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Abstract

Bone regeneration is often required to provide adequate oral rehabilitation before dental implants. Vertical ridge augmentation is the most challenging of all situations, and often requires the use of autologous bone grafting. However, autologous bone grafting induces morbidity, and the harvestable bone is limited in quantity. Alternatives to autologous bone grafting include bovine-bone-derived biomaterials, which provide good clinical results and synthetic bone substitutes that still fail to provide a reliable clinical outcome. Synthetic biomimetic calcium phosphate (SBCP) biomaterials, consisting of precipitated apatite crystals that resemble in composition and crystallinity to the mineral phase of bone, arise as alternatives to both bovine bone and the current sintered bone substitutes. This study aims to compare the vertical bone regeneration capacity of the SBCP (MimetikOss, Mimetis Biomaterials) with that of a deproteinized bovine bone matrix (DBBM, Bio-Oss^®; Geistlich Biomaterials) on the calvaria of rats. To model vertical bone augmentation, hemispherical cups were filled with the two types of biomaterial granules and implanted onto the skull of rats, while empty cups were used as controls. After 4 and 8 weeks of healing, bone growth was determined by microcomputed tomography and histomorphometry. After 4 weeks of implantation, a significantly higher bone growth was found in the case of SBCP compared with DBBM and left empty controls. At 8 weeks, no statistically significant differences were found between the two bone substitutes. These results are promising since vertical bone regeneration was faster in the case of SBCP than for DBBM.

Impact Statement

This work reports a new bone substitute made of precipitated apatite crystals that resemble in composition and crystallinity to the mineral phase of bone. The bone regeneration capacity of this synthetic biomimetic calcium phosphate (SBCP) was studied by using an original model of vertical bone regeneration with cups on the calvaria of rats. After 4 weeks, a significantly higher bone growth was found with SBCP compared with deproteinized bovine bone matrix and empty controls. This rapid vertical bone regeneration indicated that this new biomaterial is particularly interesting for filling bone defects in oral surgery.

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References

Aghaloo

T.L.

, and Moy

P.K.

Which hard tissue augmentation techniques are the most successful in furnishing bony support for implant placement?. Int J Oral Maxillofac Implants, 23, 56, 2007.

McAllister

B.S.

, and Haghighat

Bone augmentation techniques. J Periodontol, 78, 377, 2007.

Simion

, Jovanovic

S.A.

, Tinti

, and Benfenati

S.P.

Long-term evaluation of osseointegrated implants inserted at the time or after vertical ridge augmentation. A retrospective study on 123 implants with 1–5 year follow-up. Clin Oral Impl Res, 12, 35, 2001.

Cordaro

, Amadè

D.S.

, and Cordaro

Clinical results of alveolar ridge augmentation with mandibular block bone grafts in partially edentulous patients prior to implant placement. Clin Oral Impl Res, 13, 103, 2002.

Cordaro

, Torsello

, Tindara Miuccio

, Mirisola di Torresanto

, and Eliopoulos

Mandibular bone harvesting for alveolar reconstruction and implant placement: subjective and objective cross-sectional evaluation of donor and recipient site up to 4 years. Clin Oral Impl Res, 22, 1320, 2011.

Rissolo

A.R.

, and Bennett

Bone grafting and its essential role in implant dentistry. Dent Clin North Am, 42, 91, 1998.

Jensen

S.S.

, and Terheyden

Bone augmentation procedures in localized defects in the alveolar ridge: clinical results with different bone grafts and bone-substitute materials. Int J Oral Maxillofac Implants, 24(Suppl), 218, 2008.

Sanz

, and Vignoletti

Key aspects on the use of bone substitutes for bone regeneration of edentulous ridges. Dent Mater, 31, 640, 2015.

Lutz

, Neukam

F.W.

, Simion

, and Schmitt

C.M.

Long-term outcomes of bone augmentation on soft and hard-tissue stability: a systematic review. Clin Oral Impl Res, 26(Suppl 11), 103, 2015.

10.

Zhang

, Liu

, Schnitzler

, Tancret

, and Bouler

J.-M.

Calcium phosphate cements for bone substitution: chemistry, handling and mechanical properties. Acta Biomater, 10, 1035, 2014.

11.

Milani

, Dal Pozzo

, Rasperini

, Sforza

, and Dellavia

Deproteinized bovine bone remodeling pattern in alveolar socket: a clinical immunohistological evaluation. Clin Oral Impl Res, 27, 295, 2016.

12.

Galindo-Moreno

, Hernández-Cortés

, Mesa

, et al. Slow resorption of anorganic bovine bone by osteoclasts in maxillary sinus augmentation. Clin Implant Dent Relat Res, 15, 858, 2013.

13.

Kim

, Rodriguez

A.E.

, and Nowzari

The Risk of Prion Infection through Bovine Grafting Materials. Clin Implant Dent Relat Res, 18, 1095, 2016.

14.

Guo

, Su

, Wei

, Kong

, and Liu

Biocompatibility and osteogenicity of degradable Ca-deficient hydroxyapatite scaffolds from calcium phosphate cement for bone tissue engineering. Acta Biomater, 5, 268, 2009.

15.

Ben-Nissan

Advances in Calcium Phosphate Biomaterials. Springer Science & Business, Berlin, Heidelberg, 2014.

16.

Miron

R.J.

, Sculean

, Shuang

, et al. Osteoinductive potential of a novel biphasic calcium phosphate bone graft in comparison with autographs, xenografts, and DFDBA. Clin Oral Impl Res, 27, 668, 2016.

17.

Habibovic

, Yuan

, van der Valk

C.M.

, Meijer

, van Blitterswijk

C.A.

, and de Groot

3D microenvironment as essential element for osteoinduction by biomaterials. Biomaterials, 26, 3565, 2005.

18.

Lundgren

, Lundgren

A.K.

, Sennerby

, and Nyman

Augmentation of intramembraneous bone beyond the skeletal envelope using an occlusive titanium barrier. An experimental study in the rabbit. Clin Oral Impl Res, 6, 67, 1995.

19.

Yamada

, Nanba

, and Ito

Effects of occlusiveness of a titanium cap on bone generation beyond the skeletal envelope in the rabbit calvarium. Clin Oral Impl Res, 14, 455, 2003.

20.

Tamura

, Fukase

, Goke

, et al. Three-dimensional evaluation for augmented bone using guided bone regeneration. J Periodont Res, 40, 269, 2005.

21.

Yamada

, Tamura

, Hariu

, Asano

, Sato

, and Ito

Angiogenesis in newly augmented bone observed in rabbit calvarium using a titanium cap. Clin Oral Impl Res, 19, 1003, 2008.

22.

Knapen

, Gheldof

, Drion

, Layrolle

, Rompen

, and Lambert

Effect of leukocyte- and platelet-rich fibrin (L-PRF) on bone regeneration: a study in rabbits. Clin Implant Dent Relat Res, 17(Suppl 1), e1e143, 2015.

23.

Dundar

, Ozgur

, Yaman

, et al. Guided bone regeneration with local zoledronic acid and titanium barrier: an experimental study. Exp Ther Med, 12, 2015, 2016.

24.

Gjerde

, Mustafa

, Hellem

, et al. Cell therapy induced regeneration of severely atrophied mandibular bone in a clinical trial. Stem Cell Res Ther, 9, 213, 2018.

25.

Flautre

, Descamps

, Delecourt

, Blary

M.C.

, and Hardouin

Porous HA ceramic for bone replacement: role of the pores and interconnections - experimental study in the rabbit. J Mater Sci Mater Med, 12, 679, 2001.

26.

Brennan

M.Á.

, Renaud

, Amiaud

, et al. Pre-clinical studies of bone regeneration with human bone marrow stromal cells and biphasic calcium phosphate. Stem Cell Res Ther, 5, 114, 2014.

Vertical Bone Regeneration with Synthetic Biomimetic Calcium Phosphate onto the Calvaria of Rats

Abstract

Impact Statement

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