2010; 6(2):134–136; doi: 10.4161/org.6.2.11546.
12.
KeaneTJ, SwinehartIT, BadylakSF. Methods of tissue decellularization used for preparation of biologic scaffolds and in vivo relevance. Methods San Diego Calif, 2015; 84:25–34; doi: 10.1016/j.ymeth.2015.03.005.
13.
OttHC, MatthiesenTS, GohS-K, et al.Perfusion-decellularized matrix: Using nature's platform to engineer a bioartificial heart. Nat Med, 2008; 14(2):213–221; doi: 10.1038/nm1684.
14.
WainwrightJM, CzajkaCA, PatelUB, et al.Preparation of cardiac extracellular matrix from an intact porcine heart. Tissue Eng Part C Methods, 2010; 16(3):525–532; doi: 10.1089/ten.tec.2009.0392.
15.
OttHC, ClippingerB, ConradC, et al.Regeneration and orthotopic transplantation of a bioartificial lung. Nat Med, 2010; 16(8):927–933; doi: 10.1038/nm.2193.
16.
SengyokuH, TsuchiyaT, ObataT, et al.Sodium hydroxide based non-detergent decellularizing solution for rat lung. Organogenesis, 2018; 14(2):94–106; doi: 10.1080/15476278.2018.1462432.
17.
BadylakSF, TaylorD, UygunK. Whole-organ tissue engineering: Decellularization and recellularization of three-dimensional matrix scaffolds. Annu Rev Biomed Eng, 2011; 13:27–53; doi: 10.1146/annurev-bioeng-071910-124743.
18.
PetersenTH, CalleEA, ZhaoL, et al.Tissue-engineered lungs for in vivo implantation. Science, 2010; 329(5991):538–541; doi: 10.1126/science.1189345.
19.
RougierG, MaistriauxL, FievéL, et al.Decellularized vascularized bone grafts: A preliminary in vitro porcine model for bioengineered transplantable bone shafts. Front Bioeng Biotechnol, 2022; 10:1003861; doi: 10.3389/fbioe.2022.1003861.
20.
HellerU, EvrardR, LengeléB, et al.Decellularized vascularized bone grafts as therapeutic solution for bone reconstruction: A mechanical evaluation. PLoS One, 2023; 18(1):e0280193; doi: 10.1371/journal.pone.0280193.
21.
TaylorDA, KrenSM, RhettK, et al.Characterization of perfusion decellularized whole animal body, isolated organs, and multi-organ systems for tissue engineering applications. Physiol Rep, 2021; 9(12):e14817; doi: 10.14814/phy2.14817.
22.
GerliMFM, GuyetteJP, Evangelista-LeiteD, et al.Perfusion decellularization of a human limb: A novel platform for composite tissue engineering and reconstructive surgery. PLoS One, 2018; 13(1):e0191497; doi: 10.1371/journal.pone.0191497.
23.
DuisitJ, AmielH, WüthrichT, et al.Perfusion-decellularization of human ear grafts enables ECM-based scaffolds for auricular vascularized composite tissue engineering. Acta Biomater, 2018; 73:339–354; doi: 10.1016/j.actbio.2018.04.009.
24.
PoornejadN, SchaumannLB, BuckmillerEM, et al.The impact of decellularization agents on renal tissue extracellular matrix. J Biomater Appl, 2016; 31(4):521–533; doi: 10.1177/0885328216656099.
25.
JankBJ, XiongL, MoserPT, et al.Engineered composite tissue as a bioartificial limb graft. Biomaterials, 2015; 61:246–256; doi: 10.1016/j.biomaterials.2015.04.051.
26.
van SteenbergheM, SchubertT, GerelliS, et al.Porcine pulmonary valve decellularization with NaOH-based vs detergent process: Preliminary in vitro and in vivo assessments. J Cardiothorac Surg, 2018; 13(1):34; doi: 10.1186/s13019-018-0720-y.
27.
van SteenbergheM, SchubertT, BouzinC, et al.Decellularized and secured porcine arteries with NaOH-based process: Proof of concept. Ann Vasc Surg, 2018; 49:179–190; doi: 10.1016/j.avsg.2017.12.013.
28.
van SteenbergheM, SchubertT, GuiotY, et al.Enhanced vascular biocompatibility of decellularized xeno-/allogeneic matrices in a rodent model. Cell Tissue Bank, 2017; 18(2):249–262; doi: 10.1007/s10561-017-9610-0.
29.
Fawzi-GrancherS, GoebbelsRM, BigareE, et al.Human tissue allograft processing: Impact on in vitro and in vivo biocompatibility. J Mater Sci Mater Med, 2009; 20(8):1709–1720; doi: 10.1007/s10856-009-3726-0.
30.
DelloyeC, CornuO, DruezV, et al.Bone allografts: What they can offer and what they cannot. J Bone Joint Surg Br, 2007; 89(5):574–579; doi: 10.1302/0301-620X.89B5.19039.
31.
DuisitJ, OrlandoG, DeblutsD, et al.Decellularization of the porcine ear generates a biocompatible, nonimmunogenic extracellular matrix platform for face subunit bioengineering. Ann Surg, 2018; 267(6):1191–1201; doi: 10.1097/SLA.0000000000002181.
32.
LallemandE, CoiffierG, ArvieuxC, et al.MALDI-TOF MS performance compared to direct examination, culture, and 16S rDNA PCR for the rapid diagnosis of bone and joint infections. Eur J Clin Microbiol Infect Dis Off Publ Eur Soc Clin Microbiol, 2016; 35(5):857–866; doi: 10.1007/s10096-016-2608-x.
33.
SchubertT, LafontS, BeaurinG, et al.Critical size bone defect reconstruction by an autologous 3D osteogenic-like tissue derived from differentiated adipose MSCs. Biomaterials, 2013; 34(18):4428–4438; doi: 10.1016/j.biomaterials.2013.02.053.
34.
SchubertT, PoilvacheH, GalliC, et al.Galactosyl-knock-out engineered pig as a xenogenic donor source of adipose MSCs for bone regeneration. Biomaterials, 2013; 34(13):3279–3289; doi: 10.1016/j.biomaterials.2013.01.057.
35.
UygunBE, Soto-GutierrezA, YagiH, et al.Organ reengineering through development of a transplantable recellularized liver graft using decellularized liver matrix. Nat Med, 2010; 16(7):814–820; doi: 10.1038/nm.2170.
36.
HondtMD, VanaudenaerdeBM, VerbekenEK, et al.Epithelial grafting of a decellularized whole-tracheal segment: An in vivo experimental model. Interact Cardiovasc Thorac Surg, 2018; 26(5):753–760; doi: 10.1093/icvts/ivx442.
37.
MaughanEF, ButlerCR, CrowleyC, et al.A comparison of tracheal scaffold strategies for pediatric transplantation in a rabbit model. Laryngoscope, 2017; 127(12):E449–E457; doi: 10.1002/lary.26611.
38.
Di MeglioF, NurzynskaD, RomanoV, et al.Optimization of human myocardium decellularization method for the construction of implantable patches. Tissue Eng Part C Methods, 2017; 23(9):525–539; doi: 10.1089/ten.TEC.2017.0267.
39.
WainwrightDJ. Use of an acellular allograft dermal matrix (AlloDerm) in the management of full-thickness burns. Burns J Int Soc Burn Inj, 1995; 21(4):243–248; doi: 10.1016/0305-4179(95)93866-i.
40.
MooreMA, SamsellB, WallisG, et al.Decellularization of human dermis using non-denaturing anionic detergent and endonuclease: A review. Cell Tissue Bank, 2015; 16(2):249–259; doi: 10.1007/s10561-014-9467-4.
41.
CollinsBH, CotterellAH, McCurryKR, et al.Cardiac xenografts between primate species provide evidence for the importance of the alpha-galactosyl determinant in hyperacute rejection. J Immunol Baltim Md 1950, 1995; 154(10):5500–5510.
42.
MacchiariniP, OriolR, AzimzadehA, et al.Evidence of human non-alpha-galactosyl antibodies involved in the hyperacute rejection of pig lungs and their removal by pig organ perfusion. J Thorac Cardiovasc Surg, 1998; 116(5):831–843; doi: 10.1016/s0022-5223(98)00447-4.
43.
LiJ, KsebatiMB, ZhangW, et al.Conformational analysis of an alpha-galactosyl trisaccharide epitope involved in hyperacute rejection upon xenotransplantation. Carbohydr Res, 1999; 315(1–2):76–88; doi: 10.1016/s0008-6215(98)00321-8.
44.
DelloyeC. How to improve the incorporation of massive allografts?. Chir Organi Mov, 2003; 88(4):335–343.
45.
GoldbergVM, StevensonS. The biology of bone grafts. Semin Arthroplasty, 1993; 4(2):58–63.
46.
LewandrowskiKU, RebmannV, PässlerM, et al.Immune response to perforated and partially demineralized bone allografts. J Orthop Sci Off J Jpn Orthop Assoc, 2001; 6(6):545–555; doi: 10.1007/s007760100011.
47.
MankinHJ, GebhardtMC, JenningsLC, et al.Long-term results of allograft replacement in the management of bone tumors. Clin Orthop Relat Res, 1996; 324:86–97.
48.
SandersPTJ, SpieringsJF, AlbergoJI, et al.Long-term clinical outcomes of intercalary allograft reconstruction for lower-extremity bone tumors. J Bone Joint Surg Am, 2020; 102(12):1042–1049; doi: 10.2106/JBJS.18.00893.
49.
WheelerDL, EnnekingWF. Allograft bone decreases in strength in vivo over time. Clin Orthop, 2005;(435):36–42; doi: 10.1097/01.blo.0000165850.58583.50.
50.
DanovaNA, ColopySA, RadtkeCL, et al.Degradation of bone structural properties by accumulation and coalescence of microcracks. Bone, 2003; 33(2):197–205; doi: 10.1016/s8756-3282(03)00155-8.
51.
BaldwinP, LiDJ, AustonDA, et al.Autograft, allograft, and bone graft substitutes: Clinical evidence and indications for use in the setting of orthopaedic trauma surgery. J Orthop Trauma, 2019; 33(4):203–213; doi: 10.1097/BOT.0000000000001420.
52.
Pirela-CruzMA, DeCosterTA. Vascularized bone grafts. Orthopedics, 1994; 17(5):407–412; doi: 10.3928/0147-7447-19940501-05.
53.
RancySK, SchmidleG, WolfeSW. Does anyone need a vascularized graft?. Hand Clin, 2019; 35(3):323–344; doi: 10.1016/j.hcl.2019.03.005.
54.
Aponte-TinaoLA, AyerzaMA, MuscoloDL, et al.What are the risk factors and management options for infection after reconstruction with massive bone allografts?. Clin Orthop, 2016; 474(3):669–673; doi: 10.1007/s11999-015-4353-3.
55.
Aponte-TinaoLA, AyerzaMA, AlbergoJI, et al.Do massive allograft reconstructions for tumors of the femur and tibia survive 10 or more years after implantation?. Clin Orthop, 2020; 478(3):517–524; doi: 10.1097/CORR.0000000000000806.
56.
RenX, MoserPT, GilpinSE, et al.Engineering pulmonary vasculature in decellularized rat and human lungs. Nat Biotechnol, 2015; 33(10):1097–1102; doi: 10.1038/nbt.3354.
57.
GilpinSE, CharestJM, RenX, et al.Bioengineering lungs for transplantation. Thorac Surg Clin, 2016; 26(2):163–171; doi: 10.1016/j.thorsurg.2015.12.004.
58.
ZhouH, KitanoK, RenX, et al.Bioengineering human lung grafts on porcine matrix. Ann Surg, 2018; 267(3):590–598; doi: 10.1097/SLA.0000000000002129.
59.
OhataK, OttHC. Human-scale lung regeneration based on decellularized matrix scaffolds as a biologic platform. Surg Today, 2020; 50(7):633–643; doi: 10.1007/s00595-020-02000-y.
60.
GilpinSE, OttHC. Using nature's platform to engineer bio-artificial lungs. Ann Am Thorac Soc, 2015; 12(Suppl. 1):S45–S49; doi: 10.1513/AnnalsATS.201408-366MG.
LichtmanMK, Otero-VinasM, FalangaV. Transforming growth factor beta (TGF-β) isoforms in wound healing and fibrosis. Wound Repair Regen Off Publ Wound Heal Soc Eur Tissue Repair Soc, 2016; 24(2):215–222; doi: 10.1111/wrr.12398.
63.
MorikawaM, DerynckR, MiyazonoK. TGF-β and the TGF-β Family: Context-dependent roles in cell and tissue physiology. Cold Spring Harb Perspect Biol, 2016; 8(5):a021873; doi: 10.1101/cshperspect.a021873.
64.
StiversKB, BeareJE, ChiltonPM, et al.Adipose-derived cellular therapies in solid organ and vascularized-composite allotransplantation. Curr Opin Organ Transplant, 2017; 22(5):490–498; doi: 10.1097/MOT.0000000000000452.
65.
PlockJA, SchniderJT, SchweizerR, et al.The influence of timing and frequency of adipose-derived mesenchymal stem cell therapy on immunomodulation outcomes after vascularized composite allotransplantation. Transplantation, 2017; 101(1):e1–e11; doi: 10.1097/TP.0000000000001498.
66.
PappalardoM, MontesanoL, ToiaF, et al.Immunomodulation in vascularized composite allotransplantation: What is the role for adipose-derived stem cells?. Ann Plast Surg, 2019; 82(2):245–251; doi: 10.1097/SAP.0000000000001763.
67.
ZhangR, WangZ, WangH, et al.Optimal pulmonary artery perfusion mode and perfusion pressure during cardiopulmonary bypass. J Cardiovasc Surg (Torino), 2010; 51(3):435–442.
68.
SchimaH, NewaldJ, KröslP, et al.Control of perfusion pressure and flow in isolated heart bioassays. J Biomed Eng, 1988; 10(5):387–392; doi: 10.1016/0141-5425(88)90140-9.
69.
PeggDE, GreenCJ. Renal preservation by hypothermic perfusion. I. The importance of pressure-control. Cryobiology, 1973; 10(1):56–66; doi: 10.1016/0011-2240(73)90008-4.
70.
HesterRL, GrangerJP, WilliamsJ, et al.Acute and chronic servo-control of renal perfusion pressure. Am J Physiol, 1983; 244(4):F455–F460; doi: 10.1152/ajprenal.1983.244.4.F455.
71.
GilJ, WeibelER. An improved apparatus for perfusion fixation with automatic pressure control. J Microsc, 1971; 94(3):241–244; doi: 10.1111/j.1365-2818.1971.tb02372.x.
72.
AminKR, StoneJP, KerrJ, et al.Randomized preclinical study of machine perfusion in vascularized composite allografts. Br J Surg, 2021; 108(5):574–582; doi: 10.1002/bjs.11921.
73.
AnastasescouM, CornuO, BanseX, et al.Ethanol treatment of tendon allografts: A potential HIV inactivating procedure. Int Orthop, 1998; 22(4):252–254; doi: 10.1007/s002640050253.
74.
DufraneD, MarchalC, CornuO, et al.Clinical application of a physically and chemically processed human substitute for dura mater. J Neurosurg, 2003; 98(6):1198–1202; doi: 10.3171/jns.2003.98.6.1198.
75.
LewandrowskiKU, TomfordWW, SchomackerKT, et al.Improved osteoinduction of cortical bone allografts: A study of the effects of laser perforation and partial demineralization. J Orthop Res Off Publ Orthop Res Soc, 1997; 15(5):748–756; doi: 10.1002/jor.1100150518.
76.
LewandrowskiKU, SchollmeierG, EkkemkampA, et al.Incorporation of perforated and demineralized cortical bone allografts. Part I: Radiographic and histologic evaluation. Biomed Mater Eng, 2001; 11(3):197–207.
77.
SpireB, Barré-SinoussiF, MontagnierL, et al.Inactivation of lymphadenopathy associated virus by chemical disinfectants. Lancet Lond Engl, 1984; 2(8408):899–901; doi: 10.1016/s0140-6736(84)90657-3.
78.
TomfordWW. Bone allografts: Past, present and future. Cell Tissue Bank, 2000; 1(2):105–109; doi: 10.1023/A:1010158731885.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
