치과에서 나노기술의 미래

Eur J Dent. 2013 Jan; 7(1): 145–151.

PMCID: PMC3571524

Nanotechnology and dentistry

Sule Tugba Ozak¹ and Pelin Ozkan¹

¹Department of Prosthodontics, Faculty of Dentistry, Ankara University, Ankara, TURKIYE

Corresponding author: Dr. Sule Tugba Ozak, Ankara Universitesi, Dishekimligi Fakutesi, Protetik Dis Tedavisi Anabilim Dali, Besevler, 06500, Ankara, TURKIYE, Tel: +90 535 6464783, Fax: +90 312 2123954, Email: moc.oohay@abgutelus

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Copyright 2013 European Journal of Dentistry. All rights reserved.

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Abstract

Nanotechnology deals with the physical, chemical, and biological properties of structures and their components at nanoscale dimensions. Nanotechnology is based on the concept of creating functional structures by controlling atoms and molecules on a one-by-one basis. The use of this technology will allow many developments in the health sciences as well as in materials science, bio-technology, electronic and computer technology, aviation, and space exploration. With developments in materials science and biotechnology, nanotechnology is especially anticipated to provide advances in dentistry and innovations in oral health-related diagnostic and therapeutic methods.

Keywords: Nanotechnology, dentistry, nanodentistry, nanocomposite

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INTRODUCTION

Science is presently undergoing a great evolution, taking humanity to a new era: the era of nanotechnology.¹ The opportunity to witness the beginning of a pioneering development in technology is encountered rarely.

The application of nanotechnology to dentistry and the time that will be required to implement the results of research into practice are the first questions that arise regarding nanotechnology in dentistry.²

The word “nano,” which is derived from the Greek word (nannos) meaning “dwarf,” is a prefix that literally refers to 1 billionth of a physical size.¹ one nanometer (nm) is a unit of length that equals 1 billionth of a meter.³ Given that a single hair strand has a thickness of 100,000 nm, it becomes easier to visualize what is meant by “nano” and to understand its significance.⁴ The size of atoms is approximately 0.1 nm. Considering that the size of a usable nanostructure is 1 to 100 nm, it is clearly seen that the area of nanotechnology works at the level of atoms and molecules.³

According to the definition of the National Nanotechnology Initiative, nanotechnology is the direct manipulation of materials at the nanoscale.⁵ This term defines a technology that enables almost complete control of the structure of matter at nanoscale dimensions. Nanotechnology will give us the ability to arrange atoms as we desire and subsequently to achieve effective, complete control of the structure of matter.^6,7

The aims of nanotechnology are to enable the analysis of structures at the nanoscale, to understand the physical properties of structures at the nanoscale dimension, to manufacture nanoscale structures, to develop devices with nano-precision, and to establish a link between nanoscopic and macroscopic universes by inventing adequate methods.⁸

Nanotechnology is based on the idea of creating functional structures by controlling atoms and molecules on a one-by-one basis.¹ What makes nano-particles interesting and bestows unique features upon them is the fact that their size is smaller than the critical lengths defining many physical events.⁹ In general, nanotechnology is translated as “the science of the small.”¹⁰ However, in addition to creating small structures, nano-technology involves inventing materials, devices, and systems with physical, chemical, and biologic properties that differ from those of large-scale structures.⁵

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DEVELOPMENTAL PROCESS OF NANOTECHNOLOGY

Nano-phase materials were first discussed academically in 1959 at the annual meeting of the American Physical Society. At this meeting, Nobel Prize winning physicist Richard P. Feynman (1918–1988) gave a speech titled “There is plenty of room at the bottom.” In this speech, Feynman said that manufacturing at the dimension of atoms and molecules would result in many new inventions; in addition, he stated that particular methods for measurement and manufacturing at the nanoscale should first be developed to realize such a possibility.⁹ Feynman’s famous speech is accepted as the beginning of nanoscience and nanotechnology.¹¹ Since then, both experimental and theoretical developments have been proceeding rapidly.

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NANOMEDICINE

Advances in the medical implementations of nanotechnology have resulted in the formation of a new field called nanomedicine.¹¹ This concept was first put forward in 1993 by Robert A. Freitas Jr. and was defined as observing, controlling, and treating the biological systems of the human body at the molecular level using nano-structures and nano-devices.¹²

Nanomedicine includes various applications ranging from drug release with nanospheres to tissue scaffolds based on nanotechnologic design that realize tissue formation, and even nanorobots for diagnostic and therapeutic purposes.¹³ Drug molecules transported through the body by the circulatory system may cause undesirable adverse effects in untargeted regions. on the other hand, nanorobots can recognize unhealthy cells and can find and destroy them wherever they are located. Drug delivery to the exact target is of particular importance in cancer in order to destroy all of the cancer cells and at the same time avoid harming healthy cells.¹⁴

Nanomedicine can overcome many important medical problems with basic nanodevices and nanomaterials, some of which can be manufactured today. The results of many studies performed today in the field of nanomedicine are very close to transformation into practice; therefore, it can be said that these successful developments are inevitable. Nanomedicine provides improvements in available techniques in addition to developing fully new techniques.^13,15

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NANOTECHNOLOGY IN DENTISTRY

Similar to nanomedicine, the development of nanodentistry will allow nearly perfect oral health by the use of nanomaterials and biotechnologies, including tissue engineering and nanorobots.¹¹

Tissue engineering and dentistry

Potential applications of tissue engineering and stem cell research in dentistry include the treatment of orofacial fractures, bone augmentation, cartilage regeneration of the temporomandibular joint, pulp repair, periodontal ligament regeneration, and implant osseointegration. Tissue engineering enables the placement of implants that eliminate a prolonged recovery period, are biologically and physiologically more stable than previously used implants, and can safely support early loading.^16,17

Studies related to the regeneration of bone tissue constitute a major part of the studies in the tissue-engineering field. Nanoscale fibers are similar in shape to the arrangement between collagen fibrils and hydroxyapatite crystals in bone. The biodegradable polymers or ceramic materials that are often preferred in bone tissue engineering may not have sufficient mechanical endurance despite their osteoconductive and biocompatible properties despite their osteoconductive and biocompatible properties. Studies performed in recent years indicate that nanoparticles can be used to enhance the mechanical properties of these materials. The main reason for preferring nanoparticles is that the range of dimension of these structures is the same as that of cellular and molecular components.^4,18 Bone replacement materials developed via nano-technology are commercially available.^{1,19, 20}

Bone grafts with better characteristics can be developed with the use of nanocrystalline hydroxyapatite. Furthermore, it was shown that nanocrystalline hydroxyapatite stimulated the cell proliferation required for periodontal tissue regeneration.²¹

Bio-nano surface technology and dental implants

The natural bone surface has a roughness of approximately 100 nm, and such nano details are therefore important on the surfaces of implants. Osteoblast proliferation has been induced through the creation of nano-size particles on the implant surface.^4,22 Roughing the implant surface at the nanoscale level is important for the cellular response that occurs in the tissue.^23,24

Titanium implants treated with a nanostructured calcium surface coat were inserted into rabbit tibias, and their effect on osteogenesis was investigated; the nanostructured calcium coat increased the responsiveness of the bone around the implant.²⁵ Many in-vitro studies have shown that the nanotopography of the implant surface considerably affects osteogenic cells and that the nanoscale surface morphology enhances osteoblast adhesion. Moreover, the nanoscale surface morphology augments the surface area and thus provides an increased implant surface area that can react to the biologic environment.^25–28

Dental nanorobots

Although medical robots are not anticipated to have an effect on dentistry in the near future, it is not too early to consider their potential effects.² Dental nanorobots are able to move through teeth and surrounding tissues by using specific movement mechanisms. Nanocomputers that have been previously programmed via acoustic signals used for ultrasonography can control nanorobotic functions.¹¹

Nanorobots (dentifrobots) left by mouthwash or toothpaste on the occlusal surfaces of teeth can clean organic residues by moving throughout the supragingival and subgingival surfaces, continuously preventing the accumulation of calculus. These nanorobots, which can move as fast as 1 to 10 micron/second, are safely deactivated when they are swallowed.¹

Nanocomposites

The increasing interest in esthetic restorations in recent years has led to further development of materials that have the same color as that of teeth.²⁹ The latest advance in composite resins is the implementation of nanoparticle technology into restorative materials.^16,30 Nanotechnology has enabled the production of nano-dimensional filler particles,³¹ which are added either singly or as nanoclusters into composite resins. Nanofillers are different from traditional fillers.^32,33 When the filler for traditional composites is produced, large particles are minified by pinning; however, these methods cannot reduce the size of a filler that is smaller than 100 nm.^{31, 33} Nanotechnology allows the production of nano-sized filler particles that are compatible with dental composites; therefore, a greater amount of filler can be added into the composite resin matrix.³¹

Nanoparticles allow the production of composites with a smooth surface after the polishing process and confer superior esthetic features to the material. Composite resins containing such particles are easy to shape and have a high degree of strength and resistance to abrasion. Therefore, the area of use of resins containing nanoparticles is wider than that of composites containing hybrid and microfill fillers.^{29, 34}

In contrast to hybrid composites in which large particles can be separated from the matrix, only poorly attached nanoclusters are separated during abrasion in nanocomposites; thus, a well-polished restoration surface can retain its smoothness for a long time.²⁹ The particles that are separated from the surface of the nanocomposites and form defects on the surface during abrasion are nano in size, which is smaller than the wavelength of light.³³ Since particles in the wavelength of visible light (0.4 to 0.8 μm) do not reflect light, the material has superior optic character.²⁹ The fillers in nano-composites have higher translucence since they are smaller than the wavelength of light, allowing the generation of more esthetic restorations with a vast range of color options.³³

Bacteria cause plaque accumulation and subsequent periodontal disease by adhering to the rough surfaces of restorations.³⁵ Several reports have indicated that significantly smoother surfaces were achieved using composites with nanofiller compared to other composites; This is because nanocomposites have much smaller sizes and contain much higher amounts of filler.^31,35

Nanofiller technology has enabled the production of nanofill composites by bringing together the esthetic features of microfill composites and the mechanical features of hybrid composites.^29,33,36 In-vitro studies have shown that these composites had advantageous physical, mechanical, and esthetic features. Considering these features, the nanocomposite may be a concrete example of an ideal composite.^{31,33,35,37–39} However, before nanofill and nanohybrid composites take their anticipated places in routine practice, their successful in-vitro performance should be confirmed by clinical studies.^10,29,32,40 Although existing clinical studies have demonstrated that use of nanocomposites is successful after 1- and 2-year follow-up, this should be confirmed by long-term clinical studies.

Nanocomposite artificial teeth

Artificial teeth made of nanocomposite have also been produced. In these artificial teeth, inorganic fillers in nano-dimensions are diffused homogenously without any accumulation in the matrix. Therefore, the smoothness of the surface can be preserved even when the teeth are eroded. Tests have shown that nanocomposite artificial teeth are more durable than acrylic teeth and microfill composite teeth and have a higher resistance to abrasion.^41–44 Moreover, composite resin artificial teeth containing nanofiller show superior color.⁴⁵

Dental tissues and nanostructures

Although enamel, cement, and bone are formed by the organized accumulation of apatite crystals with carbon dioxide, enamel tissue has distinct characteristics because it does not contain collagen and remodeling is not possible. During enamel biomineralization, spontaneous self-assembly of the amelogenin protein in nano-spheres plays an important role in controlling the growth of apatite crystals with carbon dioxide. This process can be implemented for forming other mineralized tissues such as bone and cement, in which nano-structures were similarly used.⁵

Nanomaterials for periodontal drug delivery

Researchers have attempted to generate an effective and satisfactory drug delivery system for the treatment of periodontal diseases by producing nanoparticles impregnated with triclosan. It was concluded that the application of triclosan particles into the test area alleviated inflammation.⁵ Although this study investigated only periodontal therapy, it indicated that targeted drug delivery with nanomaterials is possible for other treatments. The best example of the future use of this technology is a procedure called Arestin^®, in which microspheres containing tetracycline are placed into periodontal pockets and tetracycline is administered locally.⁵

An in-vitro study performed with a toothpaste containing nanosized carbonate apatite showed that dentin tubules were effectively sealed, which is important for sustained treatment of dentin sensitivity.⁴⁶

Nanotechnology for preventing dental caries

The use of a toothpaste containing nanosized calcium carbonate enabled remineralization of early enamel lesions.⁴⁷ Furthermore, a study that investigated the bacteriostatic effects of silver, zinc oxide, and gold nanoparticles on Streptococcus mutans, which causes dental caries, reported that compared to the other nanoparticles, silver nanoparticles had an antimicrobial effect in lower concentrations and with lower toxicity.⁴⁸

Digital dental imaging

Advances in digital dental imaging techniques are also expected with nanotechnology. In digital radiographies obtained by nanophosphor scintillators, the radiation dose is diminished and high-quality images are obtained.⁴⁹

Applications of nanotechnology in oral and maxillofacial surgery

Selective cell manipulation and surgery performed with tools sized at the molecular level will provide great benefits, particularly in tumor tissue surgery.⁵⁰

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FUTURE FIELDS OF APPLICATION OF NANOTECHNOLOGY IN DENTISTRY

In nanodentistry, millions of active analgesic nanoparticles in a colloidal suspension are placed into the patient’s gingiva, and the anesthesia effectiveness is controlled by the dentist via nanorobots moving into the gingival sulcus. Nanorobotic analgesics are an excellent modality to provide comfort to the patient and alleviate anxiety. Many of the adverse effects and complications associated with the use of typical local analgesic solutions are absent.

Nanodental techniques for major dental repair have been advanced by technologic developments such as genetic engineering, tissue engineering, and tissue regeneration. At some time in the future, it will be possible to form a new tooth in-vitro. Preparing an autologous tooth that has both mineral and cellular dental components will be made possible by advances in research, and this process will eventually be achievable in the dentist’s office.

Nanotechnology will offer perfect therapeutic methods for esthetic dentistry. All teeth that undergo treatment such as fillings or crowns will be restored with natural biologic materials in a manner that is indistinguishable from natural dentition.

Dentin sensitivity is another pathology that is suitable for nanodental treatment. Many therapeutic agents provide only a temporary effect for this common, painful condition. However, dental nanorobots can seal specific tubules by using natural biomaterials within a few minutes and provide a quick and permanent recovery from this condition.

Orthodontic nanorobots can directly manipulate all of the periodontal tissues, including gingival, periodontal ligament, cement, and alveolar bone. They can correct, rotate, or vertically reposition the teeth within a few hours in a pain-free manner.

The durability and appearance of teeth can be improved by inserting artificial materials such as sapphire or diamond into the outer layers of the enamel with covalent bonds. Although pure sapphires and diamonds are fragile, their ultimate strength can be augmented by the addition of materials such as carbon nanotubes. Sapphire can be produced in almost all colors from the color scale. This feature provides a cosmetic alternative to standard whitening techniques.

The once-a-day application of a mouthwash or toothpaste that delivers nanorobotic structures will result in the metabolism of organic compounds into harmless and odorless structures and the continuous cleaning of calculus. These dentifrobots, which are nearly invisible (1 to 10 μm), will have the mobility of an amoeba with a velocity of 1–10 μm/second. Their production is inexpensive, and they are fully mechanic devices. Furthermore, their activity can be stopped harmlessly in case they are swallowed. Distinctively manufactured dentifrobots recognize and destroy pathogenic bacteria in plaque and other regions, but they do not affect approximately 500 harmless species in normal flora and thus contribute to the formation of a healthy ecosystem. Dentifrobots constitute a continuous barrier to halitosis by eliminating bacterial putrefaction products, a major cause of oral malodor. Thus, tooth loss and gingival diseases will be eliminated by providing these daily dental practices from a young age.¹¹

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CONCLUSION

Although the effect of nanotechnology on dentistry is limited to the use of currently available materials, rapidly progressing investigations will ensure that developments that seem unbelievable today are possible in the future. The future utilization of the advantages of nanotechnology will facilitate improvements in oral health. Advanced restorative materials, new diagnostic and therapeutic techniques, and pharmacologic approaches will improve dental care.

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REFERENCES

1. Saravana KR, Vijayalakshmi R. Nanotechnology in dentistry. Ind J Dent Res. 2006;17:62–65. [PubMed]

2. Schleyer TL. Nanodentistry: Fact or fiction? J Am Dent Assoc. 2000;131:1567–1568. [PubMed]

3. Erkoç Ş. Nanobilim ve Nanoteknoloji. 1. Baskı, Ankara: ODTÜ Yayıncılık; 2007. pp. 1–10.

4. Gumusderelioglu M, Mavis B, Karakecli A, Kahraman AS, Cakmak S, Tigli S, Demirtas TT, Aday S. Doku mühendisliğinde nanoteknoloji. Bilim ve Teknik. 2007;479 Ek.

5. Kong LX, Peng Z, Li SD, Bartold M. Nanotechnology and its role in the management of periodontal diseases. Periodontol 2000. 2006;40:184–196. [PubMed]

6. Mansoori GA. Advances in atomic and molecular nanotechnology. Principles of Nanotechnology. 1st ed. Singapore: World Scientific Publishing Co. Ptc. Ltd; 2005. pp. 1–10.

7. Rieth M. Nano-Engineering – Studies and Conclusions Nano-Engineering in science and technology. 1st ed. Singapore: World Scientific Publishing Co. Ptc. Ltd; 2003. pp. 91–103.

8. Ozbay E. İşe yarar nanoteknoloji. Seminer, Bilkent Üniv. Nanoteknoloji Araştırma Merkezi; Ankara, Turkey: 2006.

9. Poole PC, Jr, Owens FJ. Introduction to Nanotechnology. New Jersey: John Wiley & Sons Inc; 2003. pp. 1–7.

10. Duke ES. Has dentistry moved into the nanotechnology era? Compend Contin Educ Dent. 2003;24:380–382. [PubMed]

11. Freitas RA., JR Nanodentistry. J Am Dent Assoc. 2000;131:1559–1565. [PubMed]

12. Freitas RA., JR . Nanomedicine: Basic Capabilities. Vol. 1. Landes Biosciences; Retrieved online January 3, 2008 from: www.nanomedicine.com.

13. Freitas RA., JR What is nanomedicine? Nanomedicine. 2005;1:2–9. [PubMed]

14. Freitas RA., JR Nanotechnology, nanomedicine and nano-surgery. Int J Surg. 2005;3:243–246. [PubMed]

15. Caruthers SD, Wickline SA, Lanza GM. Nanotechnological applications in medicine. Current Opin Biotechnol. 2007;18:26–30. [PubMed]

16. Stephen CB. Dental Biomaterials: Where Are We and Where Are We Going? J Dent Educ. 2005;69:571–578. [PubMed]

17. Roberson MT, Heymann OH, Swift EJ., JR . Biomaterials Sturdevant’s Art and Science of Operative Dentistry. 5th ed. Mosby Co; 2006. pp. 137–139.

18. Ashammakhi N, Ndreu A, Yang Y, Ylikauppila H, Nikkola L, Hasırcı V. Tissue engineering: A new take-off using nanofiber-based scaffolds. J Craniofac Surg. 2007;18:3–17. [PubMed]

19. Strietzel FP, Reichart PA, Graf HL. Lateral alveolar ridge augmentation using a synthetic nano-crystalline hydroxiapatite bone substitution material (Ostim®) Clin Oral Impl Res. 2007;18:743–751. [PubMed]

20. Wagner V, Dullart A, Bock AK, Zweck A. The emerging nanomedicine landscape. Nature Biotechnology. 2006;24:2–9. Retrieved online February 2, 2008 from: www.nature.com/nbt/ [PubMed]

21. Kasaj A, Willershausen B, Reichert C, Röhrig B, Smeets R, Schmidt M. Ability of nanocrystalline hydroxyapatite paste to promote human periodontal ligament cell proliferation. J Oral Sci. 2008;50:279–285. [PubMed]

22. Tetè S, Mastrangelo F, Traini T, Vinci R, Sammartino G, Marenzi G, Gherlone E. A macro- and nanostructure evaluation of a novel dental implant. Implant Dent. 2008;17:309–320. [PubMed]

23. Braceras I, De Maeztu MA, Alava JI, Gay-Escoda C. In vivo low-density bone apposition on different implant surface materials. Int J Oral Maxillofac Surg. 2009;38:274–278. [PubMed]

24. Ellingsen JE, Thomsen P, Lyngstadaas P. Advances in dental implant materials and tissue regeneration. Periodontol 2000. 2006;41:136–156. [PubMed]

25. Suh JY, Jeung OC, Choi BJ, Park JW. Effects of a novel calcium titanate coating on the osseointegration of blasted endosseous implants in rabbit tibiae. Clin Oral Impl Res. 2007;18:362–369. [PubMed]

26. Meirelles L, Currie F, Jacobsson M, Albrektsson T, Wennerberg A. The effect of chemical and nanotopographical modifications on the early stages of osseointegration. Int J Oral Maxillofac Impl. 2008;23:641–647. [PubMed]

27. Chiang CY, Chiou SH, Yang WE, Hsu ML, Yung MC, Tsai ML, Chen LK, Huang HH. Formation of TiO(2) nano-network on titanium surface increases the human cell growth. Dent Mater. 2009;25:1022–1029. [PubMed]

28. Park JW, Kim HK, Kim YJ, An CH, Hanawa T. Enhanced osteoconductivity of micro-structured titanium implants (XiVE S CELLplus) by addition of surface calcium chemistry: a histomorphometric study in the rabbit femur. Clin Oral Implants Res. 2009;20:684–690. [PubMed]

29. Türkün LŞ, Uzer Çelik E. Antibakteriyal adeziv ile uygulanan kompomer ve nanofil kompozit restorasyonların bir yıllık klinik performansı Gazi Üniv Diş Hek Fak Derg. 2007;24:1–8.

30. Papadogiannis DY, Lakes RS, Papadogiannis Y, Palaghias G, Helvatjoglu-Antoinades M. The effect of temperature on viscoelastic properties of nano-hybrid composites. Dent Mater. 2008;24:257–266. [PubMed]

31. Jung M, Sehr K, Klimek J. Surface texture of four nano-filled and one hybrid composite after finishing. Oper Dent. 2007;32:45–52. [PubMed]

32. Ernst CP, Brandenbusch M, Meyer G, Canbek K, Gottschalk F, Willershausen B. Two- year clinical performance of a nanofiller vs a fine-particle hybrid resin composite. Clin Oral Invest. 2006;10:119–125. [PubMed]

33. Mitra SB, Wu D, Holmes BN. An application of nanotechnology in advanced dental materials. J Am Dent Assoc. 2003;134:1382–1390. [PubMed]

34. Yesil ZD, Alapatı S, Johnston W, Seghi RR. Evaluation of the wear resistance of new nanocomposite resin restorative materials. J Prosthet Dent. 2008;99:435–443. [PubMed]

35. Joniot S, Salomon JP, Dejou J, Grégoire G. Use of two surface analyzers to evaluate the surface roughness of four esthetic restorative materials after polishing. Oper Dent. 2006;31:39–46. [PubMed]

36. Davis N. A nanotechnology composite. Compend Contin Educ Dent. 2003;24:662–670. [PubMed]

37. Curtis AR, Palin WM, Fleming GJP, Shortall ACC, Marquis PM. The mechanical properties of nanofilled resin-based composites: The impact of dry and wet cyclic pre-loading on bi-axial flexure strength. Dent Mater. 2009;25:188–197. [PubMed]

38. Pinnavaia TJ, Beall GW. Polymer-Clay Nanocomposites. West Sussex, England: John Wiley & Sons Ltd; 2000. pp. 1–8.

39. Watanabe H, Khera SC, Vargas MA, Qian F. Fracture toughness comparison of six resin composites. Dent Mater. 2008;24:418–425. [PubMed]

40. Schirrmeister JF, Huber K, Hellwig E, Hahn P. Two-year evaluation of a new nano-ceramic restorative material. Clin Oral Invest. 2006;10:181–186. [PubMed]

41. Suzuki S. In vitro wear of nano-composite denture teeth. J Prosthodont. 2004;13:238–243. [PubMed]

42. Ghazal M, Hedderich J, Kern M. Wear of fekdspathic ceramic, nanofilled composite resin and acrylic resin artificial teeth when opposed to different antogonists. Eur J Oral Sci. 2008;116:585–592. [PubMed]

43. Ghazal M, Albashaireh ZS, Kern M. Wear resistance of nanofilled composite and feldspathic ceramic artificial teeth. J Prosthet Dent. 2008;100:441–448. [PubMed]

44. Loyaga-Rendon PG, Takahashi H, Hayakawa I, Iwasaki N. Compositional characteristics and hardness of acrylic and composite resin artificial teeth. J Prosthet Dent. 2007;98:141–149. [PubMed]

45. Imamura S, Takahashi H, Hayakawa I, Loyaga-Rendon PG, Minakuchi S. Effect of filler type and polishing on the discoloration of composite resin artificial teeth. Dent Mater J. 2008;27:802–808. [PubMed]

46. Lee SY, Kwon HK, Kim BI. Effect of dentinal tubule occlusion by dentifrice containing nano-carbonate apatite. J Oral Rehabil. 2008;35:847–853. [PubMed]

47. Nakashima S, Yoshie M, Sano H, Bahar A. Effect of a test dentifrice containing nano-sized calcium carbonate on remineralization of enamel lesions in vitro. J Oral Sci. 2009;51:69–77. [PubMed]

48. Hernández-Sierra JF, Ruiz F, Pena DC, Martínez-Gutiérrez F, Martínez AE, Guillén Ade J, Tapia-Pérez H, Castañón GM. The antimicrobial sensitivity of Streptococcus mutans to nanoparticles of silver, zinc oxide, and gold. Nanomedicine. 2008;4:237–240. [PubMed]

49. Mupparapu M. New nanophosphor scintillators for solid-state digital dental imagers. Dentomaxillofac Radiol. 2006;35:475–476. [PubMed]

50. Troulis MJ, Ward BB, Zuniga JA. Emerging Technologies: Findings of the 2005 AAOMS Research Summit. J Oral Maxillofac Surg. 2005;63:1436–1442. [PubMed]

Ann Med Health Sci Res. 2014 Sep-Oct; 4(Suppl 3): S171–S177.

doi:  10.4103/2141-9248.141951

PMCID: PMC4212373

Nanotechnology and its Application in Dentistry

IMF Abiodun-Solanke, DM Ajayi, and AO Arigbede¹

Department of Restorative Dentistry, College of Medicine, University of Ibadan, Nigeria

¹Department of Restorative Dentistry, College of Health Sciences, University of Port-Harcourt, Nigeria

Address for correspondence: Dr. Iyabo M. Funmilayo Abiodun-Solanke, Department of Restorative Dentistry, College of Medicine, University of Ibadan, Nigeria. E-mail: ac.oohay@fmilosiba

Author information ► Copyright and License information ►

Copyright : © Annals of Medical and Health Sciences Research

This is an open-access article distributed under the terms of the Creative Commons Attribution-Noncommercial-Share Alike 3.0 Unported, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Abstract

Nanotechnology influences almost every facet of everyday life from security to medicine. The concept of nanotechnology is that when one goes down to the bottom of things, one can discover unlimited possibilities and potential of the basic particle. In nanotechnology, analysis can be made to the level of manipulating atoms, molecules and chemical bonds between them. The growing interest in the dental applications of nanotechnology is leading to the emergence of a new field called nanodentistry. An electronic database search that included PubMed, MedLine, and Cochrane library was conducted. Key words used in the search are nanotechnology dentistry and applications. Language limitation was set as articles reviewed were only those written and published in English language. We did not search the gray literature. Initially, 52 articles were retrieved from the database, and articles considered were those published from 2008 to 2013. Eight articles that met the selection criteria were eventually selected and reviewed.

Keywords: Application, Biotechnology, Dentistry, Nano

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Introduction

Definition

Nanotechnology or nanoscience refers to research and development of an applied science at the atomic or molecular level (i.e. molecular engineering, manufacturing).[1] The word “nano” is said to be derived from the Greek word which stands for “dwarf”.[2] Nanoscale though small in size has vast potential.[1] one nanometer is 1 billionth or 10⁻⁹ of a meter.[3] The comparative size of a nanometer to a meter is the same as the size of a marble to the size of the earth. The other way of putting it is that a nanometer is the amount a man's beard grows in the time it takes him to raise a razor to his face.[4,5]

History

The American Physicist Richard Feynman through his lecture titled “there is plenty room at the bottom” delivered at Caltech in 1959 was touted as the one who provided the inspiration for the field of nanotechnology, but it was the Japanese scientist Norio Taniguchi of the Tokyo University of Science who first employed the term “nano-technology” in 1974.[6] However, the term “nanotechnology” as against “nano-technology” was coined by Prof. Kevie E. Drexler in his 1986 book titled Engines of Creation: The Coming Era of Nanotechnology.[7]

Concept and production of nanostructures

The basic idea of nanotechnology is to employ individual atoms and molecules to construct functional structures.[8] Nanotechnology can be applied to various medical fields like Pharmacological research, clinical diagnosis, supplementing immune system, cryogenic storage of biological tissues, detection of proteins, probing of DNA structure, tissue engineering, tumor destruction via heating (hyperthermia) separation and purification of biological molecules and cells, magnetic resonance imaging (MRI) contrast enhancement, etc. Nanotechnology influences almost every facet of everyday life from security to medicine. The concept of nanotechnology is that when one goes down to the bottom of things, one can discover unlimited possibilities and potential of the basic particle. In nanotechnology, analysis can be made to the level of manipulating atoms, molecules and chemical bonds between them. The various nanoparticles include nanopores, nanotubes, quantum dots, nanoshells, nanospheres, nanowires, nanocapsules, dendrimers, nanorods, liposomes and so on.[9,10] More recently, tiny machines called nanoassemblers that could be controlled by computer to perform specialized jobs have been invented. These nanoassemblers could be smaller than a cell nucleus so that they fit into places that are hard to reach by hand or with any other technology. It can be used to destroy bacteria in the mouth that cause dental caries or even repair spots on the teeth where decay has set in by the use of computers to direct these tiny workers in their tasks.[11,12,13]

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Method of Literature Search

To identify publications, we conducted an electronic database search. The search included PubMed, MedLine and Cochrane library. Key words used in the search are nanotechnology, dentistry and applications. Language limitation was set, as articles reviewed were only those written and published in English language. We did not search the gray literature. Initially 52 articles were retrieved from the database, and articles considered were those published from 2008 to 2013.

Study design

The articles included were mainly literature reviews that considered the broad application of nano particles in all aspects of dentistry, and not just a particular specialty. We did not consider case reports, case control studies, clinical trials, editorials or opinion letters.

Eight articles that met the selection criteria were eventually selected and reviewed.

Types of nanotechnologies

Basically, nanotechnologies consist of three mutually overlapping and progressively more powerful molecular technologies:

1. Nanoscale structured materials and devices that can be fabricated for advanced diagnosis and biosensors, targeted drug delivery and smart drugs
2. Molecular medicine via genomics, proteomics, artificial biobotics (microbial robots)
3. Molecular machine systems and medical nanorobots allow instant pathogen diagnosis and extermination and efficient augmentation and improvement of natural physiological function.

Applications of nanotechnology

Nanotechnology has wide industrial and clinical applications in:[14]

1. Medicine:
   • -Diagnostics
   • -Drug delivery
   • -Tissue engineering.
2. Chemistry and environment:
   • -Catalysis
   • -Filtration.
3. Energy:
   • Reduction of energy consumption
   • Increasing the efficiency of energy production
   • The use of more environmentally friendly energy systems
   • Recycling of batteries.
4. Information and communication:
   • Novel semi-conductor devices
   • Novel optoelectronic devices
   • Displays
   • Quantum computers.
5. Heavy industry:
   • Aerospace
   • Refineries
   • Vehicle manufactures
   • Consumer goods
   • Foods.

Nanomedicine

Advances in biomaterials and biotechnology have resulted in the formation of a new field called nanomedicine,[15] which was first put forward in 1993 by Robert A. Freitas Jr. Nanomedicine is the science of preventing, diagnosing and treating disease using nanosized particles.[14,16,17]

Nanomedicine includes various applications ranging from drug release with nanospheres to tissue scaffolds based on nanotechnologic design that realize tissue formation, and even nanorobots for diagnostics and therapeutic purposes.[18] Drug molecules transported through the body by the circulatory system may cause undesirable adverse effects in untargeted regions. Nanorobots on the others hand can recognize unhealthy cells and can find and destroy them wherever they are located.

Drug delivery to the exact target is of particular importance in cancer in order to destroy all of the cancer cells and at the same time avoid harming healthy cells.[19] Nanomedicine can overcome many important medical problems with basic nanodevices and nanomaterials, some of which can be manufactured today. Nanomedicine provides improvements in available techniques in addition to developing fully new techniques.[18,20]

Nanotechnology in dentistry

Because of the growing interest in the future of dental application of nanotechnology, a new field called nanodentistry is emerging. The development of nanodentistry will allow nearly perfect oral health by the use of nanomaterials and biotechnologies including tissue engineering and nanorobots.[15]

The new treatment opportunities in dentistry include local anesthesia, dentition renaturalization, permanent cure of hypersensitivity, complete orthodontic realignment during a single office visit, covalently bonded diamondized enamel and continuous oral health maintenance with the help of mechanical dentifrobots (nanorobotic dentifrice) that destroy caries-causing bacteria and even repair blemishes on the teeth where decay has set in.[21]

Application of nanotechnology in diagnosis and treatment

Nanodiagnostics

Nanodiagnostic devices can be used for early disease identification at the cellular and molecular levels. Nanomedicine could increase the efficiency and reliability of in vitro diagnostics, through the use of selective nanodevices to collect human fluids or tissues samples and to make multiple analyses at the subcellular level. Nanodevices can be inserted into the body to identify the early presence of a disease or to identify and quantify toxic molecules and tumor cells.[15,22]

Diagnosis and treatment of oral cancer

Exosome is a membrane bound secretory vesicle containing a proteomic and genomic marker whose level is elevated in malignancy. This marker has been studied by using atomic force microscopy which employs nanoparticles. The nanoelectromechanical system, oral fluid nanosensor test, and optical nanobiosensor can also be used for diagnosing oral cancer. Nanoshells which are miniscale beads are specific tools in cancer therapeutics. Nanoshells have outer metallic layers that selectively destroy cancer cells while leaving normal cells intact. Undergoing trial are nanoparticle-coated, radioactive sources placed close to or within the tumor to destroy it.[23]

Tissue engineering and dentistry

Potential applications of tissue engineering and stem cell research in dentistry include the treatment of orofacial fractures, bone augmentation, cartilage regeneration of the temporomandibular joint, pulp repair, periodontal ligament regeneration and implant osseointegration. Tissue engineering enables the placement of implants that eliminate a prolonged recovery period, that are biologically and physiologically more stable than previously used implants, and that can safely support early loading.[24,25]

Bone grafts with better characteristics can be developed with the use of nanocrystalline hydroxyapatite. It was shown that nanocrystalline hydroxyapatite stimulated the cell proliferation required for periodontal tissue regeneration.[26]

Bio-nano surface technology and dental implants

Osteoblast proliferation has been induced through the creation of nano-size particles on the implant surface.[25,27] Roughening the implant surface at the nanoscale level is important for the cellular response that occur in the tissue.[28,29] Many studies have shown that nanotopography of the implant surface considerably affects osteogenic cells and that the nanoscale surface morphology enhances osteoblast adhesion. The nanoscale surface morphology augments area and thus provides an increased implant surface area that can react with the biologic environment.[30,31]

Bone replacement materials

Nanotechnology aims to emulate the natural structure present on bone, which is composed of organic compounds (mainly collagen) and reinforced with inorganic ones. Nanocrystals show a loose microstructure, with nanopores situated between the crystals. The surfaces of the pores are modified such that they adsorbed protein, due to the addition of silica molecules. Bone defects can be treated using the hydroxyapatite nanoparticles.[32]

Nanoanesthesia

Application of nanotechnology can be used to induce anesthesia. The gingiva of the patients is instilled with a colloidal suspension containing millions of active, analgesic, micron-sized dental robots that respond to input supplied by the dentist. After contacting the surface of crown or mucosa, the ambulating nanorobots reach the pulp via the gingiva sulcus, lamina propia and dentinal tubules, guided by chemical gradient, temperature differentials controlled by the dentist. once in the pulp, they shut down all sensation by establishing control over nerve-impulse traffic in any tooth that requires treatment. After completion of treatment, they restore sensation thereby providing patient with anxiety-free and needless comfort. Anesthesia is fast acting, and reversible, with no side effects or complications associated with its use.[15,32]

Nanosolutions

They provide unique and dispersible nanoparticle, which can be used in bonding agents (trade name: Adper, Single Bond Plus, Adhesive Single Bond). A new flowable composite (Dentiflow) has an acceptable shear bond strength for bonding orthodontic brackets and can be used without liquid to reduce the bonding procedure time while maintaining an acceptable bond strength.[33,34] Ceram-X Mono™; a nanocomposite was reported to have a lesser bond strength compared with traditional orthodontic composite but was within clinically acceptable range for bonding.[35]

Nanoparticles have also been used as sterilizing solution in the form of nanosized emulsified oil droplets that bombard pathogens.[32,36]

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Impression Materials

Nanofillers are integrated into vinypolysiloxanes, producing a unique siloxane impression material that has a better flow, improved hydrophilic properties and enhanced precision detail.[3,32]

Nanoneedles

Suture needles incorporating nano-sized stainless steel crystals have been developed (trade name: Sandrik Bioline, RK91 needles, AB Sandrik Sweden). Nano tweezers are also under development, which will make cell surgery possible in the near future.[32]

Nanorobotic dentrifices (dentifrobots)

Dentifrobots in the form of mouthwash or toothpaste left on the occlusal surface of teeth can clean organic residues by moving throughout the supragingival and subgingival surfaces, metabolizing trapped organic matter into harmless and odorless vapors and performing continuous calculus debridement. These nanorobots can move as fast as 1-10 μ/s and are safely self-deactivated when they are swallowed.[32]

Hypersensitivity cure

Hypersensitivity may be caused by changes in the pressure transmitted hydrodynamically to the pulp. The dentinal tubules of a hypersensitive tooth have twice the diameter and eight times the surface density of those in nonsensitive teeth. Dental nanorobots could selectively and precisely occlude selected tubules in minutes using native logical materials, offering patients a quick and permanent cure.[32]

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Orthodontic Treatment

Use of excessive orthodontic force might cause loss of anchorage and root resorption. Katz et al.[37] in their study have reported a reduction in the frictional force produced by orthodontic movement by coating the orthodontic wire with inorganic fullerene-like tungsten disulfide nanoparticles (IF-WS₂) known for their excellent dry lubrication properties. Cao et al.[38] in a study reported that brackets coated with the nitrogen-doped titanium oxide thin film showed high antimicrobial and bacterial adhesive properties against normal oral pathogenic bacteria through visible light, which is effective in prevention of enamel demineralization and gingivitis in orthodontic patients. Considering the effect of surface treatment on bond strength, a high bond strength between stainless steel brackets and artificially aged composite restoration in surfaces of restored teeth treated with diamond bur was reported by some authors.[39] Concerning nanoindentation of orthodontic archwires, application of decontamination regimen and clinical use had no significant effect on the nickel titanium archwires, but did have a statistically significant effect on the steel archwires. Decontamination of the steel wires significantly increased the observed surface hardness and reduced the surface roughness. Clinical use demonstrated a statistically significant increase in the observed elastic modulus and a decrease in surface roughness.[40] Orthodontic nanorobots could directly manipulate the periodontal tissues, allowing rapid and painless tooth straightening, rotating and vertical repositioning as well as rapid tissue repair within minutes to hours.[32,37]

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Nanocomposite

The latest advancement in the manufacturing process of dental composite resins is the utilization of nanoparticle technology.[19,32,41] Nanotechnology has enabled the production of nanodimensional filler particles[42] which are added either singly or as nanoclusters into composite resins. Nanofillers are different from traditional fillers[43,44] in that when the filler for traditional composite is produced, large particles are minified by pining and these methods cannot reduce the size of a filler that is smaller than 100 nm.[42] Nanoparticles allow the production of composites with a smooth surface after the polishing process and confer superior esthetic features to the material. Composite resins with such particles are easy to shape and have a high degree of strength and resistance to abrasion. Therefore, resins containing nanoparticle are used in wider areas than composites with hybrid and microfilled fillers.[45] It has been observed that no relevant difference in terms of enamel lesions and cracks occurred after debracketing of orthodontic brackets bonded with flowable orthodontic composite compared with traditional orthodontic composite.[46]

Unlike in hybrid composite where large particles can be separated from the matrix, only poorly attached nanoclusters are separated during abrasion in nanocomposites, and thus retention is enhanced with well-polished surface.[45] The fillers in nanocomposites have higher transluscence since they are smaller than the wavelength of light, thereby allowing the generation of more esthetic restorations with a vast range of color options.[44] Nanofiller technology has enabled the production of nanofill composites by bringing together the esthetic features of microfill composites and the mechanical features of hybrid composites.[44,47]

Nanocomposites artificial teeth

Inorganic fillers in nanodimensions are diffused homogenously without any accumulation in the matrix in the artificial teeth produced from nanocomposites. Studies have shown that nanocomposite artificial teeth are more durable than acrylic teeth and microfill composite teeth and have a higher resistance to abrasion.[48,49,50,51]

Nanoencapsulation

Targeted release systems that encompass nanocapsules including novel vaccines, antibiotics and drug delivery with reduced side effects have been developed by the South West Research Institute.[3] An example is an attempt to generate effective and satisfactory drug delivery system for the treatment of periodontal diseases by producing nanocapsules impregnated with triclosan. Application of triclosan into the test area alleviated inflammation.[52]

Nanotechnology for preventing dental caries

The use of a toothpaste containing nanosized calcium carbonate enabled remineralization of early enamel lesions.[53]

Digital dental imaging

Advances in digital dental imaging techniques are also expected with nanotechnology. The radiation dose obtained using digital radiography with nanophosphor scintillators is diminished and high quality images obtained.[54]

Major tooth repair/nanotissue engineering

Replacement of the whole tooth, including the cellular and mineral components, is called complete dentition replacement. This is made possible through a combination of nanotechnology, genetic engineering and tissue engineering.[23]

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Surface Disinfectants

Nanotechnology was deployed to the production of a surface disinfectant called Eco-True which was reported to have 100% destructive effect on HIV and germs. Clinical applications of the disinfectant include sterilization of instruments and incisions for the purpose of preventing post-operative infections.[55] EnviroSystems of San Jose employed nanotechnology to produce strong but environmentally friendly chemicals.[56]

Stem cells imaging/tracking

For the evaluation of therapeutic efficacy of transplanted stem cells, it is important to track their survival, migration, fate and regenerative impact in vivo. Stem cells can be tracked in vivo after transplantation using different labeling techniques. Initial labeling can be with fluorescent dyes or magnetic nanoparticles such as superparamagnetic iron oxide. Visualization of the labeled cells could be done using imaging systems e.g. MRI.[57,58]

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Hazards of Nanoparticles

The nonpyrogenic nanorobots used in vivo are bulk Teflon, carbon powder and monocrystal sapphire. Pyrogenic nanorobots are alumina, silica and trace elements like copper and zinc. Nanorobots may release inhibitors, antagonists or down regulators for the pathway in a targeted fashion to selectively absorb the endogenous pyrogens, chemically modify them, then release them back into the body in a harmless inactivated form.[32]

The extensive application of nanomaterials in a wide range of products for human use possesses a potential risk for toxicity risk to human health and environment. American health association concluded that short-term exposure to elevated particulate matter concentrations in outdoor air significantly contributes to increased acute cardiovascular mortality, particularly in at risk subset of the population.[1] An in vitro cytotoxicity assessment of an orthodontic composite containing titanium dioxide (Ti0₂) nanoparticles by Heravi and others revealed that orthodontic adhesive containing Ti0₂ nanoparticles indicated comparable or even lower toxicity than its nanoparticle free counterpart. It was concluded that incorporation of 1% by weight of Ti0₂ nanoparticles to the composite structure does not result in additional health hazards compared to that occurring with pure adhesive.[59] In another study,[60] it was reported that leached components from composite material induced embryotoxicity in mouse blastocyst in vitro, while no toxicity was observed when subcutaneously implanted in vivo.

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Future of Nanotechnology

Nanotechnology is foreseen to change health care in a fundamental way. It forms the basis of novel methods for disease diagnosis and prevention. It will be useful in therapeutic selection tailored to the patients profile and will come in handy in drug delivery and gene therapy.

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Conclusion

Nanotechnology is set to revolutionize clinical dental practice. In no distant future, oral health care services will become less stressful for the dental surgeons, more acceptable to patients and the outcome will significantly become more favorable. Rapidly progressing investigations will ensure that developments that seem unbelievable today are possible in the future. Optimal utilization of the advantages and opportunities offered by nanotechnology in clinical dental practice will facilitate improvements in oral health. However, as with all technologies, nanotechnology carries a significant potential for misuse and abuse on a scale and scope never seen before if not properly controlled and directed.

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Footnotes

Source of Support: Nil.

Conflict of Interest: None declared.

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References

1. Kovvuru SK, Mahita VN, Manjun BS, Babu BS. Nanotechnology: The emerging science in dentistry. J Orofac Res. 2012;2:33–6.

2. Verma SK, Prabhat KC, Goyal L, Rani M, Jain A. A critical review of the implication of nanotechnology in modern dental practice. Natl J Maxillofac Surg. 2010;1:41–4. [PMC free article] [PubMed]

3. Kanaparthy R, Kanaparthy A. The changing face of dentistry: Nanotechnology. Int J Nanomedicine. 2011;6:2799–804. [PMC free article] [PubMed]

4. Taniguchi N. on the basic concept of nanotechnology. Proceeding of the International Conferences on Production Engineering. 1974

5. Schleyer TL. Nanodentistry. Fact or fiction? J Am Dent Assoc. 2000;131:1567–8. [PubMed]

6. A brief history of nanotechnology. [Last accessed on 2014 Jan 15]. Available from: http://www.charpan.com/a-brief .

7. Feynman R. There's plenty room at the bottom. In: Gilbert HD, editor. Miniaturization. New York: Reinhold; 1961. pp. 282–96.

8. Sanjna N, Bhuminathan S, Muthuvignesh J. Upsurge of nanotechnology in dentistry and dental implants. Int J Multidiscip Dent. 2011;1:264–8.

9. Freitas RA., Jr . Georgetown, TX: Landes Bioscience; 1999. Nanomedicine: Basic Capabilities; pp. 345–50.

10. Iijima S, Brabec C, Maito A. Structural flexibility of carbon nanotubes. J Chem Physiol. 1996;104:2089–92.

11. Drexler KE, Perterson C, Pergamita G. New York: William Morrow, Quill Books; 1991. Unbundling the Future: The Nanotechnology Revolution; p. 225.

12. Drexler KE. New Era of Nanotechnology. New York: Anchor Press; 1986. Engines of Creation: The Coming Era of Nanotechnology; p. 229.

13. Merkle RC. Advances in Anti-ageing Medicine. Vol. 1. Larchmont, New York Mary Ann Liebert: 1996. Nanotechnology and Nanomedicine; pp. 277–86.

14. European Science Foundation (ESF) Nanomedicine: Forward look on nanomedicine. [Last accessed on 2011 Oct 05]. Available from: http://www.esf.org/publicatiions/forward looks.html .

15. Freitas RA., Jr Nanodentistry. J Am Dent Assoc. 2000;131:1559–65. [PubMed]

16. Kubik T, Bogunia-Kubik K, Sugisaka M. Nanotechnology on duty in medical applications. Curr Pharm Biotechnol. 2005;6:17–33. [PubMed]

17. Drexler PE, Peterson C. New York: William Morrow/onill Books; 1991. Unbounding the Future: The Nanotechnolgy Revolution.

18. Freitas RA., Jr What is nanomedicine? Nanomedicine. 2005;1:2–9. [PubMed]

19. Freitas RA., Jr Nanotechnology, nanomedicine and nanosurgery. Int J Surg. 2005;3:243–6. [PubMed]

20. Caruthers SD, Wickline SA, Lanza GM. Nanotechnological applications in medicine. Curr Opin Biotechnol. 2007;18:26–30. [PubMed]

21. Rybachuk AV, Chema IS, Nebesna TY. Nanotechnology and nanoparticles in dentistry. J Pharmacol Pharm. 2008;1:18–20.

22. Lampton C. Nanotechnology promises to revolutionize the diagnosis and treatment of diseases. Genet Eng News. 1995;15:23–5.

23. Shetty NJ, Swati P, David K. Nanorobots: Future in dentistry. Saudi Dent J. 2013;25:49–52. [PMC free article] [PubMed]

24. Bayne SC. Dental biomaterials: Where are we and where are we going? J Dent Educ. 2005;69:571–85. [PubMed]

25. Roberson MT, Heymann OH, Swift FR. 5th ed. France Mosby Co; 2006. Biomaterials. Sturdevant's Arts and Science of Operative Dentistry; pp. 137–9.

26. Kasaj A, Willershausen B, Reichert C, Röhrig B, Smeets R, Schmidt M. Ability of nanocrystalline hydroxyapatite paste to promote human periodontal ligament cell proliferation. J Oral Sci. 2008;50:279–85. [PubMed]

27. Tetè S, Mastrangelo F, Traini T, Vinci R, Sammartino G, Marenzi G, et al. A macro- and nanostructure evaluation of a novel dental implant. Implant Dent. 2008;17:309–20. [PubMed]

28. Braceras I, De Maeztu MA, Alava JI, Gay-Escoda C. In vivo low-density bone apposition on different implant surface materials. Int J Oral Maxillofac Surg. 2009;38:274–8. [PubMed]

29. Ellingsen JE, Thomsen P, Lyngstadaas SP. Advances in dental implant materials and tissue regeneration. Periodontol 2000. 2006;41:136–56. [PubMed]

30. Meirelles L, Currie F, Jacobsson M, Albrektsson T, Wennerberg A. The effect of chemical and nanotopographical modifications on the early stages of osseointegration. Int J Oral Maxillofac Implants. 2008;23:641–7. [PubMed]

31. Park JW, Kim HK, Kim YJ, An CH, Hanawa T. Enhanced osteoconductivity of micro-structured titanium implants (XiVE S CELLplus) by addition of surface calcium chemistry: A histomorphometric study in the rabbit femur. Clin Oral Implants Res. 2009;20:684–90. [PubMed]

32. Saravana KR, Vijayalakshmi R. Nanotechnology in dentistry. Indian J Dent Res. 2006;17:62–5. [PubMed]

33. D’Attilio M, Traini T, Di Iorio D, Varvara G, Festa F, Tecco S. Shear bond strength, bond failure, and scanning electron microscopy analysis of a new flowable composite for orthodontic use. Angle Orthod. 2005;75:410–5. [PubMed]

34. Tecco S, Traini T, Caputi S, Festa F, de Luca V, D’Attilio M. A new one-step dental flowable composite for orthodontic use: An in vitro bond strength study. Angle Orthod. 2005;75:672–7. [PubMed]

35. Nagar N, Vaz AC. Comparison of shear bond strengths of conventional orthodontic composite and nano-ceramic restorative composite: An in vitro study. Indian J Dent Res. 2013;24:713–8. [PubMed]

36. Nagpal AR, Kaur J, Sharma S, Bansal A, Sacher P. Nanotechnology – The era of molecular dentistry. Indian J Dent Sci. 2011;3:80–2.

37. Redlich M, Katz A, Rapoport L, Wagner HD, Feldman Y, Tenne R. Improved orthodontic stainless steel wires coated with inorganic fullerene-like nanoparticles of WS(2) impregnated in electroless nickel-phosphorous film. Dent Mater. 2008;24:1640–6. [PubMed]

38. Cao B, Wang Y, Li N, Liu B, Zhang Y. Preparation of an orthodontic bracket coated with an nitrogen-doped TiO (2-x) N (y) thin film and examination of its antimicrobial performance. Dent Mater J. 2013;32:311–6. [PubMed]

39. Eslamian L, Borzabadi-Farahani A, Mousavi N, Ghasemi A. The effects of various surface treatments on the shear bond strengths of stainless steel brackets to artificially-aged composite restorations. Aust Orthod J. 2011;27:28–32. [PubMed]

40. Alcock JP, Barbour ME, Sandy JR, Ireland AJ. Nanoindentation of orthodontic archwires: The effect of decontamination and clinical use on hardness, elastic modulus and surface roughness. Dent Mater. 2009;25:1039–43. [PubMed]

41. Papadogiannis DY, Lakes RS, Papadogiannis Y, Palaghias G, Helvatjoglu-Antoniades M. The effect of temperature on the viscoelastic properties of nano-hybrid composites. Dent Mater. 2008;24:257–66. [PubMed]

42. Jung M, Sehr K, Klimek J. Surface texture of four nanofilled and one hybrid composite after finishing. Oper Dent. 2007;32:45–52. [PubMed]

43. Ernst CP, Brandenbusch M, Meyer G, Canbek K, Gottschalk F, Willershausen B. Two-year clinical performance of a nanofiller vs a fine-particle hybrid resin composite. Clin Oral Investig. 2006;10:119–25. [PubMed]

44. Mitra SB, Wu D, Holmes BN. An application of nanotechnology in advanced dental materials. J Am Dent Assoc. 2003;134:1382–90. [PubMed]

45. Yesil ZD, Alapati S, Johnston W, Seghi RR. Evaluation of the wear resistance of new nanocomposite resin restorative materials. J Prosthet Dent. 2008;99:435–43. [PubMed]

46. Tecco S, Tetè S, D’Attilio M, Festa F. Enamel surface after debracketing of orthodontic brackets bonded with flowable orthodontic composite. A comparison with a traditional orthodontic composite resin. Minerva Stomatol. 2008;57:81–94. [PubMed]

47. Davis N. A nanotechnology composite. (669-70).Compend Contin Educ Dent. 2003;24:662, 665–7. [PubMed]

48. Suzuki S. In vitro wear of nano-composite denture teeth. J Prosthodont. 2004;13:238–43. [PubMed]

49. Ghazal M, Hedderich J, Kern M. Wear of feldspathic ceramic, nano-filled composite resin and acrylic resin artificial teeth when opposed to different antagonists. Eur J Oral Sci. 2008;116:585–92. [PubMed]

50. Ghazal M, Albashaireh ZS, Kern M. Wear resistance of nanofilled composite resin and feldspathic ceramic artificial teeth. J Prosthet Dent. 2008;100:441–8. [PubMed]

51. Loyaga-Rendon PG, Takahashi H, Hayakawa I, Iwasaki N. Compositional characteristics and hardness of acrylic and composite resin artificial teeth. J Prosthet Dent. 2007;98:141–9. [PubMed]

52. Kong LX, Peng Z, Li SD, Bartold PM. Nanotechnology and its role in the management of periodontal diseases. Periodontol 2000. 2006;40:184–96. [PubMed]

53. Nakashima S, Yoshie M, Sano H, Bahar A. Effect of a test dentifrice containing nano-sized calcium carbonate on remineralization of enamel lesions in vitro. J Oral Sci. 2009;51:69–77. [PubMed]

54. Mupparapu M. New nanophosphor scintillators for solid-state digital dental imagers. Dentomaxillofac Radiol. 2006;35:475–6. [PubMed]

55. Satyanarayana TS, Rathika R. Nanothechnology: The future. J Interdiscip Med. 2011;1:93–100.

56. Nanotechnology Used to Create Environmentally Friendly Disinfectant – New Product. [Last accessed on 2014 Jan 15]. Available from: http://www.azonano.com/article.aspx .

57. Gopal KS, Lankupalli AM. Stem cells therapy: A new hope for dentist. J Clin Diagn Res. 2012;6:142–4.

58. Ma Px. Biomimetic materials for tissue engineering. Adv Drug Deliv Rev. 2008;60:184–98. [PMC free article] [PubMed]

59. Heravi F, Ramezani M, Poosti M, Hosseini M, Shajiei A, Ahrari F. In vitro cytotoxicity assessment of an orthodontic composite containing titanium-dioxide nano-particles. J Dent Res Dent Clin Dent Prospects. 2013;7:192–8. [PMC free article] [PubMed]

60. Libonati A, Marzo G, Klinger FG, Farini D, Gallusi G, Tecco S, et al. Embryotoxicity assays for leached components from dental restorative materials. Reprod Biol Endocrinol. 2011;9:136. [PMC free article] [PubMed]

• Abstract
• INTRODUCTION
• DEVELOPMENTAL PROCESS OF NANOTECHNOLOGY
• NANOMEDICINE
• NANOTECHNOLOGY IN DENTISTRY
• FUTURE FIELDS OF APPLICATION OF NANOTECHNOLOGY IN DENTISTRY
• CONCLUSION
• REFERENCES

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Articles from European Journal of Dentistry are provided here courtesy of Dental Investigations Society

나노 메디칼 하이드록시아파타이트, nano <mHAP> 트리트먼트 페이스트

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