Vol. 3 Frontiers in Nanobiomedical Research HANDBOOK OF NANOBIOMEDICAL RESEARCH Fundamentals, Applications and Recent Developments l1 Materials for Nanomedicine 8874v1_9789814520645_tp.indd 1 26/6/14 1:52 pm Frontiers in Nanobiomedical Research ISSN: 2251-3965 Series Editors: Martin L. Yarmush (Harvard Medical School, USA) Donglu Shi (University of Cincinnati, USA) Published Vol. 1: Handbook of Immunological Properties of Engineered Nanomaterials edited by Marina A. Dobrovolskaia and Scott E. McNeil (SAIC-Frederick, Inc., USA) Vol. 2: Tissue Regeneration: Where Nano-Structure Meets Biology edited by Qing Liu (3D Biotek, USA and Tongji University, China) and Hongjun Wang (Stevens Institute of Technology, USA) Vol. 3: Handbook of Nanobiomedical Research: Fundamentals, Applications and Recent Developments (In 4 Volumes) edited by Vladimir Torchilin (Northeastern University, USA) Forthcoming titles Cancer Therapeutics and Imaging: Molecular and Cellular Engineering and Nanobiomedicine edited by Kaushal Rege (Arizona State University, USA) Nano Vaccines edited by Balaji Narasimhan (Iowa State University, USA) Nano Pharmaceuticals edited by Rajesh N. Dave (New Jersey Institute of Technology, USA) Thermal Aspects in Nanobiomedical Systems and Devices by Dong Cai (Boston College, USA) Nano Mechanochemistry in Biology edited by Jeffrey Ruberti (Northeastern University, USA) Nanomaterial Probes of Biological Processes and Systems edited by David Mast (University of Cincinnati, USA) Handbook of Biomaterials edited by Donglu Shi (University of Cincinnati, USA) and Xuejun Wen (Clemson University, USA) Sanjeed - Hdbk of Nanobiomedical Research.indd 1 26/6/2014 3:04:56 PM HANDBOOK OF NANOBIOMEDICAL RESEARCH Fundamentals, Applications and Recent Developments l 1 Materials for Nanomedicine editor Vol. 3 Vladimir Torchilin Frontiers in Northeastern University, USA Nanobiomedical Research World Scientific NEW JERSEY • LONDON • SINGAPORE • BEIJING • SHANGHAI • HONG KONG • TAIPEI • CHENNAI 8874v1_9789814520645_tp.indd 2 26/6/14 1:52 pm Published by World Scientific Publishing Co. Pte. Ltd. 5 Toh Tuck Link, Singapore 596224 USA office: 27 Warren Street, Suite 401-402, Hackensack, NJ 07601 UK office: 57 Shelton Street, Covent Garden, London WC2H 9HE Library of Congress Cataloging-in-Publication Data Handbook of nanobiomedical research : fundamentals, applications, and recent developments / editor, Vladimir Torchilin. p. ; cm. -- (Frontiers in nanobiomedical research ; vol. 3) Includes bibliographical references and index. ISBN 978-9814520645 (set : alk. paper) -- ISBN 978-9814520676 (volume 1 : alk. paper) -- ISBN 978-9814520683 (volume 2 : alk. paper) -- ISBN 978-9814520690 (volume 3 : alk. paper) -- ISBN 978-9814520706 (volume 4 : alk. paper) I. Torchilin, V. P., editor. II. Series: Frontiers in nanobiomedical research ; v. 3. 2251-3965 [DNLM: 1. Nanomedicine. 2. Nanostructures. 3. Nanotechnology. QT 36.5] R857.N34 610.28--dc23 2014024090 British Library Cataloguing-in-Publication Data A catalogue record for this book is available from the British Library. Copyright © 2014 by World Scientific Publishing Co. Pte. Ltd. All rights reserved. This book, or parts thereof, may not be reproduced in any form or by any means, electronic or mechanical, including photocopying, recording or any information storage and retrieval system now known or to be invented, without written permission from the publisher. For photocopying of material in this volume, please pay a copying fee through the Copyright Clearance Center, Inc., 222 Rosewood Drive, Danvers, MA 01923, USA. In this case permission to photocopy is not required from the publisher. Typeset by Stallion Press Email: [email protected] Printed in Singapore Sanjeed - Hdbk of Nanobiomedical Research.indd 2 26/6/2014 3:04:56 PM Vol-I b1655 Handbook of Nanobiomedical Research 11 July 2014 6:50 AM Contents Chapter 1 Liposomal Nanomedicines 1 Amr S. Abu Lila, Tatsuhiro Ishida and Theresa M. Allen Chapter 2 Solid Lipid Nanoparticles for Biomedical Applications 55 Karsten Mäder Chapter 3 Micellar Nanopreparations for Medicine 87 Rupa Sawant and Aditi Jhaveri Chapter 4 Nanoemulsions in Medicine 141 William B. Tucker and Sandro Mecozzi Chapter 5 Drug Nanocrystals and Nanosuspensions in Medicine 169 Leena Peltonen, Jouni Hirvonen and Timo Laaksonen Chapter 6 Polymeric Nanosystems for Integrated Image-Guided Cancer Therapy 199 Amit Singh, Arun K. Iyer and Mansoor M. Amiji Chapter 7 Polysaccharide-Based Nanocarriers for Drug Delivery 235 Carmen Teijeiro, Adam McGlone, Noemi Csaba, Marcos Garcia-Fuentes and María J. Alonso Chapter 8 Dendrimers for Biomedical Applications 279 Lisa M. Kaminskas, Victoria M. McLeod, Seth A. Jones, Ben J. Boyd and Christopher J. H. Porter Chapter 9 Layer-by-Layer Nanopreparations for Medicine — Smart Polyelectrolyte Multilayer Capsules and Coatings 329 Rawil F. Fakhrullin, Gleb B. Sukhorukov and Yuri M. Lvov v bb11665555__FFMM__VVooll--II..iinndddd vv 77//1111//22001144 11::1111::0088 PPMM Vol-I b1655 Handbook of Nanobiomedical Research 11 July 2014 6:50 AM vi Contents Chapter 10 Inorganic Nanopreparations for Nanomedicine 367 James Ramos and Kaushal Rege Chapter 11 Silica-Based Nanoparticles for Biomedical Imaging and Drug Delivery Applications 403 Stephanie A. Kramer and Wenbin Lin Chapter 12 Carbon Nanotubes in Biomedical Applications 439 Krunal K. Mehta, Elena E. Paskaleva, Jonathan S. Dordick and Ravi S. Kane Chapter 13 Core-Shell Nanoparticles for Biomedical Applications 475 Mahmoud Elsabahy and Karen L. Wooley Chapter 14 Structure–Activity Relationships for Tumor-Targeting Gold Nanoparticles 519 Erik C. Dreaden, Ivan H. El-Sayed and Mostafa A. El-Sayed Chapter 15 Silver Nanoparticles as Novel Antibacterial and Antiviral Agents 565 Stefania Galdiero, Annarita Falanga, Marco Cantisani, Avinash Ingle, Massimiliano Galdiero and Mahendra Rai Chapter 16 Magnetic Nanoparticles for Drug Delivery 595 Rainer Tietze, Harald Unterweger and Christoph Alexiou Chapter 17 Quantum Dots as a Platform Nanomaterial for Biomedical Applications 621 Eleonora Petryayeva, Roza Bidshahri, Kate Liu, Charles A. Haynes, Igor L. Medintz, and W. Russ Algar Index 663 bb11665555__FFMM__VVooll--II..iinndddd vvii 77//1111//22001144 11::1111::0088 PPMM Vol-I b1655 Handbook of Nanobiomedical Research 11 July 2014 6:47 AM Chapter 1 Liposomal Nanomedicines Amr S. Abu Lila*,†, Tatsuhiro Ishida* and Theresa M. Allen‡,§ *Department of Pharmacokinetics and Biopharmaceutics, Subdivision of Biopharmaceutical Sciences, Institute of Health Biosciences, The University of Tokushima; 1-78-1, Sho-machi, Tokushima 770-8505, Japan †Department of Pharmaceutics and Industrial Pharmacy, Faculty of Pharmacy, Zagazig University, Zagazig, Egypt ‡Department of Pharmacology, University of Alberta, Edmonton, AB T6G 2H7, Canada §[email protected] 1. Introduction Since Bangham’s original description of phospholipid bilayer vesicles in 1965,1 liposomes have emerged as archetypal nanoscale drug carriers, and they have received much attention as transporters of pharmacological agents.2–7 Liposomes, sometimes called l ipidic nanoparticles (LNP), are phospholipid bilayer vesicles that self-assemble when naturally occurring, or synthetic, phospholipids (PLs) are hydrated with excess water or aqueous salt solutions. Hydration can occur from dried preparations or in the presence of organic solvent such as ethanol, and various therapeutic molecules can be included in the hydration solution. Some examples of the PLs commonly used in liposome production include phosphatidylcholine (PC), in particular hydrogenated soybean phos- phatidylcholine (HSPC), sphingomyelin (SM) and phosphatidylglycerol (PG), and also the lipid cholesterol (Chol) is often included in the prepara- tions. Liposomes can range in diameter from 0.025 µm to greater than 1 bb11665555__CChh--0011__VVooll--II..iinndddd 11 77//1111//22001144 11::0066::1111 PPMM Vol-I b1655 Handbook of Nanobiomedical Research 11 July 2014 6:47 AM 2 A. S. Abu Lila, T. Ishida & T. M. Allen (a) (b) (c) (d) Fig. 1. Structures of different liposomal preparations, (a) classical liposome encapsulating lipid soluble drugs, (b) classical liposome encapsulating aqueous soluble drugs, (c) sterically stabilized liposomes and (d) ligand-targeted liposome containing an aqueous soluble drug. 20 µm, and are composed of a single bilayer surrounding an aqueous core, or of multiple bilayers, called lamellae, which are separated by aqueous com- partments. Because of their amphiphilic nature, liposomes can accommodate a variety of drugs with different physicochemical characteristics Figs. 1(a)– 1(b). Hydrophilic drugs — polar and ionic compounds — can be encapsu- lated within the internal aqueous compartments,8 while lipophilic drugs, are usually associated with the fatty acyl chains of the lipid bilayers9 Moreover, drugs may partition between the enclosed aqueous volume and the phospho- lipid bilayer membranes according to the solubility and ionization character- istics of the drug, which is greatly affected by the pH of the surrounding medium.10–12 The net surface charge of a liposome can be varied by incorporation of lipids with negative or positive charges. For example, inclusion of a long- chain amine in the bilayer will give positively charged vesicles, and inclusion of diacetyl phosphate will give negatively charged vesicles. Positively charged liposomes have been used experimentally as carriers for anionic genetic materials.13–15 bb11665555__CChh--0011__VVooll--II..iinndddd 22 77//1111//22001144 11::0066::1111 PPMM Vol-I b1655 Handbook of Nanobiomedical Research 11 July 2014 6:47 AM Liposomal Nanomedicines 3 2. Inherent Problems Relating to Liposomal Formulations 2.1. Non-optimal drug release rates Drug release rates can have implications for the therapeutic effects of all types of drug delivery systems, including liposomes. It is well-known that drugs entrapped in liposomes, or other types of particles, are not bioavailable; they only become bioavailable when they are released. Therefore, optimization of the release rate of entrapped drugs from the liposomes is crucial for ensuring the delivery of minimal therapeutic concentrations of bioavailable drugs within the target tissue, at appropriate rates, for sufficient periods of time, to achieve an acceptable therapeutic outcome.16–18 Soon after the development of liposomes as d rug delivery systems, several problems associated with the in vivo use of the 1st generation “ classical” liposomes were identified. The challenges include: the difficulty in retaining some types of molecules, in particular hydrophobic substances, in association with the liposomes, and an inappropriate rate of drug release from liposomes. Drug release from liposomes was shown to be mediated by factors such as interactions with serum proteins,19–21 the drug loading method, and the phys- icochemical properties of the lipid membrane and the entrapped drug.22 Drugs with extremely low octanol/buffer partition coefficients exhibited prolonged liposomal retention, whereas molecules with log p ranging from −0.3 to 1.7 were, in contrast, released rapidly.23 Alteration of the membrane composition of liposomes was found to affect the release rate of the encapsu- lated drug. Switching from a fluid phase phospholipid bilayer to a solid phase bilayer,24 and incorporation of cholesterol19,25,26 were shown to reduce the leakage of drugs from liposomes. With the development of active “ remote” loading procedures for encap- sulation of weak bases and weak acids, and by the careful choice of drugs with physical characteristics that made them amenable to retention in liposomes, control over the release rate of entrapped drugs could be achieved. The reten- tion properties of drugs in liposomes are dependent on the drug properties and the bilayer properties. For example, weak bases such as doxorubicin (DXR), which are hydrophobic at physiological pH, can be retained for long periods of time when present as sulfate or citrate precipitates inside liposomes that have an interior/exterior pH gradient.27 Other drugs that lack an ionizable group, including paclitaxel or ciprofloxacin, cannot be remotely loaded and are released rapidly from liposomes.28–31 Alteration of the drug-to- lipid ratio was found to affect the drug release rate, in a drug-dependent manner. Mayer et al.32 have reported that increasing the drug-to-lipid ratio resulted in decreased drug retention of DXR. On the other hand, increasing bb11665555__CChh--0011__VVooll--II..iinndddd 33 77//1111//22001144 11::0066::1122 PPMM