Targeted Nanomedicines for Cancer Therapy, From Basics to Clinical Trials
DOI:
https://doi.org/10.18433/jpps30583Abstract
Traditional systemic chemotherapy involves the wide distribution of drug molecules in the body, causing toxic side effects in the healthy tissues and limiting the therapeutic dose required at the site of drug action. In order to decrease side effects and increase the drug efficacy, recent research on chemotherapy focuses on drug targeting. Targeted therapy can be achieved by several mechanisms including; 1) using an antibody as a drug that is specific to a disease biomarker, 2) using an antibody (or peptide) as a targeting agent conjugated to the drug molecule, 3) delivering the drug molecules to the target tissue in a nano-carrier with or without the targeting agent attached on its surface. The third approach involves the nanomedicines that can be targeted to diseased tissues by both passive (extravasating at diseased sites due to leaky vasculature) and active (specific interaction of the targeting agent with disease biomarker) targeting mechanisms. In this review we will cover the passively targeted nanomedicines prepared using nano drug carriers. Ideally the carrier particle should be in the right size (1-100nm), stable enough to prevent drug leakage during circulation, and safe not to cause any damage to healthy tissues. Competition for all these properties generated many different types of materials to be used as nanodrug delivery systems. After a brief review of most commonly used drug carriers, we discuss the clinical use of the targeted nanomedicines with regard to their pharmacokinetic and pharmacodynamics properties, and how these properties vary from conventional formulations providing free drugs in the circulation after administration.
Downloads
References
Henderson LA, Shankar LK. Clinical Translation of the National Institutes of Health’s Investments in Nanodrug Products and Devices. The AAPS journal. 2017:1-17.
Boholm M, Arvidsson R. A definition framework for the terms nanomaterial and nanoparticle. NanoEthics. 2016;10(1):25-40.
Ageitos JM, Chuah J-A, Numata K. Design Considerations for Properties of Nanocarriers on Disposition and Efficiency of Drug and Gene Delivery. 2016.
Wagner V, Dullaart A, Bock A-K, Zweck A. The emerging nanomedicine landscape. Nature biotechnology. 2006;24(10):1211-7.
Raj S, Jose S, Sumod U, Sabitha M. Nanotechnology in cosmetics: Opportunities and challenges. Journal of pharmacy & bioallied sciences. 2012;4(3):186.
Iijima M, Nagasaki Y, Okada T, Kato M, Kataoka K. Core-polymerized reactive micelles from heterotelechelic amphiphilic block copolymers. Macromolecules. 1999;32(4):1140-6.
Park JH, Lee S, Kim J-H, Park K, Kim K, Kwon IC. Polymeric nanomedicine for cancer therapy. Progress in Polymer Science. 2008;33(1):113-37.
Önyüksel H, Bahadori F. Tümör Tedavisinde Hedeflendirilmiş Nanotaşıyıcılar. In: Gursoy Z, editor. Farmasötik Nanotaşıyıcılar ve Uygulamaları. Istanbul: Kontrollü Salım Sistemleri Derneği; 2013.
Caban S, Aytekin E, Sahin A, Capan Y. Nanosystems for drug delivery. OA Drug Design & Delivery. 2014;2(1):2.
Akbarzadeh A, Rezaei-Sadabady R, Davaran S, Joo SW, Zarghami N, Hanifehpour Y, et al. Liposome: classification, preparation, and applications. Nanoscale research letters. 2013;8(1):102.
Allen TM, Cullis PR. Liposomal drug delivery systems: from concept to clinical applications. Advanced drug delivery reviews. 2013;65(1):36-48.
Rajera R, Nagpal K, Singh SK, Mishra DN. Niosomes: a controlled and novel drug delivery system. Biological and Pharmaceutical Bulletin. 2011;34(7):945-53.
Bahadori F, Topçu G, Eroğlu MS, Önyüksel H. A new lipid-based nano formulation of vinorelbine. AAPS PharmSciTech. 2014;15(5):1138-48.
Torchilin VP. Micellar nanocarriers: pharmaceutical perspectives. Pharmaceutical research. 2007;24(1):1.
Lim SB, Banerjee A, Önyüksel H. Improvement of drug safety by the use of lipid-based nanocarriers. Journal of controlled release. 2012;163(1):34-45.
Azeem A, Rizwan M, Ahmad FJ, Iqbal Z, Khar RK, Aqil M, et al. Nanoemulsion components screening and selection: a technical note. AAPS PharmSciTech. 2009;10(1):69-76.
Tadros T, Izquierdo P, Esquena J, Solans C. Formation and stability of nano-emulsions. Advances in colloid and interface science. 2004;108:303-18.
He C-X, He Z-G, Gao J-Q. Microemulsions as drug delivery systems to improve the solubility and the bioavailability of poorly water-soluble drugs. Expert opinion on drug delivery. 2010;7(4):445-60.
Pardeike J, Hommoss A, Müller RH. Lipid nanoparticles (SLN, NLC) in cosmetic and pharmaceutical dermal products. International journal of pharmaceutics. 2009;366(1):170-84.
Zhao Y, Huang L. Lipid nanoparticles for gene delivery. Advances in genetics. 2014;88:13.
Abbasi E, Aval SF, Akbarzadeh A, Milani M, Nasrabadi HT, Joo SW, et al. Dendrimers: synthesis, applications, and properties. Nanoscale Research Letters. 2014;9(1):247.
Liechty WB, Kryscio DR, Slaughter BV, Peppas NA. Polymers for drug delivery systems. Annual review of chemical and biomolecular engineering. 2010;1:149-73.
Larson N, Ghandehari H. Polymeric conjugates for drug delivery. Chemistry of Materials. 2012;24(5):840-53.
James HP, John R, Alex A, Anoop K. Smart polymers for the controlled delivery of drugs–a concise overview. Acta Pharmaceutica Sinica B. 2014;4(2):120-7.
Junghanns J-UA, Müller RH. Nanocrystal technology, drug delivery and clinical applications. International journal of nanomedicine. 2008;3(3):295.
Walling MA, Novak JA, Shepard JR. Quantum dots for live cell and in vivo imaging. International journal of molecular sciences. 2009;10(2):441-91.
Montellano A, Da Ros T, Bianco A, Prato M. Fullerene C 60 as a multifunctional system for drug and gene delivery. Nanoscale. 2011;3(10):4035-41.
Hilder TA, Hill JM. Carbon nanotubes as drug delivery nanocapsules. Current Applied Physics. 2008;8(3):258-61.
Smith DM, Simon JK, Baker Jr JR. Applications of nanotechnology for immunology. Nature Reviews Immunology. 2013;13(8):592-605.
Kim JS, Kuk E, Yu KN, Kim J-H, Park SJ, Lee HJ, et al. Antimicrobial effects of silver nanoparticles. Nanomedicine: Nanotechnology, Biology and Medicine. 2007;3(1):95-101.
Her S, Jaffray DA, Allen C. Gold nanoparticles for applications in cancer radiotherapy: Mechanisms and recent advancements. Advanced drug delivery reviews. 2015.
Akbarzadeh A, Samiei M, Davaran S. Magnetic nanoparticles: preparation, physical properties, and applications in biomedicine. Nanoscale research letters. 2012;7(1):144.
Shan X, Yuan Y, Liu C, Tao X, Sheng Y, Xu F. Influence of PEG chain on the complement activation suppression and longevity in vivo prolongation of the PCL biomedical nanoparticles. Biomedical microdevices. 2009;11(6):1187.
Owens DE, Peppas NA. Opsonization, biodistribution, and pharmacokinetics of polymeric nanoparticles. International journal of pharmaceutics. 2006;307(1):93-102.
Dagar A, Kuzmis A, Rubinstein I, Sekosan M, Onyuksel H. VIP-targeted Cytotoxic Nanomedicine for Breast Cancer. Drug delivery and translational research. 2012;2(6):454-62.
Koo OM, Rubinstein I, Onyuksel H. Role of nanotechnology in targeted drug delivery and imaging: a concise review. Nanomedicine: Nanotechnology, Biology and Medicine. 2005;1(3):193-212.
Hafner A, Lovrić J, Lakoš GP, Pepić I. Nanotherapeutics in the EU: an overview on current state and future directions. International journal of nanomedicine. 2014;9:1005.
Friedman LM, Furberg C, DeMets DL, Reboussin DM, Granger CB. Fundamentals of clinical trials: Springer; 1998.
Onaran O, Kayaalp S. Reseptörler ve İlaç Reseptör İlişkisi. In: Kayaalp S, editor. Akılcıl Tedavi Yönünden Tıbbi Farmakoloji. 1. Ankara: Pelikan kitabevi; 2012.
Gilman A, Rall T, Nies A, Taylor PG. Gilman’s: The pharmacological Basis of Therapeutics. 1996 New York. Pergamon Press.
Kunzmann A, Andersson B, Thurnherr T, Krug H, Scheynius A, Fadeel B. Toxicology of engineered nanomaterials: focus on biocompatibility, biodistribution and biodegradation. Biochimica et Biophysica Acta (BBA)-General Subjects. 2011;1810(3):361-73.
Akhter S, Ahmad I, Ahmad MZ, Ramazani F, Singh A, Rahman Z, et al. Nanomedicines as cancer therapeutics: current status. Current cancer drug targets. 2013;13(4):362-78.
Chen M-C, Sonaje K, Chen K-J, Sung H-W. A review of the prospects for polymeric nanoparticle platforms in oral insulin delivery. Biomaterials. 2011;32(36):9826-38.
Swabb EA, Wei J, Gullino PM. Diffusion and convection in normal and neoplastic tissues. Cancer research. 1974;34(10):2814-22.
Solomon R, Gabizon AA. Clinical pharmacology of liposomal anthracyclines: focus on pegylated liposomal doxorubicin. Clinical Lymphoma and Myeloma. 2008;8(1):21-32.
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2020 Journal of Pharmacy & Pharmaceutical Sciences
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
This is an open access journal with free of charge non-commercial download. At the time of submission, authors will be asked to transfer the copyright to the accepted article to the Journal of Pharmacy and Pharmaceutical Sciences. The author may purchase the copyright for $500 upon which he/she will have the exclusive copyright to the article. Nevertheless, acceptance of a manuscript for publication in the Journal is with the authors' approval of the terms and conditions of the Creative Commons copyright license Creative Common license (Attribution-ShareAlike) License for non-commercial uses.
CLOCKSS system has permission to collect, preserve, and serve this Archival Unit.
