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Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi

Yıl 2022, Cilt: 10 Sayı: 4, 1890 - 1909, 25.10.2022
https://doi.org/10.29130/dubited.1079780

Öz

Biyoimplant mühendisliği hasarlı dokuları ve organları onarmak, tamir etmek ya da korumayı amaçlamaktadır. Her yıl çok sayıda insan kaza ya da çeşitli hastalıklardan kaynaklı olan iskelet kusurlarındaki kemikleri onarmak/tamir etmek istemektedir. Bu nedenle üzerinde yeni kemik büyümesinin oluşabileceği iskeleleri oluşturabilmek çok farklı biyomalzeme türleri kullanılmıştır. Hidroksiapatit, apatit wollostonit ve karbon temelli biyomalzemeler bu amaçla kullanılmıştır. Karbon nanomateryal baskılı iskeleler ticari olarak ulaşılabilirlik, mekanik stabilite, biyolojik uyumluluk özelliklerinden dolayı kullanımı oldukça yaygın biyomalzeme grubudur. Karbon esaslı iskeleler osteojenikfarklılaşma, kemik doku yenilenmesi, etkili hücre çoğalması özelliği göstermektedir. Kemik iskeleleri doku mühendisliğinde kemik büyümesi, yenilenmesi, tamiri, kemik dokusu hücrelerinde farklılaşma, adhezyon için temel yapı taşı olarak görülmektedir. Kemik iskeleleri gibi hareket eden çok sayıda karbon nanomateryali mevcuttur. Karbon nanotüpler, grafen ve fulleren kemik iskelesi olarak kullanılabilen karbon esaslı malzemelerin başlıcalarıdır. Grafen ve türevleri dikkat çekici fiziksel, kimyasal ve biyolojik özelliklere sahip 2D karbon esaslı bir malzemedir. Grafen mükemmel elektriksel iletkenliği, biyouyumluluğu, yüzey alanı ve termal özellikleri yüzünden bilim dünyası tarafından ilgi görmektedir. Grafenin tabakaları yüksek mekanik dirence ve yüksek spesifik yüzey alanına sahiptir. Dahası grafenin kök hücre farklılaşmasını ve biyomateryal özelliklerini geliştirdiği literatürde raporlanmıştır. Gerçekleştirilen çalışmada grafenin biyouyumluluk özellikleri, grafenin biyomateryal olarak kullanımına dair son çalışmalar ve karbon temelli maddelerin klinik olarak uygulanabilmesi amacıyla biyogüvenlik tartışmaları incelenmiştir.

Kaynakça

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A New Type Of Graphene Based Bone Scaffold In Tissue Engineering

Yıl 2022, Cilt: 10 Sayı: 4, 1890 - 1909, 25.10.2022
https://doi.org/10.29130/dubited.1079780

Öz

The aim of bioimplant technology is to repair, repair or preserve damaged tissues and organs. Every year, many people want to fix/repair bones in skeletal defects caused by accidents or various diseases. For this reason, many different types of biomaterials have been used to create scaffolds on which new bone growth can take place. Hydroxyapatite, apatite-wollostonite, and carbon-based biomaterials have been used for this purpose. Scaffolds printed with carbon nanomaterials are a widely used group of biomaterials because of their commercial availability, mechanical stability, and biocompatibility.Carbon-based scaffolds demonstrate osteogenic differentiation, bone tissue regeneration, and efficient cell proliferation. Bone scaffolds are considered to be the basic building blocks for bone growth, regeneration, repair, differentiation, and adhesion in bone tissue cells in tissue engineering. Many carbon nanomaterials are available that act as skeletons. Carbon nanotubes, graphene, and fullerene are the main carbon-based materials that can be used as skeletons. Graphene and its derivatives are a 2D carbon-based material with remarkable physical, chemical, and biological properties. Graphene is of interest to the scientific community because of its excellent electrical conductivity, biocompatibility, surface area, and thermal properties. Graphene sheets have high mechanical strength and large specific surface area. In addition, it has been reported in the literature that graphene enhances stem cell differentiation and biomaterial properties. The conducted study examined the biocompatibility properties of graphene, current studies on the use of graphene as a biomaterial, and biosafety discussions for the clinical application of carbon-based materials. 

Kaynakça

  • [1]Y. Liu, L. Shi, L. Su, H.C. van der Mei, P.C. Jutte, Y. Ren, H.J. Busscher, “Nanotechnology-based antimicrobials and delivery systems for biofilm-infection control,” Chem. Soc. Rev., vol.48, no.2, pp. 428–446, 2019.
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  • [3]PA. Gunatillake, R. Adhikari, “Biodegradable synthetic polymers for tissue engineering,” Eur Cell Mater, vol. 20, no.5, pp. 1–16, 2003.
  • [4]V. Rosa, B. Della, BN. Cavalcanti, JE. Nör, “Tissue engineering: from research to dental clinics,” Dent Mater, vol. 28, no.4, pp. 341–8, 2012.
  • [5]KB. Armstrong, LG. Bevan, WF. Cole, “Care and repair of advanced composites,” SAE International; 2005.
  • [6]R.Y. Basha, K.Sampath, M. Doble, “Design of biocomposite materials for bone tissue regeneration,” Mater Sci Eng C Mater Biol Appl, vol. 57, pp.452–63, 2015.
  • [7]A. Khademhosseini, R. Langer, “A decade of progress in tissue engineering,” Nat Protocol,vol. 11, no. 10, pp. 1775–81,2016.
  • [8]S. V. Vlierberghe, P. Dubruel, E. Schacht, “ Biopolymer-based hydrogels as scaffolds for tissue engineering applications: a review,” Biomacromolecules, vol.12, no. 5, pp.1387–408, 2011.
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  • [10]N. Krishnamoorthy, YT. Tseng, P. Gajendrarao, P. Sarathchandra, A. McCormack , I. Carubelli, “A novel strategy to enhance secretion of ECM components by stem cells: relevance to tissue engineering,” Tissue Eng, vol. 24, no. 1-2, pp. 145–56, 2017.
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  • [13]T. Umeyama, H. Imahor, “Photofunctional hybrid nanocarbon materials,” J Phys Chem C, vol. 117, no.7, pp.3195–209, 2012.
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  • [15]S. W. Hong, J. H. Lee, S. H. Kang, E. Y. Hwang, Y. S. Hwang, M. H. Lee, J. C. Park, “Enhanced neural cell adhesion and neurite outgrowth on graphene-based biomimetic substrates,” Biomed Res Int, vol. 212149, no. 16, 2014.
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  • [20]J. Morin, N. Dubey, F. Decroix, E. Luong-Van, AH. Castro Neto, V. Rosa, “Graphene transfer to 3-dimensional surfaces: a vacuum-assisted dry transfer method,” 2D Mater, vol.4, no.2, pp.025060, 2017.
  • [21]A.K. Geim, K.S. Novoselov, “The rise of graphene", Nat. Mater. vol.6, pp.183–191, 2007.
  • [22]L. Brown, R. Hovden, P. Huang, M. Wojcik, D.A. Muller, J. Park, “Twinning and twisting of tri-and bilayer graphene,” Nano Lett., vol. 12, no.3, pp.1609–1615, 2012.
  • [23]C. Gardin, A. Piattelli, B. Zavan, “ Graphene in regenerative medicine: focus on stem cells and neuronal differentiation,” Trends in biotechnology, vol.34, no.6, pp.435-437, 2016.
  • [24]D.Galpaya, “Synthesis, Charactesization and Application of Graphene Oxide-Polymer Nanocomposites ,” Master of Polymer Engineering ,Queensland University of Technology, 2015.
  • [25]E. R. Susan, “Synthesis of graphene platelets,” Durhan Thesis, Department of Chemistry, Durham University, 2015.
  • [26]S. Bae, H. Kim, Y. Lee, X. Xu, J.-S. Park, Y. Zheng, S. Iijima, “Rollto- roll production of 30-inch graphene films for transparent electrodes,” Nature Nanotechnology, vol.5, no.8, pp.574–578, 2010.
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  • [32]F. Menaa, A. Abdelghani, ve B. Menaa, “Graphene nanomaterials as biocompatible and conductive scaffolds for stem cells: impact for tissue engineering and regenerative medicine,” J Tissue Eng Regen Med, vol. 9, no. 12, pp. 1321-1338, 2014. [33]L. Cao, F. Zhang, Q. Wang, X. Wu, “Fabrication of chitosan/graphene oxide polymer nanofiber and its biocompatibility for cartilage tissue engineering,” Materials Science and Engineering: C, vol. 79, pp. 697-701, 2017.
  • [34]K. Hu, D.D. Kulkarni, I. Choi, V.V. Tsukruk, “Graphene-polymer nanocomposites for structural and functional applications,” Progress in Polymer Science, vol. 39, no. 11, pp.1934-1972, 2014.
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  • [36]A. Tonetto, PW. Lago, M. Borba, V. Rosa, “Effects of chrondro-osseous regenerative compound associated with local treatments in the regeneration of bone defects around implants: an in vivo study,” Clin Oral Investig, vol. 20, no.1–8, 2016.
  • [37]H. Porwal, R. Saggar, “Ceramic matrix nanocomposites. In: Beaumont PWR, Zweben CH, editors,” Compr Compos Mater II. Oxford: Elsevier, pp.138–61, 2018.
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Toplam 60 adet kaynakça vardır.

Ayrıntılar

Birincil Dil Türkçe
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Mine Kırkbınar 0000-0001-8703-1421

Erhan İbrahimoğlu 0000-0002-8073-5570

Fatih Çalışkan 0000-0002-9568-7049

Yayımlanma Tarihi 25 Ekim 2022
Yayımlandığı Sayı Yıl 2022 Cilt: 10 Sayı: 4

Kaynak Göster

APA Kırkbınar, M., İbrahimoğlu, E., & Çalışkan, F. (2022). Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi. Duzce University Journal of Science and Technology, 10(4), 1890-1909. https://doi.org/10.29130/dubited.1079780
AMA Kırkbınar M, İbrahimoğlu E, Çalışkan F. Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi. DÜBİTED. Ekim 2022;10(4):1890-1909. doi:10.29130/dubited.1079780
Chicago Kırkbınar, Mine, Erhan İbrahimoğlu, ve Fatih Çalışkan. “Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi”. Duzce University Journal of Science and Technology 10, sy. 4 (Ekim 2022): 1890-1909. https://doi.org/10.29130/dubited.1079780.
EndNote Kırkbınar M, İbrahimoğlu E, Çalışkan F (01 Ekim 2022) Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi. Duzce University Journal of Science and Technology 10 4 1890–1909.
IEEE M. Kırkbınar, E. İbrahimoğlu, ve F. Çalışkan, “Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi”, DÜBİTED, c. 10, sy. 4, ss. 1890–1909, 2022, doi: 10.29130/dubited.1079780.
ISNAD Kırkbınar, Mine vd. “Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi”. Duzce University Journal of Science and Technology 10/4 (Ekim 2022), 1890-1909. https://doi.org/10.29130/dubited.1079780.
JAMA Kırkbınar M, İbrahimoğlu E, Çalışkan F. Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi. DÜBİTED. 2022;10:1890–1909.
MLA Kırkbınar, Mine vd. “Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi”. Duzce University Journal of Science and Technology, c. 10, sy. 4, 2022, ss. 1890-09, doi:10.29130/dubited.1079780.
Vancouver Kırkbınar M, İbrahimoğlu E, Çalışkan F. Doku Mühendisliğinde Yeni Tip Grafen Esaslı Kemik İskelesi. DÜBİTED. 2022;10(4):1890-909.