Catunda IS, Vasconcelos BCE, Corrêa MVM, Matos MF, Nogueira
EFC, Learreta JA. Non-invasive joint decompression: An important factor in the
regeneration of the bone marrow and disc recapture in temporomandibular
arthropathies. Med Oral Patol Oral Cir Bucal. 2018
Sep
1;23 (5):e506-10.
doi:10.4317/medoral.22397
http://dx.doi.org/doi:10.4317/medoral.22397
1.
Buser D, Hoffman B, Bernard JP, Lussi A, Mettler D, Schenk RK. Evaluation of filling
materials in membrane protected bone defects. A comparative histomorphometric
study in the mandible of miniature pigs. Clin Oral Implants Res.
1998;9:137-50. |
|
|
|
2.
Olszta MJ, Cheng X, Jee SS, Kumar R, Kim YY, Kaufman MJ, et al. Bone
structure and formation: A new perspective, Materials Science and Engineering
R. 2007;58:77–116. |
|
|
|
3.
O'Brien FJ. Biomaterials & scaffolds for tissue engineering. Mater Today.
2011;14:88–95. |
|
|
|
4.
Vlierberghe SV, Dubruel P, Schacht E. Biopolymer-based hydrogels as scaffolds
for tissue engineering applications: a review. Biomacromolecules.
2011;2:1387–408. |
|
|
|
5.
Di Martino A, Sittinger M, Risbud MV. Chitosan: a versatile biopolymer for orthopaedic
tissue-engineering. Biomaterials.
2005;26:5983–90. |
|
|
|
6.
Tigli RS, Karakecili A, Gumusderelioglu M. In vitro characterization of
chitosan scaffolds: influence of composition and deacetylation
degree. J Mater Sci: Mater Med. 2007;18:1665–74. |
|
|
|
7.
Cui W, Li X, Xie C, Chen J, Zou J, Zhou S, et al. Controllable growth of
hydroxyapatite on electrospun poly(dl-lactide) fibers grafted with
chitosan as potential tissueengineeringscaffolds. Polymer. 2010;51:2320–8. |
|
|
|
8.
Koutsopoulos S. Synthesis and characterization of hydroxyapatite crystals: A
review study on the analytical methods. J
Biomed Mater Res. 2002;62:600–12. |
|
|
|
9.
Hench LL. Bioceramics. J Am Ceram Soc. 1998;81:1705–28. |
|
|
|
10.
Blaker JJ, Gough JE, Maquet V, Notingher I, Boccaccini AR. In vitro
evaluation of novel bioactive composites based on Bioglass-filledpolylactide foams for bone tissue engineering scaffolds. J Biomed
Mater Res. 2003;67A:1401–11. |
|
|
|
11.
Castro F, Kuhn S, Jensen K, Ferreira A, Rocha F, Vicente A et al. Continuous-flow Precipitation of hydroxyapatite in ultrasonic Microsystems. ChemEng J 2013;215:979–87. |
|
|
|
12.
Kong L, Gao Y, Lu G, Gong Y, Zhao N, Zhang X. A study on the bioactivity of
chitosan/nano-hydroxyapatite composite scaffolds for bone tissue engineering.
Eur Polymer J. 2006;42:3171–9. |
|
|
|
13. Kashiwazaki H,
Kishiya Y, Matsuda A, Yamaguchi K, Iizuka T, Tanaka J et al. Fabrication of porous
chitosan/hydroxyapatite nanocomposites: their mechanical and biological
properties. BioMed Mater Eng.
2009;19:133–40. |
|
|
|
14.
Thein-Han WW, Misra RDK. Three-dimensional chitosan-nanohydroxyapatite composite
scaffolds for bone tissue engineering. JOM J Miner Metals Mater Soc.
2009;61:41–4. |
|
|
|
15.
Lee JS, Baek SD, Venkatesan J, Bhatnagar I, Chang HK, Kim HT et al. In vivo
study of chitosan-natural nano hydroxyapatite scaffolds. Int J BiolMacromol. 2014;67:360–6. |
|
|
|
16.
He Y, Dong Y, Cui F, Chen X, Lin R. Ectopic Osteogenesis and Scaffold
Biodegradation of Nano-Hydroxyapatite-Chitosan in a Rat Model. PLoS ONE. 2015;10:1-15. |
|
|
|
17.
Tsiourvas D, Sapalidis A, Papadopoulos T. Hydroxyapatite/chitosan-based
porous three-dimensional scaffolds with complex geometries. Mater Today. 2016;7:59-66. |
|
|
|
18.
Gomes PS, Fernandes MH. Rodent models in bone-related research: the relevance
of calvarial defects in the assessment of bone regeneration strategies. Lab Anim.2011;45:14-24. |
|
|
|
19.
Tsiourvas D, Tsetsekou A, Kammenou MI, Boukos N. Controlling the formation of
hydroxyapatite nanorods with dendrimers. J Am
Ceram Soc. 2011;94:2023–9. |
|
|
|
20.
Kuo YC, Tsai YT. Inverted Colloidal Crystal Scaffolds for Uniform Cartilage
Regeneration, Biomacromolecules. 2010;11:731–9. |
|
|
|
21.
Ghiacci G, Graiani G, Ravanetti F, Lumetti S, Manfredi E, Galli C, et al.
"Over-inlay" block graft and differential morphometry: a novel
block graft model to study bone regeneration and host-to-graft interfaces in
rats. J Periodontal Implant Sci. 2016;46:220-3. |
|
|
|
22.
Kim RW, Kim JH, Moon SY. Effect of hydroxyapatite on critical-sized defect. Maxillofacial
Plastic and Reconstructive Surgery. 2016;38:1-6. |
|
|
|
23.
Kim JY, Yang BE, Ahn JH, Park SO, Shim HW. Comparable efficacy of silk
fibroin with the collagen membranes for guided bone regeneration in rat
calvarial defects. J AdvProsthodont.
2014;6:539-46. |
|
|
|
24.
Donos N, Dereka X, Mardas N. Experimental models for guided bone regeneration
in healthy and medically compromised conditions. Periodontology 2000.2015;68:99-121. |
|
|
|
25.
Gao R, Watson M, Callon KE, Tuari D, Dray M, Naot D, et al. Local application
of lactoferrin promotes bone regeneration in a rat critical-sized calvarial defect
model as demonstrated by micro-CT and histological analysis. J Tissue Eng
Regen Med.2018;12:620-6. |
|
|
|
26.
Vajgel A, Mardas N, Farias BC, Petrie A, Cimoes R, Donos N. A systematic
review on the critical size defect model. Clin
Oral Impl Res. 2014;25:879–93. |
|
|
|
27.
Al-Kattan R, Retzepi M, Calciolari E, Donos N. Microarray gene expression
during early healing of GBR-treated calvarial critical size defects. Clin Oral Impl Res. 2016;00:1-10. |
|
|
|
28. Zhang H, Mao X, Du Z,
Jiang W, Han X, Zhao D, et al. Three dimensional printed macroporouspolylactic
acid/hydroxyapatite composite scaffolds for promoting bone formation in a
critical-size rat calvarial defect model. SciTechnolAdv
Mater.2016;17:136-48. |
|
|
|
29. de Santana WM, de
Sousa DN, Ferreira VM, Duarte WR. Simvastatin and biphasic calcium phosphate affects
bone formation in critical-sized rat calvarial defects. Acta Cir Bras. 2016;31:300-7. |
|
|
|
30.
Mukherjee DP, Tunkle AS, Roberts RA, Clavenna A, Rogers S, Smith D. An Animal
Evaluation of a Paste of Chitosan Glutamate and Hydroxyapatite as a Synthetic
Bone Graft Material Biomater. 2003;67:603-9. |
|
|
|
31.
Lohmann P, Willuweit A, Neffe AT, Geisler S, Gebauer TP, Beer S, et al. Bone
regeneration induced by a 3D architectured hydrogel in a rat critical-size
calvarial defect. Biomaterials.
2017;113:158-69. |
|
|
|
32.
Townsend JM, Dennis SC, Whitlow J, Feng Y, Wang J, Andrews B, et al.
Colloidal Gels with Extracellular Matrix Particles and Growth Factors for Bone
Regeneration in Critical Size Rat Calvarial Defects. AAPS J. 2017;19:703-11. |
|
|
|
33.
Pryor ME, Polimeni G, Koo KT, Hartman MJ, Gross H, April M, et al. Analysis
of rat calvaria defects implanted with a platelet-rich plasma preparation:
histologic and histometric observations. J
ClinPeriodontol.2005;32:966-72. |
|
|
|
34.
Park JW, Bae SR, Suh JY, Lee DH, Kim SH, Kim H, et al. Evaluation of bone healing
with eggshell-derived bone graft substitutes in rat calvaria: a pilot study.
J Biomed Mater Res A. 2008;87:203-14. |
|
|
|
35.
Lee JS, Baek SD, Venkatesan J, Bhatnagar I, Chang HK, Kim HT, et al. In vivo
study of chitosan-natural nano hydroxyapatite scaffolds. Int J
BiolMacromol.2014;67:360-6. |
|
|
|
36. Johari B,
Ahmadzadehzarajabad M, Azami M, Kazemi M, Soleimani M, Kargozar S, et al. Repair of rat critical
size calvarial defect using osteoblast-like and umbilical vein endothelial
cells seeded in gelatin/hydroxyapatite scaffolds. J Biomed Mater Res.
2016;104:1770-8. |
|
|
|
37.
Otsuki B, Takemoto M, Fujibayashi S, Neo M, Kokubo T, Nakamura T. Porethroat
size and connectivity determine bone and tissue ingrowth into porousimplants:
three-dimensional micro-CT based structural analyses of
porousbioactivetitanium implants. Biomaterials.
2006;27:5892-900. |
|
|
|
38.
Bobyn JD, Pilliar RM, Cameron HU, Weatherly GC. The optimum pore sizefor the
fixation of porous-surfaced metal implants by the ingrowth of bone. ClinOrthopRelat Res. 1980;150:263-70. |
|
|
|
39.
Cook SD, Walsh KA, Haddad RJ.Jr. Interface mechanics and bone growthinto porous
Co–Cr–Mo alloy implants, ClinOrthopRelat Res. 1985;193:271-80. |
|
|
|
40.
Whang K, Healy KE, Elenz DR, Nam EK, Tsai DC, Thomas CH, et al. Engineering
bone regeneration withbioabsorbable scaffolds with novel microarchitecture.
Tissue Eng. 1999;5:35-51. |
|
|
|
41.
Liao F, Chen Y, Li Z, Wang Y, Shi B, Gong Z, et al. A novel
bioactivethree-dimensional b-tricalcium phosphate/chitosan scaffold for
periodontaltissue engineering. J Mater Sci: Mater Med. 2010;21:489-96. |
|
|