Cancer Nanomedicine: from Targeted Delivery to Combination Therapy

Cancer Nanomedicine: from Targeted Delivery to Combination Therapy

Review Cancer nanomedicine: from targeted delivery to combination therapy 1,2,3 1 1 1,2 Xiaoyang Xu , William Ho , Xueqing Zhang , Nicolas Bertrand , and 1 Omid Farokhzad 1 Laboratory of Nanomedicine and Biomaterials, Brigham and Women’s Hospital, Harvard Medical School, Boston, MA 02115, USA 2 The David H. Koch Institute for Integrative Cancer Research, Massachusetts Institute of Technology, Cambridge, MA 02139, USA 3 Department of Chemical, Biological and Pharmaceutical Engineering, New Jersey Institute of Technology, Newark, NJ 07102, USA The advent of nanomedicine marks an unparalleled op- advantages of NPs have brought widespread attention to portunity to advance the treatment of various diseases, the field of nanomedicine, including their large ratio of including cancer. The unique properties of nanoparticles volume to surface area, modifiable external shell, biode- (NPs), such as large surface-to-volume ratio, small size, gradability, and low cytotoxicity [4]. Furthermore, nano- the ability to encapsulate various drugs, and tunable medicine brings us dramatically closer to realizing the full surface chemistry, give them many advantages over their promise of personalized medicine [5]. bulk counterparts. This includes multivalent surface mod- Engineered therapeutic NPs offer numerous clinical ification with targeting ligands, efficient navigation of the advantages. Surface modification with polyethylene glycol complex in vivo environment, increased intracellular traf- (PEG) protects NPs from clearance from the blood by the ficking, and sustained release of drug payload. These mononuclear phagocytic system (MPS), markedly increasing advantages make NPs a mode of treatment potentially both circulation times and drug uptake by target cells superior to conventional cancer therapies. This review [2,6]. Functionalization of the NP surface with multivalent highlights the most recent developments in cancer treat- targeting moieties not only improves drug efficacy but simul- ment using NPs as drug delivery vehicles, including prom- taneously reduces the dose, providing a novel method to ising opportunities in targeted and combination therapy. optimize drug pharmacokinetics [6]. NPs spatially localize through passive/active targeting and are capable of deliver- Nanomedicine in cancer therapy ing drugs through epi/endothelial barriers [3]. Below we Nanomedicine (see Glossary) is the design and development present some examples of engineered NPs and their features of therapeutics and diagnostic tools distinguished by the nanoscopic scale of its delivery vehicles and diagnostic agents [1]. The nanomedical field is rapidly gaining recog- Glossary nition through developing ways of administering treatment, Active targeting: the targeted homing of NPs to sites of disease by modifying particularly anticancer therapy, with unprecedented safety the surface of the particle with ligands specific to biomarkers overrepresented and efficiency. Researchers have improved on the current in target cells. Amphiphilic: possessing both hydrophilic and hydrophobic parts. standards in drug delivery relating to biodistribution, in- Combinatorial nanodelivery: the delivery of more than a single therapeutic tracellular uptake, and dosing efficacy by utilizing NPs to agent in one particle, often in an optimized ratio for synergistic effect. Multiple encapsulate therapeutic agents and target sites of disease cancer pathways may be targeted with one particle. Liposome: a spherical vesicle comprising a lipid bilayer. [2]. The successful application of processes to improve the Microfluidics: a technology used to quickly fabricate uniform NPs by delivery of biomedical entities through functional NPs is a manipulating minute amounts of liquid via channels on the micrometer scale. revolutionary approach to disease treatment. Several lipo- Mononuclear phagocyte system (MPS): the MPS, also called the reticuloen- dothelial system, comprises the phagocytes located in reticular connective some- and polymer-based therapeutic NPs have been ap- tissue present in the liver, lymph nodes, and spleen that are responsible for the proved by the FDA for clinical use [1]. This review discusses eventual clearance of most NPs. the NPs under investigation with an emphasis on systems Nanomedicine: the design and development of therapeutic agents and diagnostic tools distinguished by the nanoscopic scale of its delivery vehicles that have reached clinical trials (Table 1). and diagnostic agents. NPs are minute particles, typically less than 200 nm in Nanoparticle (NP): particles, usually comprising lipid or polymer, typically less diameter. Their nanoscopic size facilitates intracellular than 200 nm in diameter. Passive targeting/enhanced permeability and retention (EPR) effect: refers to uptake. NPs have the ability to encapsulate therapeutic the observation that the permeable vasculature and disordered basement agents and release them in a controlled manner to specifi- membrane of tumor tissue leads to preferential accumulation of entities of 10– 500 nm in size. cally target diseased cells. NP encapsulation also improves Poly(D,L-lactide-co-glycolide) (PLGA): a commonly used polymer for the the solubility of unmodified drug compounds [3]. Additional construction of NPs, usually selected for its controlled release capabilities. Polyethylene glycol (PEG): a polymer used to modify the NP surface, resulting Corresponding authors: Xu, X. ([email protected]); in the prevention of nonspecific binding to blood components. These ‘stealth’ Farokhzad, O. ([email protected]). particles are better able to evade clearance by cells of the MPS. Keywords: nanomedicine; targeted delivery; combination therapy; cancer. RNAi: a pathway in eukaryotic cells where short pieces of RNA are able to induce the breakdown of complementary mRNAs. 1471-4914/ Zwitterionic polymer: a polymer that is capable of exhibiting both positive and ß 2015 Elsevier Ltd. All rights reserved. http://dx.doi.org/10.1016/j.molmed.2015.01.001 negative charges and has been shown to resist nonspecific protein adsorption. Trends in Molecular Medicine, April 2015, Vol. 21, No. 4 223 Review Trends in Molecular Medicine April 2015, Vol. 21, No. 4 Table 1. Nanomedicines in clinical development Targeting ligand Therapeutic agent Indication Clinical status encapsulated Liposomes ALN-TTR02 (NCT01559077) Passive siRNA TTR amyloidosis Phase II CALAA-01 (NCT00689065) Tf siRNA Solid tumors Phase I CPX-351 (NCT00822094) Passive Cytarabine and Acute myeloid leukemia Phase III daunorubicin MBP-426 (NCT00964080) Tf Oxaliplatin Gastroesophageal Phase II adenocarcinoma SGT53-01 (NCT00470613) Antibody fragment p53 gene Solid tumors Phase I TKM-PLK1 (NCT01262235) Passive siRNA Solid tumors Phase II Polymeric NPs BIND-014 (NCT01300533) Small molecule Docetaxel Solid tumors Phase II Atu027 (NCT01808638) Protein kinase N3 siRNA Solid tumors Phase II CRLX-101 (NCT01380769)/ Passive CPT Non-small cell lung Phase II (NCT00333502)/(NCT02010567) cancer/rectal cancer/renal cell carcinoma that have been designed to address existing challenges in controllable mixing time, which promotes higher NP yield drug delivery, with a specific focus on cancer therapy. and uniform size [14,15]. Through multi-inlet mixing at NPs increase drug solubility, mitigate cytotoxicity, and different ratios and hydrodynamic flow focusing, the NPs improve drug pharmacokinetic profiles, as exemplified by self-assemble through diffusive mass transfer at the interface 1 1 nanomedicines such as Doxil and Genexol-PM . The of miscible liquids (Figure 1) [12]. Other significant advan- past decade has witnessed numerous new biotechnological tages of microfluidics include the reproduciblility of device approaches to the treatment of cancer. For example, the fabrication and rapid, consistent NP synthesis with narrow 2006 Nobel Prize in Physiology or Medicine brought size distributions [14]. Microfluidic devices are tunable and renewed focus on gene silencing, and the therapeutic can use 3D hydrodynamic focusing to create NPs of different opportunities offered by precise regulation of gene expres- sizes and targeting ligand densities with multiple polymers, sion have fostered the interest of medical stakeholders in which can in turn produce diverse NP libraries (Figure 1) siRNA and miRNA technologies [7]. Nevertheless, deliver- [16,17]. In addition, microfluidics provides a means of rapidly ing nucleic acids into cells is challenging to say the least: and continuously forming consistent nano- and microstruc- nucleic acids are vulnerable to nucleases ubiquitous in the tures while simultaneously encapsulating drugs, which is not blood and their dense negative charges hinder cell inter- readily feasible with conventional approaches [18,19]. How- nalization. Furthermore, the nonspecific interferon re- ever, to take full advantage of the benefits of microfluidic sponse triggered by the presence of foreign nucleic acids nanoformulation, the challenges associated with the high in the cytoplasm is a major impediment to clinical trans- costs of glass/silicon fabrication and large-scale production lation [7–9]. To avoid these drawbacks, the ideal siRNA for clinical use remain to be addressed [14]. delivery system should efficiently encapsulate the nega- tively charged siRNA molecule, prevent degradation by ‘Stealth’ modification of NPs endogenous enzymes, and facilitate cellular uptake and Modification with PEG is currently the gold standard for intracellular release. NP coating [10,20,21]. PEG surface functionalization

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