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[1]Moore, L.K., M. Gatica, E.K. Chow, and D. Ho: Diamond-Based Nanomedicine: Enhanced Drug Delivery and Imaging. Disruptive Sc Techn 1(1), 54-61 (2012)
[2]Gismondi, A., G. Reina, S. Orlanducci, F. Mizzoni, S. Gay, M.L. Terranova, and A. Canini: Nanodiamonds coupled with plant bioactive metabolites: A nanotech approach for cancer therapy. Biomater 38, 22–35 (2015)
[3]Wang, M., and M. Thanou: Targeting nanoparticles to cancer. Pharmacol Res 62, 90–99 (2010)
[4]Li, C: A targeted approach to cancer imaging and therapy. Nat Mater 13(2), 110–115 (2014)
[5]Getts, D.R., R.L. Terry, M.T. Getts, C. Deffrasnes, M. Müller, C. van Vreden, T.M. Ashhurst, B. Chami, D. McCarthy, H. Wu, J. Ma, A. Martin, L.D. Shae, P. Witting, G.S. Kansas, J. Kühn, W. Hafezi, I.L. Campbell, D. Reilly, J. Say, L. Brown, M.Y. White, S.J. Cordwell, S.J. Chadban, E.B. Thorp, S. Bao, S.D. Miller, and N.J. King: Therapeutic inflammatory monocyte modulation using immune-modifying microparticles. Sci Transl Med 6(219), 219ra7 (2014)
[6]Gupta, A.S.: Nanomedicine approaches in vascular disease: a review. Nanomedicine 7, 763–779 (2011)
[7]Mura, S. and P. Couvreur: Nanotheranostics for personalized medicine. Adv Drug Deliv Rev 64, 1394–1416 (2012)
[8]Kaur, R., and I. Badea: Nanodiamonds as novel nanomaterials for biomedical applications: drug delivery and imaging systems. Int J Nanomedicine 8, 203–220 (2013)
[9]Puzyr, A.P., A.V. Baron, K.V. Purtov, E.V. Bortnikov, N.H. Skobelev, O.A. Mogilnaya, and V. S. Bondar: Nanodiamonds with novel properties: a biological study. Diamond and Related Materials 16(12), 2124–2128 (2007)
[10]Mochalin, V.N., O. Shenderova, D. Ho, and Y. Gogotsi: The properties and applications of nanodiamonds. Nat Nanotechnol 7, 11–23 (2012)
[11]Ho, D., C.-H.K. Wang, and E.K.-H. Chow: Nanodiamonds: The intersection of nanotechnology, drug development, and personalized medicine. Science Advances 1(7), e1500439 (2015)
[12]Danilenko, V.: On the history of the discovery of nanodiamond synthesis. Phys Solid State;46, 595–599 (2004)
[13]Greiner, N.R., D.S. Phillips, J.D. Johnson, and F. Volk: Diamonds in detonation soot. Nature 333, 440-442 (1988)
[14]Osawa, E.: Single-nano buckydiamond particles: Synthesis strategies, characterization methodologies and emerging applications. In: Ho D, ed. Nanodiamonds: Applications in Biology and Medicine. New York City: Springer, pp. 1–33 (2010)
[15]Guo-Wei, Y., W. Jin-Bin, and L. Qui-Xiang: Preparation of nano-crystalline diamonds using pulsed laser induced reactive quenching. Journal of Physics: Condensed Matter 10(35), 7923 (1998)
[16]Osawaa, E., S. Sasakib, and R. Yamanoia: Ultananocrystalline diamond (2nd ed.) Elsevier, pp. 165–179 (2012)
[17]Vial, S., C. Mansuy, S. Sagan, T. Irinopoulou, F. Burlina, J.P. Boudou, G. Chassaing, and S. Lavielle, Peptide-grafted nanodiamonds: preparation, cytotoxicity and uptake in cells. Chem Bio Chem 9, 2113–2119 (2008)
[18]Terranova, M.L., S. Orlanducci, E. Tamburri, V. Guglielmotti, F. Toschi, D. Hampai, and M. Rossi: Polycrystalline diamond on self-assembled detonation nanodiamond: a viable route for fabrication of all-diamond preformed micro-components. Nanotechnology 19, 415600–415605 (2008)
[19]Orlanducci, S., I. Cianchetta, E. Tamburri, M.L. Terranova, M. Cassani, R. Matassa, and M. Rossi.: Gold nanoparticles on nanodiamond for nanophotonic applications. MRS Proceedings 1452, 13–19 (2012)
[20]Tamburri, E., S. Orlanducci, V. Guglielmotti, M. Rossi, and M.L. Terranova: Engineering detonation nanodiamond-polyaniline nanocomposites by electrochemical routes: structural features and functional characterizations. Polymer 52, 5001–5008 (2011)
[21]Vaijayanthimala, V., and H.C. Chang: Functionalized fluorescent nanodiamonds for biomedical applications. Future Med 4, 47–55 (2009)
[22]Purtov, K.V., A.I. Petunin, A.E. Burov, A.P. Puzyr, and V.S. Bondar: Nanodiamonds as carriers for address delivery of biologically active substances. Nanoscale Res Lett 5, 631–636 (2010)
[23]Alhaddad, A., M.P. Adam, J. Botsoa, G. Dantelle, S. Perruchas, T. Gacoin, C. Mansuy, S. Lavielle, C. Malvy, F. Treussart, and J-R. Bertrand: Nanodiamond as a vector for siRNA delivery to Ewing sarcoma cells. Small 7, 3087–3095 (2011)
[24]Zhu, Y., J. Li, W. Li, Y. Zhang, X. Yang, N. Chen, Y. Sun, Y. Zhao, C. Fan, and Q. Huang.: The biocompatibility of nanodiamonds and their application in drug delivery systems. Theranostics 2(3), 302–312 (2012)
[25]Liu, K.K., C.L. Cheng, C.C. Chang, and J.I. Chao.: Biocompatible and detectable carboxylated nanodiamond on human cell. Nanotechnol 18, 325102 (2007)
[26]Horie, M., K.L. Komaba, H. Kato, A. Nakamura, K.Yamamoto, S. Endoh, K. Fujita, S. Kinugasa, K. Mizuno, Y. Hagihara, Y. Yoshida, and H. Iwahashi.: Evaluation of cellular influences induced by stable nanodiamond dispers: the cellular influences of nanodiamond are small. Diam Relat Mat 24, 15–24 (2012)
[27]Faklaris, O., V. Joshi, T. Irinopoulou, P. Tauc, M. Sennour, H. Girard, C. Gesset, J.-C. Arnault, A. Thorel, J.-P. Boudou, P.A. Curmi, and F. Treussart: Photo-luminescent diamond nanoparticles for cell labeling: study of the uptake mechanism in mammalian cells. ACS Nano 3(12), 3955–3962 (2009)
[28]Martín, R., M. Alvaro, J.R. Herance, and H. García: Fenton-treated functionalized diamond nanoparticles as gene delivery system. ACS Nano 4, 65–74 (2010)
[29]Fang, C.Y., V. Vaijayanthimala, C.A. Cheng, S.H. Yeh, C.F. Chang, C.L. Li, and H-C. Chang: The exocytosis of fluorescent nanodiamond and its use as a long-term cell tracker. Small 7 (23):3363–3370 (2011)
[30]Schrand, A.M., J.B. Lin, S.C. Hens, an S.M. Hussain: Temporal and mechanistic tracking of cellular uptake dynamics with novel surface fluorophore-bound nanodiamonds. Nanoscale 3, 435–445 (2011)
[31]Rej, E., T. Gaebel, T. Boele, D. Waddington, and D. Reilly: Hyperpolarized nanodiamond with long spin-relaxation times. Nat Commun 6, Article number 8459 (2015)
[32]Wang, X., X.C. Low, W. Hou, L.N. Abdullah, T.B. Toh, M. Mohd Abdul Rashid, D. Ho, and E.K. Chow: Epirubicin-Adsorbed Nanodiamonds Kill Chemoresistant Hepatic Cancer Stem Cells. ACS Nano 8 (12), 12151–12166 (2014)
[33]Poland, C.A., R. Duffin, I. Kinloch, A. Maynard, W.A. Wallace, A. Seaton, V. Stone, S. Brown, W. Macnee, and K. Donaldson: Carbon nanotubes introduced into the abdominal cavity of mice show asbestos-like pathogenicity in a pilot study. Nat Nanotechnol 3(7), 423–428 (2008)
[34]Chow, E.K., X.-Q. Zhang, M. Chen, R. Lam, E. Robinson, H. Huang, D. Schaffer, E. Osawa, A. Goga, and D. Ho: Nanodiamond Therapeutic Delivery Agents Mediate Enhanced Chemo-resistant Tumor Treatment. Sci Transl Med 3, 73ra21 (2011)
[35]Zhang, Q., V.N. Mochalin, I. Neitzel, I.Y. Knoke, J. Han, C.A. Klug, J.G. Zhou, P.I. Lelkes, and Y. Gogotsi. Fluorescent PLLA-nanodiamond composites for bone tissue engineering. Biomaterials 32(1):87–94 (2011)
[36]Yuan, Y., X. Wang, G. Jia, J.-H. Liu, T. Wang, Y. Gu, S.-T. Yang, S. Zhen, H. Wang, and Y. Liu: Pulmonary toxicity and translocation of nanodiamonds in mice. Diam Relat Mater 19, 291–299 (2010)
[37]Mohan, N., C.-S. Chen, H.-H. Hsieh, Y.C. Wu, and H.C. Chang:In vivo Imaging and toxicity assessments of fluorescent nanodiamonds in Caenorhabditis elegans. Nano Lett 10(9), 3692–3699 (2010)
[38]Xi, G., E. Robinson, B. Mania-Farnell, E.F. Vanin, K.-W. Shim, T. Takao, E.V. Allender, C.S. Mayanil, M.B. Soares, D. Ho, and T. Tomita: Convection-enhanced delivery of nanodiamond drug delivery platforms for intracranial tumor treatment. Nanomedicine: Nanotechnol Biol Med 10(2), 381–391 (2014)
[39]Lam, R., M. Chen, E. Pierstorff, H. Huang, E. Osawa, and D. Ho: Nanodiamond-Embedded Microfilm Devices for Localized Chemotherapeutic Elution. ACS Nano 2 (10), 2095–2102 (2008)
[40]Boudou, J.P., P.A. Curmi, F. Jelezko, J. Wrachtrup, P. Aubert, M. Sennour, G. Balasubramanian, R. Reuter, A. Thorel, and E. Gaffet: High yield fabrication of fluorescent nanodiamonds. Nanotechnol 20(23), 235602 (2009)
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Frontiers in Bioscience-Scholar (FBS) is published by IMR Press from Volume 13 Issue 1 (2021). Previous articles were published by another publisher on a subscription basis, and they are hosted by IMR Press on imrpress.com as a courtesy and upon agreement with Frontiers in Bioscience.
, Dhan Prakash 1, Sneh Gupta 21 Amity Institute for Herbal Research and Studies, Amity University UP, Sector-125, Noida-201313, India
2 Department of Zoology, R.G.P.G. College, Chippi Tank, Meerut-250001, India
*Author to whom correspondence should be addressed.
Abstract
Diamond nano-particles find new and far-reaching applications in modern biomedical science and biotechnologies. Due to its excellent biocompatibility, nano-diamonds serve as versatile platforms that can be embedded within polymer-based microfilm devices. Nano-diamonds are complexed with a chemotherapeutic that enables sustained/slow release of the drug for a minimum of one month, with a significant amount of drug in reserve. This opens up the potential for highly localized drug release as a complementary and potent form of treatment with systemic injection towards the reduction of continuous dosing, and as such, attenuation of the often powerful side effects of chemotherapy. Nano-diamonds are quite economical, enabling the broad impact of these devices towards a spectrum of physiological disorders e.g. serving as a local chemotherapeutic patch, or as a pericardial device to suppress inflammation after open heart surgery. Nano-diamond patch could be used to treat a localized region where residual cancer cells might remain after a tumor is removed. Nano-diamonds can be used to explore a broad range of therapeutic classes, including additional small molecules, proteins, therapeutic antibodies, RNAi.
Keywords
- Cancer
- Nanodiamonds
- Drug delivery
- Carbon nanoparticles
- Brain tumors
- Breast cancer
- Chemo resistance
- Review
References
- [1] Moore, L.K., M. Gatica, E.K. Chow, and D. Ho: Diamond-Based Nanomedicine: Enhanced Drug Delivery and Imaging. Disruptive Sc Techn 1(1), 54-61 (2012)
- [2] Gismondi, A., G. Reina, S. Orlanducci, F. Mizzoni, S. Gay, M.L. Terranova, and A. Canini: Nanodiamonds coupled with plant bioactive metabolites: A nanotech approach for cancer therapy. Biomater 38, 22–35 (2015)
- [3] Wang, M., and M. Thanou: Targeting nanoparticles to cancer. Pharmacol Res 62, 90–99 (2010)
- [4] Li, C: A targeted approach to cancer imaging and therapy. Nat Mater 13(2), 110–115 (2014)
- [5] Getts, D.R., R.L. Terry, M.T. Getts, C. Deffrasnes, M. Müller, C. van Vreden, T.M. Ashhurst, B. Chami, D. McCarthy, H. Wu, J. Ma, A. Martin, L.D. Shae, P. Witting, G.S. Kansas, J. Kühn, W. Hafezi, I.L. Campbell, D. Reilly, J. Say, L. Brown, M.Y. White, S.J. Cordwell, S.J. Chadban, E.B. Thorp, S. Bao, S.D. Miller, and N.J. King: Therapeutic inflammatory monocyte modulation using immune-modifying microparticles. Sci Transl Med 6(219), 219ra7 (2014)
- [6] Gupta, A.S.: Nanomedicine approaches in vascular disease: a review. Nanomedicine 7, 763–779 (2011)
- [7] Mura, S. and P. Couvreur: Nanotheranostics for personalized medicine. Adv Drug Deliv Rev 64, 1394–1416 (2012)
- [8] Kaur, R., and I. Badea: Nanodiamonds as novel nanomaterials for biomedical applications: drug delivery and imaging systems. Int J Nanomedicine 8, 203–220 (2013)
- [9] Puzyr, A.P., A.V. Baron, K.V. Purtov, E.V. Bortnikov, N.H. Skobelev, O.A. Mogilnaya, and V. S. Bondar: Nanodiamonds with novel properties: a biological study. Diamond and Related Materials 16(12), 2124–2128 (2007)
- [10] Mochalin, V.N., O. Shenderova, D. Ho, and Y. Gogotsi: The properties and applications of nanodiamonds. Nat Nanotechnol 7, 11–23 (2012)
- [11] Ho, D., C.-H.K. Wang, and E.K.-H. Chow: Nanodiamonds: The intersection of nanotechnology, drug development, and personalized medicine. Science Advances 1(7), e1500439 (2015)
- [12] Danilenko, V.: On the history of the discovery of nanodiamond synthesis. Phys Solid State;46, 595–599 (2004)
- [13] Greiner, N.R., D.S. Phillips, J.D. Johnson, and F. Volk: Diamonds in detonation soot. Nature 333, 440-442 (1988)
- [14] Osawa, E.: Single-nano buckydiamond particles: Synthesis strategies, characterization methodologies and emerging applications. In: Ho D, ed. Nanodiamonds: Applications in Biology and Medicine. New York City: Springer, pp. 1–33 (2010)
- [15] Guo-Wei, Y., W. Jin-Bin, and L. Qui-Xiang: Preparation of nano-crystalline diamonds using pulsed laser induced reactive quenching. Journal of Physics: Condensed Matter 10(35), 7923 (1998)
- [16] Osawaa, E., S. Sasakib, and R. Yamanoia: Ultananocrystalline diamond (2nd ed.) Elsevier, pp. 165–179 (2012)
- [17] Vial, S., C. Mansuy, S. Sagan, T. Irinopoulou, F. Burlina, J.P. Boudou, G. Chassaing, and S. Lavielle, Peptide-grafted nanodiamonds: preparation, cytotoxicity and uptake in cells. Chem Bio Chem 9, 2113–2119 (2008)
- [18] Terranova, M.L., S. Orlanducci, E. Tamburri, V. Guglielmotti, F. Toschi, D. Hampai, and M. Rossi: Polycrystalline diamond on self-assembled detonation nanodiamond: a viable route for fabrication of all-diamond preformed micro-components. Nanotechnology 19, 415600–415605 (2008)
- [19] Orlanducci, S., I. Cianchetta, E. Tamburri, M.L. Terranova, M. Cassani, R. Matassa, and M. Rossi.: Gold nanoparticles on nanodiamond for nanophotonic applications. MRS Proceedings 1452, 13–19 (2012)
- [20] Tamburri, E., S. Orlanducci, V. Guglielmotti, M. Rossi, and M.L. Terranova: Engineering detonation nanodiamond-polyaniline nanocomposites by electrochemical routes: structural features and functional characterizations. Polymer 52, 5001–5008 (2011)
- [21] Vaijayanthimala, V., and H.C. Chang: Functionalized fluorescent nanodiamonds for biomedical applications. Future Med 4, 47–55 (2009)
- [22] Purtov, K.V., A.I. Petunin, A.E. Burov, A.P. Puzyr, and V.S. Bondar: Nanodiamonds as carriers for address delivery of biologically active substances. Nanoscale Res Lett 5, 631–636 (2010)
- [23] Alhaddad, A., M.P. Adam, J. Botsoa, G. Dantelle, S. Perruchas, T. Gacoin, C. Mansuy, S. Lavielle, C. Malvy, F. Treussart, and J-R. Bertrand: Nanodiamond as a vector for siRNA delivery to Ewing sarcoma cells. Small 7, 3087–3095 (2011)
- [24] Zhu, Y., J. Li, W. Li, Y. Zhang, X. Yang, N. Chen, Y. Sun, Y. Zhao, C. Fan, and Q. Huang.: The biocompatibility of nanodiamonds and their application in drug delivery systems. Theranostics 2(3), 302–312 (2012)
- [25] Liu, K.K., C.L. Cheng, C.C. Chang, and J.I. Chao.: Biocompatible and detectable carboxylated nanodiamond on human cell. Nanotechnol 18, 325102 (2007)
- [26] Horie, M., K.L. Komaba, H. Kato, A. Nakamura, K.Yamamoto, S. Endoh, K. Fujita, S. Kinugasa, K. Mizuno, Y. Hagihara, Y. Yoshida, and H. Iwahashi.: Evaluation of cellular influences induced by stable nanodiamond dispers: the cellular influences of nanodiamond are small. Diam Relat Mat 24, 15–24 (2012)
- [27] Faklaris, O., V. Joshi, T. Irinopoulou, P. Tauc, M. Sennour, H. Girard, C. Gesset, J.-C. Arnault, A. Thorel, J.-P. Boudou, P.A. Curmi, and F. Treussart: Photo-luminescent diamond nanoparticles for cell labeling: study of the uptake mechanism in mammalian cells. ACS Nano 3(12), 3955–3962 (2009)
- [28] Martín, R., M. Alvaro, J.R. Herance, and H. García: Fenton-treated functionalized diamond nanoparticles as gene delivery system. ACS Nano 4, 65–74 (2010)
- [29] Fang, C.Y., V. Vaijayanthimala, C.A. Cheng, S.H. Yeh, C.F. Chang, C.L. Li, and H-C. Chang: The exocytosis of fluorescent nanodiamond and its use as a long-term cell tracker. Small 7 (23):3363–3370 (2011)
- [30] Schrand, A.M., J.B. Lin, S.C. Hens, an S.M. Hussain: Temporal and mechanistic tracking of cellular uptake dynamics with novel surface fluorophore-bound nanodiamonds. Nanoscale 3, 435–445 (2011)
- [31] Rej, E., T. Gaebel, T. Boele, D. Waddington, and D. Reilly: Hyperpolarized nanodiamond with long spin-relaxation times. Nat Commun 6, Article number 8459 (2015)
- [32] Wang, X., X.C. Low, W. Hou, L.N. Abdullah, T.B. Toh, M. Mohd Abdul Rashid, D. Ho, and E.K. Chow: Epirubicin-Adsorbed Nanodiamonds Kill Chemoresistant Hepatic Cancer Stem Cells. ACS Nano 8 (12), 12151–12166 (2014)
- [33] Poland, C.A., R. Duffin, I. Kinloch, A. Maynard, W.A. Wallace, A. Seaton, V. Stone, S. Brown, W. Macnee, and K. Donaldson: Carbon nanotubes introduced into the abdominal cavity of mice show asbestos-like pathogenicity in a pilot study. Nat Nanotechnol 3(7), 423–428 (2008)
- [34] Chow, E.K., X.-Q. Zhang, M. Chen, R. Lam, E. Robinson, H. Huang, D. Schaffer, E. Osawa, A. Goga, and D. Ho: Nanodiamond Therapeutic Delivery Agents Mediate Enhanced Chemo-resistant Tumor Treatment. Sci Transl Med 3, 73ra21 (2011)
- [35] Zhang, Q., V.N. Mochalin, I. Neitzel, I.Y. Knoke, J. Han, C.A. Klug, J.G. Zhou, P.I. Lelkes, and Y. Gogotsi. Fluorescent PLLA-nanodiamond composites for bone tissue engineering. Biomaterials 32(1):87–94 (2011)
- [36] Yuan, Y., X. Wang, G. Jia, J.-H. Liu, T. Wang, Y. Gu, S.-T. Yang, S. Zhen, H. Wang, and Y. Liu: Pulmonary toxicity and translocation of nanodiamonds in mice. Diam Relat Mater 19, 291–299 (2010)
- [37] Mohan, N., C.-S. Chen, H.-H. Hsieh, Y.C. Wu, and H.C. Chang:In vivo Imaging and toxicity assessments of fluorescent nanodiamonds in Caenorhabditis elegans. Nano Lett 10(9), 3692–3699 (2010)
- [38] Xi, G., E. Robinson, B. Mania-Farnell, E.F. Vanin, K.-W. Shim, T. Takao, E.V. Allender, C.S. Mayanil, M.B. Soares, D. Ho, and T. Tomita: Convection-enhanced delivery of nanodiamond drug delivery platforms for intracranial tumor treatment. Nanomedicine: Nanotechnol Biol Med 10(2), 381–391 (2014)
- [39] Lam, R., M. Chen, E. Pierstorff, H. Huang, E. Osawa, and D. Ho: Nanodiamond-Embedded Microfilm Devices for Localized Chemotherapeutic Elution. ACS Nano 2 (10), 2095–2102 (2008)
- [40] Boudou, J.P., P.A. Curmi, F. Jelezko, J. Wrachtrup, P. Aubert, M. Sennour, G. Balasubramanian, R. Reuter, A. Thorel, and E. Gaffet: High yield fabrication of fluorescent nanodiamonds. Nanotechnol 20(23), 235602 (2009)