Hydroxyapatite 3D-printed scaffolds with Gyroid-Triply periodic minimal surface porous structure: Fabrication and an in vivo pilot study in sheep.

Bouakaz, Islam; Drouet, Christophe; Grossin, David; Cobraiville, Elisabeth; Nolens, Gregory

doi:10.1016/j.actbio.2023.08.041

Article (Scientific journals)

Hydroxyapatite 3D-printed scaffolds with Gyroid-Triply periodic minimal surface porous structure: Fabrication and an in vivo pilot study in sheep.

Bouakaz, Islam; Drouet, Christophe; Grossin, David et al.

2023 • In Acta Biomaterialia, 170, p. 580 - 595

Peer Reviewed verified by ORBi

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https://hdl.handle.net/2268/345452

DOI
10.1016/j.actbio.2023.08.041

PubMed
37673232

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Keywords :

Additive manufacturing; Bone scaffolds; Gyroid; Hydroxyapatite; Large animal model; TPMS; Durapatite; Animals; Pilot Projects; Porosity; Sheep; Bone Regeneration; Surface Properties; Femur; Printing, Three-Dimensional; Tissue Scaffolds/chemistry; Durapatite/chemistry; Durapatite/pharmacology; Animal model; Bone repair; Gyroids; In-vivo; Pilot studies; Porous structures; Triply periodic minimal surfaces; Tissue Scaffolds; Biotechnology; Biochemistry; Biomaterials; Biomedical Engineering; Molecular Biology

Abstract :

[en] Bone repair is a major challenge in regenerative medicine, e.g. for large defects. There is a need for bioactive, highly percolating bone substitutes favoring bone ingrowth and tissue healing. Here, a modern 3D printing approach (VAT photopolymerization) was exploited to fabricate hydroxyapatite (HA) scaffolds with a Gyroid-"Triply periodic minimal surface" (TPMS) porous structure (65% porosity, 90.5% HA densification) inspired from trabecular bone. Percolation and absorption capacities were analyzed in gaseous and liquid conditions. Mechanical properties relevant to guided bone regeneration in non-load bearing sites, as for maxillofacial contour reconstruction, were evidenced from 3-point bending tests and macrospherical indentation. Scaffolds were implanted in a clinically-relevant large animal model (sheep femur), over 6 months, enabling thorough analyses at short (4 weeks) and long (26 weeks) time points. In vivo performances were systematically compared to the bovine bone-derived Bio-OssⓇ standard. The local tissue response was examined thoroughly by semi-quantitative histopathology. Results demonstrated the absence of toxicity. Bone healing was assessed by bone dynamics analysis through epifluorescence using various fluorochromes and quantitative histomorphometry. Performant bone regeneration was evidenced with similar overall performances to the control, although the Gyroid biomaterial slightly outperformed Bio-OssⓇ at early healing time in terms of osteointegration and appositional mineralization. This work is considered a pilot study on the in vivo evaluation of TPMS-based 3D porous scaffolds in a large animal model, for an extended period of time, and in comparison to a clinical standard. Our results confirm the relevance of such scaffolds for bone regeneration in view of clinical practice. STATEMENT OF SIGNIFICANCE: Bone repair, e.g. for large bone defects or patients with defective vascularization is still a major challenge. Highly percolating TPMS porous structures have recently emerged, but no in vivo data were reported on a large animal model of clinical relevance and comparing to an international standard. Here, we fabricated TPMS scaffolds of HA, determined their chemical, percolation and mechanical features, and ran an in-depth pilot study in the sheep with a systematic comparison to the Bio-OssⓇ reference. Our results clearly show the high bone-forming capability of such scaffolds, with outcomes even better than Bio-OssⓇ at short implantation time. This preclinical work provides quantitative data validating the relevance of such TMPS porous scaffolds for bone regeneration in view of clinical evaluation.

Disciplines :

Surgery
Materials science & engineering

Author, co-author :

Bouakaz, Islam ; CERHUM - PIMW, 4000 Liège, Belgium, CIRIMAT, Université de Toulouse, CNRS / Toulouse INP / UT3, 31030 Toulouse, France

Drouet, Christophe ; CIRIMAT, Université de Toulouse, CNRS / Toulouse INP / UT3, 31030 Toulouse, France. Electronic address: christophe.drouet@cirimat.fr

Grossin, David ; CIRIMAT, Université de Toulouse, CNRS / Toulouse INP / UT3, 31030 Toulouse, France

Cobraiville, Elisabeth ; Université de Liège - ULiège > Aérospatiale et Mécanique (A&M) ; CERHUM - PIMW, 4000 Liège, Belgium

Nolens, Gregory ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Génie biomécanique ; CERHUM - PIMW, 4000 Liège, Belgium, Faculty of Medicine, University of Namur, 5000 Namur, Belgium. Electronic address: gregory.nolens@cerhum.com

Language :

English

Title :

Hydroxyapatite 3D-printed scaffolds with Gyroid-Triply periodic minimal surface porous structure: Fabrication and an in vivo pilot study in sheep.

Publication date :

15 October 2023

Journal title :

Acta Biomaterialia

ISSN :

1742-7061

eISSN :

1878-7568

Publisher :

Acta Materialia Inc, England

Volume :

170

Pages :

580 - 595

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://api.elsevier.com/content/article/PII:S1742706123005056?httpAccept=text/xml

Funders :

European Union. Marie Skłodowska-Curie Actions
Walloon Region
EU - European Union
Région Occitanie Pyrénées-Méditerranée

Funding text :

DOC-3D-Printing and DOC-3D-Occitanie: The DOC-3D-Printing project has received funding from the European Union's Horizon 2020 research and innovation programme under the Marie Sk\u0142odowska-Curie grant agreement No. 764935. The DOC-3D-Occitanie project has received funding from the \u201CR\u00E9gion Occitanie\u201D under the REPERE action No. 18022525.This work was supported in part by the following projects:This work was supported in part by the following projects:, DOC-3D-Printing and DOC-3D-Occitanie: The DOC-3D-Printing project has received funding from the European Union's Horizon 2020 research and innovation programme under the Marie Sk\u0142odowska-Curie grant agreement No. 764935. The DOC-3D-Occitanie project has received funding from the \u201CR\u00E9gion Occitanie\u201D under the REPERE action No. 18022525. DOVIMIS: The DOVIMIS project has received funding from the European Union's FEDER \u201CWallonie 2020.EU\u201D program and the Walloon Region government under the program COOTECH MIX grant agreement No. 7931.

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Bibliography

Boskey, A.L., Mineral-matrix interactions in bone and cartilage. Clin. Orthop. Relat. Res., 1992, 244–274.
Bonjour, J.P., Calcium and phosphate: a duet of ions playing for bone health. J. Am. Coll. Nutr. 30:5 (2011), 438S–448S.
Driessens, F.C.M., Vandijk, J.W.E., Verbeeck, R.M.H., The role of bone mineral in calcium and phosphate homeostasis. Bull. Soc. Chim. Belg. 95:5-6 (1986), 337–342.
Huggins, C., The composition of bone and the function of the bone cell. Physiol. Rev. 17:1 (1937), 119–143.
Rey, C., Combes, C., Drouet, C., Glimcher, M.J., Bone mineral: update on chemical composition and structure. Osteoporos. Int. 20:6 (2009), 1013–1021.
Von Euw, S., Wang, Y., Laurent, G., Drouet, C., Babonneau, F., Nassif, N., Azaïs, T., Bone mineral: new insights into its chemical composition. Sci. Rep., 9(1), 2019, 8456.
Brandi, M.L., Microarchitecture, the key to bone quality. Rheumatology, 48(Suppl 4), 2009 (February): p. iv3-8.
Sakkas, A., Wilde, F., Heufelder, M., Winter, K., Schramm, A., Autogenous bone grafts in oral implantology—is it still a “gold standard”? A consecutive review of 279 patients with 456 clinical procedures. Int. J. Implant Dentistry, 3(1), 2017, 23.
Stevenson, S., Biology of bone grafts. Orthop. Clin. North Am. 30:4 (1999), 543–552.
Ou, Q., Wu, P., Zhou, Z., Pan, D., Tang, J.Y., Complication of osteo reconstruction by utilizing free vascularized fibular bone graft. BMC Surgery, 20(1), 2020, 216.
Arrington, E.D., Smith, W.J., Chambers, H.G., Bucknell, A.L., Davino, N.A., Complications of iliac crest bone graft harvesting. Clin. Orthop. Relat. Res.(329), 1996, 300–309.
Migliorini, F., La Padula, G., Torsiello, E., Spiezia, F., Oliva, F., Maffulli, N., Strategies for large bone defect reconstruction after trauma, infections or tumour excision: a comprehensive review of the literature. Eur. J. Med. Res., 26(1), 2021, 118.
Galindo-Moreno, P., Hernández-Cortés, P., Mesa, F., Carranza, N., Juodzbalys, G., Aguilar, M., O'Valle, F., Slow resorption of anorganic bovine bone by osteoclasts in maxillary sinus augmentation. Clin. Implant Dent. Relat. Res. 15:6 (2013), 858–866.
Mordenfeld, A., Hallman, M., Johansson, C.B., Albrektsson, T., Histological and histomorphometrical analyses of biopsies harvested 11 years after maxillary sinus floor augmentation with deproteinized bovine and autogenous bone. Clin. Oral. Implants Res. 21:9 (2010), 961–970.
Traini, T., Valentini, P., Iezzi, G., Piattelli, A., A histologic and histomorphometric evaluation of anorganic bovine bone retrieved 9 years after a sinus augmentation procedure. J. Periodontol. 78:5 (2007), 955–961.
Maiorana, C., Beretta, M., Salina, S., Santoro, F., Reduction of autogenous bone graft resorption by means of bio-oss coverage: a prospective study. Int. J. Periodontics Restorative Dent. 25:1 (2005), 19–25.
Aghaloo, T.L., Moy, P.K., Which hard tissue augmentation techniques are the most successful in furnishing bony support for implant placement?. Int. J. Oral Maxillofac. Implants 22:Suppl (2007), 49–70.
Jung, R.E., Fenner, N., Hämmerle, C.H., Zitzmann, N.U., Long-term outcome of implants placed with guided bone regeneration (GBR) using resorbable and non-resorbable membranes after 12-14 years. Clin. Oral. Implants Res. 24:10 (2013), 1065–1073.
Orsini, G., Scarano, A., Degidi, M., Caputi, S., Iezzi, G., Piattelli, A., Histological and ultrastructural evaluation of bone around Bio-Oss particles in sinus augmentation. Oral Dis. 13:6 (2007), 586–593.
Yoshikawa, H., Tamai, N., Murase, T., Myoui, A., Interconnected porous hydroxyapatite ceramics for bone tissue engineering. J. R. Soc., Interface 6:suppl_3 (2008), S341–S348.
Tamai, N., Myoui, A., Tomita, T., Nakase, T., Tanaka, J., Ochi, T., Yoshikawa, H., Novel hydroxyapatite ceramics with an interconnective porous structure exhibit superior osteoconduction in vivo. J. Biomed. Mater. Res. 59 (2002), 110–117.
Bal, Z., Kaito, T., Korkusuz, F., Yoshikawa, H., Bone regeneration with hydroxyapatite-based biomaterials. Emergent Mater. 3:4 (2020), 521–544.
Markovic, S., Veselinovic, L., Lukic, M.J., Karanovic, L., Bracko, I., Ignjatovic, N., Uskokovic, D., Synthetical bone-like and biological hydroxyapatites: a comparative study of crystal structure and morphology. Biomed. Mater., 6(4), 2011.
Bouler, J.M., Pilet, P., Gauthier, O., Verron, E., Biphasic calcium phosphate ceramics for bone reconstruction: A review of biological response. Acta Biomater. 53 (2017), 1–12.
Hing, K.A., Bioceramic bone graft substitutes: influence of porosity and chemistry. Int. J. Appl. Ceram. Technol. 2:3 (2005), 184–199.
Gauthier, O., Bouler, J.-M., Aguado, E., Pilet, P., Daculsi, G., Macroporous biphasic calcium phosphate ceramics: influence of macropore diameter and macroporosity percentage on bone ingrowth. Biomaterials 19:1 (1998), 133–139.
Bobbert, F.S.L., Zadpoor, A.A., Effects of bone substitute architecture and surface properties on cell response, angiogenesis, and structure of new bone. J. Mater. Chem. B 5:31 (2017), 6175–6192.
Bignon, A., Chouteau, J., Chevalier, J., Fantozzi, G., Carret, J.P., Chavassieux, P., Boivin, G., Melin, M., Hartmann, D., Effect of micro- and macroporosity of bone substitutes on their mechanical properties and cellular response. J. Mater. Sci. Mater. Med. 14:12 (2003), 1089–1097.
Khang, D., Lu, J., Yao, C., Haberstroh, K.M., Webster, T.J., The role of nanometer and sub-micron surface features on vascular and bone cell adhesion on titanium. Biomaterials 29:8 (2008), 970–983.
Yuan, H.P., Kurashina, K., de Bruijn, J.D., Li, Y.B., de Groot, K., Zhang, X.D., A preliminary study on osteoinduction of two kinds of calcium phosphate ceramics. Biomaterials 20:19 (1999), 1799–1806.
Klenke, F.M., Liu, Y., Yuan, H., Hunziker, E.B., Siebenrock, K.A., Hofstetter, W., Impact of pore size on the vascularization and osseointegration of ceramic bone substitutes in vivo. J. Biomedical Mater. Res. Part A 85A:3 (2008), 777–786.
Feng, B., Jinkang, Z., Zhen, W., Jianxi, L., Jiang, C., Jian, L., Guolin, M., Xin, D., The effect of pore size on tissue ingrowth and neovascularization in porous bioceramics of controlled architecture in vivo. Biomed. Mater., 6(1), 2011, 015007.
Karageorgiou, V., Kaplan, D., Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials 26:27 (2005), 5474–5491.
Klawitter, J.J., Hulbert, S.F., Application of porous ceramics for the attachment of load bearing internal orthopedic applications. J. Biomed. Mater. Res. 5:6 (1971), 161–229.
von Doernberg, M.-C, von Rechenberg, B., Bohner, M., Grünenfelder, S., van Lenthe, G.H., Müller, R., Gasser, B., Mathys, R., Baroud, G., Auer, J., In vivo behavior of calcium phosphate scaffolds with four different pore sizes. Biomaterials 27:30 (2006), 5186–5198.
Li, J., Zhi, W., Xu, T., Shi, F., Duan, K., Wang, J., Mu, Y., Weng, J., Ectopic osteogenesis and angiogenesis regulated by porous architecture of hydroxyapatite scaffolds with similar interconnecting structure in vivo. Regener. Biomateri. 3:5 (2016), 285–297.
Mirkhalaf, M., Wang, X., Entezari, A., Dunstan, C.R., Jiang, X., Zreiqat, H., Redefining architectural effects in 3D printed scaffolds through rational design for optimal bone tissue regeneration. Appl. Mater. Today, 25, 2021, 101168.
Van hede, D., Liang, B., Anania, S., Barzegari, M., Verlée, B., Nolens, G., Pirson, J., Geris, L., Lambert, F., 3D-printed synthetic hydroxyapatite scaffold with in silico optimized macrostructure enhances bone formation in vivo. Adv. Funct. Mater., 32(6), 2022, 2105002.
Rumpler, M., Woesz, A., Dunlop, J.W.C., van Dongen, J.T., Fratzl, P., The effect of geometry on three-dimensional tissue growth. J. R. Soc. Interface 5:27 (2008), 1173–1180.
Bidan, C.M., Kommareddy, K.P., Rumpler, M., Kollmannsberger, P., Bréchet, Y.J., Fratzl, P., Dunlop, J.W., How linear tension converts to curvature: geometric control of bone tissue growth. PLoS One, 7(5), 2012, e36336.
Knychala, J., Bouropoulos, N., Catt, C.J., Katsamenis, O.L., Please, C.P., Sengers, B.G., Pore geometry regulates early stage human bone marrow cell tissue formation and organisation. Ann. Biomed. Eng. 41:5 (2013), 917–930.
Drouet, C., Barré, R., Brunel, G., Dechambre, G., Benqué, E., Combes, C., Rey, C., Impact of calcium phosphate particle morphology on osteoconduction: an in vivo study. Bioceramics 20:Parts 1 and 2 (2008), 361–363 p. 1371.
Griffith, M.L., Halloran, J.W., Freeform fabrication of ceramics via stereolithography. J. Am. Ceram. Soc. 79:10 (1996), 2601–2608.
Chen, Z., Li, Z., Li, J., Liu, C., Lao, C., Fu, Y., Liu, C., Li, Y., Wang, P., He, Y., 3D printing of ceramics: a review. J. Eur. Ceram. Soc. 39:4 (2019), 661–687.
Chu, T.M.G., Halloran, J.W., Hollister, S.J., Feinberg, S.E., Hydroxyapatite implants with designed internal architecture. J. Mater. Sci. 12:6 (2001), 471–478.
Deng, Y., Mieczkowski, M., Three-dimensional periodic cubic membrane structure in the mitochondria of amoebae Chaos carolinensis. Protoplasma 203:1 (1998), 16–25.
Saranathan, V., Osuji, C.O., Mochrie, S.G., Noh, H., Narayanan, S., Sandy, A., Dufresne, E.R., Prum, R.O., Structure, function, and self-assembly of single network gyroid (I4132) photonic crystals in butterfly wing scales. Proc. Natl. Acad. Sci. U. S. A. 107:26 (2010), 11676–11681.
Iyer, J., Moore, T., Nguyen, D., Roy, P., Stolaroff, J., Heat transfer and pressure drop characteristics of heat exchangers based on triply periodic minimal and periodic nodal surfaces. Appl. Therm. Eng., 209, 2022, 118192.
Seuba, J., Deville, S., Guizard, C., Stevenson, A.J., The effect of wall thickness distribution on mechanical reliability and strength in unidirectional porous ceramics. Sci. Technol. Adv. Mater. 17:1 (2016), 128–135.
Lu, F., Wu, R., Shen, M., Xie, L., Liu, M., Li, Y., Xu, S., Wan, L., Yang, X., Gao, C., Gou, Z., Rational design of bioceramic scaffolds with tuning pore geometry by stereolithography: microstructure evaluation and mechanical evolution. J. Eur. Ceram. Soc. 41:2 (2021), 1672–1682.
Goutagny, C., Hocquet, S., Hautcoeur, D., Lasgorceix, M., Somers, N., Leriche, A., Development of calcium phosphate suspensions suitable for the stereolithography process. Open Ceram., 7, 2021, 100167.
Yao, Y., Qin, W., Xing, B., Sha, N., Jiao, T., Zhao, Z., High performance hydroxyapatite ceramics and a triply periodic minimum surface structure fabricated by digital light processing 3D printing. J. Adv. Ceram. 10:1 (2021), 39–48.
Charbonnier, B., Manassero, M., Bourguignon, M., Decambron, A., El-Hafci, H., Morin, C., Leon, D., Bensidoum, M., Corsia, S., Petite, H., Marchat, D., Potier, E., Custom-made macroporous bioceramic implants based on triply-periodic minimal surfaces for bone defects in load-bearing sites. Acta Biomater. 109 (2020), 254–266.
Ramírez, J.A., Ospina, V., Rozo, A.A., Viana, M.I., Ocampo, S., Restrepo, S., Vásquez, N.A., Paucar, C., García, C., Influence of geometry on cell proliferation of PLA and alumina scaffolds constructed by additive manufacturing. J. Mater. Res. 34:22 (2019), 3757–3765.
Melchels, F.P.W., Barradas, A.M.C., van Blitterswijk, C.A., de Boer, J., Feijen, J., Grijpma, D.W., Effects of the architecture of tissue engineering scaffolds on cell seeding and culturing. Acta Biomater. 6:11 (2010), 4208–4217.
Paré, A., Charbonnier, B., Tournier, P., Vignes, C., Veziers, J., Lesoeur, J., Laure, B., Bertin, H., De Pinieux, G., Cherrier, G., Guicheux, J., Gauthier, O., Corre, P., Marchat, D., Weiss, P., Tailored three-dimensionally printed triply periodic calcium phosphate implants: a preclinical study for craniofacial bone repair. ACS Biomater. Sci. Eng. 6:1 (2020), 553–563.
Zhang, Q., Ma, L., Ji, X., He, Y., Cui, Y., Liu, X., Xuan, C., Wang, Z., Yang, W., Chai, M., Shi, X., High-strength hydroxyapatite scaffolds with minimal surface macrostructures for load-bearing bone regeneration. Adv. Funct. Mater., 32(33), 2022, 2204182.
Li, L., Shi, J., Zhang, K., Yang, L., Yu, F., Zhu, L., Liang, H., Wang, X., Jiang, Q., Early osteointegration evaluation of porous Ti6Al4V scaffolds designed based on triply periodic minimal surface models. J. Orthop. Transl. 19 (2019), 94–105.
Li, L., Wang, P., Jin, J., Xie, C., Xue, B., Lai, J., Zhu, L., Jiang, Q., The triply periodic minimal surface-based 3D printed engineering scaffold for meniscus function reconstruction. Biomater. Res., 26(1), 2022, 45.
Thygesen, T., Slots, C., Jensen, M.B., Ditzel, N., Kassem, M., Langhorn, L., Andersen, M.Ø., Comparison of off-the-shelf β-tricalcium phosphate implants with novel resorbable 3D printed implants in mandible ramus of pigs. Bone, 159, 2022, 116370.
Paré, A., Charbonnier, B., Veziers, J., Vignes, C., Dutilleul, M., De Pinieux, G., Laure, B., Bossard, A., Saucet-Zerbib, A., Touzot-Jourde, G., Weiss, P., Corre, P., Gauthier, O., Marchat, D., Standardized and axially vascularized calcium phosphate-based implants for segmental mandibular defects: a promising proof of concept. Acta Biomater. 154 (2022), 626–640.
Castro, A.P.G., Pires, T., Santos, J.E., Gouveia, B.P., Fernandes, P.R., Permeability versus design in TPMS scaffolds. Materials, 12, 2019, 10.3390/ma12081313.
Santos, J., Pires, T., Gouveia, B.P., Castro, A.P.G., Fernandes, P.R., On the permeability of TPMS scaffolds. J. Mech. Behav. Biomed. Mater., 110, 2020, 103932.
Yang, E., Leary, M., Lozanovski, B., Downing, D., Mazur, M., Sarker, A., Khorasani, A., Jones, A., Maconachie, T., Bateman, S., Easton, M., Qian, M., Choong, P., Brandt, M., Effect of geometry on the mechanical properties of Ti-6Al-4V Gyroid structures fabricated via SLM: a numerical study. Mater. Des., 184, 2019, 108165.
Glatt, V., Evans, C.H., Tetsworth, K., A concert between biology and biomechanics: the influence of the mechanical environment on bone healing. Front. Physiol., 7, 2016, 678.
Hine, P.J., Leejarkpai, T., Khosravi, E., Duckett, R.A., Feast, W.J., Structure property relationships in linear and cross-linked poly(imidonorbornenes) prepared using ring opening metathesis polymerisation (ROMP). Polymer 42:23 (2001), 9413–9422.
Andrzejewska, E., Photopolymerization kinetics of multifunctional monomers. Prog. Polym. Sci. 26:4 (2001), 605–665.
Jackson, N., Assad, M., Vollmer, D., Stanley, J., Chagnon, M., Histopathological evaluation of orthopedic medical devices: the state-of-the-art in animal models, imaging, and histomorphometry techniques. Toxicol. Pathol. 47:3 (2019), 280–296.
Pei, Y., Agostini, F., Skoczylas, F., Rehydration on heat-treated cementitious materials up to 700°C-coupled transport properties characterization. Constr. Build. Mater. 144 (2017), 650–662.
Pennella, F., Cerino, G., Massai, D., Gallo, D., Falvo D'Urso Labate, G., Schiavi, A., Deriu, M.A., Audenino, A., Morbiducci, U., A survey of methods for the evaluation of tissue engineering scaffold permeability. Ann. Biomed. Eng. 41:10 (2013), 2027–2041.
Paknahad, A., Kucko, N.W., Leeuwenburgh, S.C.G., Sluys, L.J., Experimental and numerical analysis on bending and tensile failure behavior of calcium phosphate cements. J. Mech. Behav. Biomed. Mater., 103, 2020, 103565.
Yasuda, H.Y., Mahara, S., Nishiyama, T., Umakoshi, Y., Preparation of hydroxyapatite/α-tricalcium phosphate composites by colloidal process. Sci. Technol. Adv. Mater. 3:1 (2002), 29–33.
Sagadevan, S., Murugasen, P., Novel analysis on the influence of tip radius and shape of the nanoindenter on the hardness of materials. Procedia Mater. Sci. 6 (2014), 1871–1878.
Zhang, L., Feih, S., Daynes, S., Chang, S., Wang, M.Y., Wei, J., Lu, W.F., Pseudo-ductile fracture of 3D printed alumina triply periodic minimal surface structures. J. Eur. Ceram. Soc. 40:2 (2020), 408–416.
Le Guéhennec, L., Van hede, D., Plougonven, E., Nolens, G., Verlée, B., De Pauw, M.-C., Lambert, F., In vitro and in vivo biocompatibility of calcium-phosphate scaffolds three-dimensional printed by stereolithography for bone regeneration. J. Biomedical Mater. Res. Part A 108:3 (2020), 412–425.
Isaacson, N., Lopez-Ambrosio, K., Chubb, L., Waanders, N., Hoffmann, E., Witt, C., James, S., Prawel, D.A., Compressive properties and failure behavior of photocast hydroxyapatite gyroid scaffolds vary with porosity. J. Biomater. Appl. 37:1 (2022), 55–76.
Lee, J.-W., Lee, Y.H., Lee, H., Koh, Y.H., Kim, H.E., Improving mechanical properties of porous calcium phosphate scaffolds by constructing elongated gyroid structures using digital light processing. Ceram. Int. 47:3 (2021), 3252–3258.