Targeting Strategies for the Combination Treatment of Cancer Using Drug Delivery Systems

Cancer cells have characteristics of acquired and intrinsic resistances to chemotherapy treatment—due to the hostile tumor microenvironment—that create a significant challenge for effective therapeutic regimens. Multidrug resistance, collateral toxicity to normal cells, and detrimental systemic side effects present significant obstacles, necessitating alternative and safer treatment strategies. Traditional administration of chemotherapeutics has demonstrated minimal success due to the non-specificity of action, uptake and rapid clearance by the immune system, and subsequent metabolic alteration and poor tumor penetration. Nanomedicine can provide a more effective approach to targeting cancer by focusing on the vascular, tissue, and cellular characteristics that are unique to solid tumors. Targeted methods of treatment using nanoparticles can decrease the likelihood of resistant clonal populations of cancerous cells. Dual encapsulation of chemotherapeutic drug allows simultaneous targeting of more than one characteristic of the tumor. Several first-generation, non-targeted nanomedicines have received clinical approval starting with Doxil® in 1995. However, more than two decades later, second-generation or targeted nanomedicines have yet to be approved for treatment despite promising results in pre-clinical studies. This review highlights recent studies using targeted nanoparticles for cancer treatment focusing on approaches that target either the tumor vasculature (referred to as ‘vascular targeting’), the tumor microenvironment (‘tissue targeting’) or the individual cancer cells (‘cellular targeting’). Recent studies combining these different targeting methods are also discussed in this review. Finally, this review summarizes some of the reasons for the lack of clinical success in the field of targeted nanomedicines.

[1]  Peng Zhang,et al.  Multifunctional nanoassemblies for vincristine sulfate delivery to overcome multidrug resistance by escaping P-glycoprotein mediated efflux. , 2011, Biomaterials.

[2]  Zhiwei Hu,et al.  Targeting tissue factor on tumour cells and angiogenic vascular endothelial cells by factor VII-targeted verteporfin photodynamic therapy for breast cancer in vitro and in vivo in mice , 2010, BMC Cancer.

[3]  Y. Yoshioka,et al.  Optimization and internalization mechanisms of PEGylated adenovirus vector with targeting peptide for cancer gene therapy. , 2012, Biomacromolecules.

[4]  Wei Li,et al.  Molecular Mechanisms of Anti-cancer Activities of β-elemene: Targeting Hallmarks of Cancer. , 2016, Anti-cancer agents in medicinal chemistry.

[5]  Alexander V Kabanov,et al.  Macrophage exosomes as natural nanocarriers for protein delivery to inflamed brain. , 2017, Biomaterials.

[6]  Xin-guo Jiang,et al.  Precise glioma targeting of and penetration by aptamer and peptide dual-functioned nanoparticles. , 2012, Biomaterials.

[7]  De-guang Sun,et al.  Metformin reverses multidrug resistance in human hepatocellular carcinoma Bel-7402/5-fluorouracil cells , 2014, Molecular medicine reports.

[8]  Xun Sun,et al.  Coadministration of Oligomeric Hyaluronic Acid-Modified Liposomes with Tumor-Penetrating Peptide-iRGD Enhances the Antitumor Efficacy of Doxorubicin against Melanoma. , 2017, ACS applied materials & interfaces.

[9]  Jianlin Shi,et al.  Tumor vascular-targeted co-delivery of anti-angiogenesis and chemotherapeutic agents by mesoporous silica nanoparticle-based drug delivery system for synergetic therapy of tumor , 2015, International journal of nanomedicine.

[10]  L. Qiu,et al.  Reversal of P-glycoprotein-mediated multidrug resistance by doxorubicin and quinine co-loaded liposomes in tumor cells , 2017, Journal of liposome research.

[11]  Chen Jiang,et al.  Tumor-targeting and microenvironment-responsive smart nanoparticles for combination therapy of antiangiogenesis and apoptosis. , 2013, ACS nano.

[12]  Kazuo Maruyama,et al.  Transferrin-modified liposomes equipped with a pH-sensitive fusogenic peptide: an artificial viral-like delivery system. , 2004, Biochemistry.

[13]  Liangzhu Feng,et al.  Drug-Induced Self-Assembly of Modified Albumins as Nano-theranostics for Tumor-Targeted Combination Therapy. , 2015, ACS nano.

[14]  Yueqi Zhu,et al.  Synergistic mediation of tumor signaling pathways in hepatocellular carcinoma therapy via dual-drug-loaded pH-responsive electrospun fibrous scaffolds. , 2015, Journal of materials chemistry. B.

[15]  S. Beg,et al.  Nanoparticles for Cancer Targeting: Current and Future Directions. , 2016, Current drug delivery.

[16]  Ming Zhao,et al.  Lipid rafts-mediated endocytosis and physiology-based cell membrane traffic models of doxorubicin liposomes. , 2016, Biochimica et biophysica acta.

[17]  Xiaolian Sun,et al.  Nanoparticle design strategies for enhanced anticancer therapy by exploiting the tumour microenvironment. , 2017, Chemical Society reviews.

[18]  V. Préat,et al.  RGD-based strategies to target alpha(v) beta(3) integrin in cancer therapy and diagnosis. , 2012, Molecular pharmaceutics.

[19]  Hong Wang,et al.  Honokiol Enhances Paclitaxel Efficacy in Multi-Drug Resistant Human Cancer Model through the Induction of Apoptosis , 2014, PloS one.

[20]  S. Mitragotri,et al.  Vascular Targeting of Nanocarriers: Perplexing Aspects of the Seemingly Straightforward Paradigm , 2014, ACS nano.

[21]  Yanxiu Ge,et al.  The application of prodrug-based nano-drug delivery strategy in cancer combination therapy. , 2016, Colloids and surfaces. B, Biointerfaces.

[22]  A. Molinari,et al.  Liposomes as nanomedical devices , 2015, International journal of nanomedicine.

[23]  P. Rai,et al.  Targeting Cancer using Polymeric Nanoparticle mediated Combination Chemotherapy , 2016, International journal of nanomedicine and nanosurgery.

[24]  A. Jemal,et al.  Cancer statistics, 2016 , 2016, CA: a cancer journal for clinicians.

[25]  Qiang Zhang,et al.  Synergistic inhibition of breast cancer by co-delivery of VEGF siRNA and paclitaxel via vapreotide-modified core-shell nanoparticles. , 2014, Biomaterials.

[26]  Haiyan Liu,et al.  Galactose-installed photo-crosslinked pH-sensitive degradable micelles for active targeting chemotherapy of hepatocellular carcinoma in mice. , 2014, Journal of controlled release : official journal of the Controlled Release Society.

[27]  H. Gu,et al.  Highly effective antiangiogenesis via magnetic mesoporous silica-based siRNA vehicle targeting the VEGF gene for orthotopic ovarian cancer therapy , 2015, International journal of nanomedicine.

[28]  K. Borden,et al.  Mechanisms and insights into drug resistance in cancer , 2013, Front. Pharmacol..

[29]  S. Nair,et al.  Transferrin targeted core-shell nanomedicine for combinatorial delivery of doxorubicin and sorafenib against hepatocellular carcinoma. , 2014, Nanomedicine : nanotechnology, biology, and medicine.

[30]  P. Skipp,et al.  Nanoparticles in the lung and their protein corona: the few proteins that count , 2016, Nanotoxicology.

[31]  Jing Liu,et al.  Antibody h-R3-dendrimer mediated siRNA has excellent endosomal escape and tumor targeted delivery ability, and represents efficient siPLK1 silencing and inhibition of cell proliferation, migration and invasion , 2016, Oncotarget.

[32]  P. Zhang,et al.  Transferrin-conjugated doxorubicin-loaded lipid-coated nanoparticles for the targeting and therapy of lung cancer , 2014, Oncology letters.

[33]  Baoan Chen,et al.  Biocompatibility of Fe3O4/DNR magnetic nanoparticles in the treatment of hematologic malignancies , 2010, International journal of nanomedicine.

[34]  A. Moshnikova,et al.  Novel pH-Sensitive Cyclic Peptides , 2016, Scientific Reports.

[35]  Zheng-Rong Lu,et al.  Multifunctional cationic lipid-based nanoparticles facilitate endosomal escape and reduction-triggered cytosolic siRNA release. , 2014, Molecular pharmaceutics.

[36]  Philip M. Kelly,et al.  Transferrin-functionalized nanoparticles lose their targeting capabilities when a biomolecule corona adsorbs on the surface. , 2013, Nature nanotechnology.

[37]  Véronique Préat,et al.  To exploit the tumor microenvironment: Passive and active tumor targeting of nanocarriers for anti-cancer drug delivery. , 2010, Journal of controlled release : official journal of the Controlled Release Society.

[38]  Ali Jahanban-Esfahlan,et al.  Combination of nanotechnology with vascular targeting agents for effective cancer therapy , 2018, Journal of cellular physiology.

[39]  D. Engelman,et al.  The pH low insertion peptide pHLIP Variant 3 as a novel marker of acidic malignant lesions , 2015, Proceedings of the National Academy of Sciences.

[40]  Tao Zhang,et al.  Combination of chemotherapy and cancer stem cell targeting agents: Preclinical and clinical studies. , 2017, Cancer letters.

[41]  P. Rai,et al.  Nanoparticles for Effective Combination Therapy of Cancer , 2016, International journal of nanotechnology and nanomedicine.

[42]  Huangxian Ju,et al.  Cell-specific and pH-activatable rubyrin-loaded nanoparticles for highly selective near-infrared photodynamic therapy against cancer. , 2013, Journal of the American Chemical Society.

[43]  D. Heitjan,et al.  Efficacy of the nanoparticle-drug conjugate CRLX101 in combination with bevacizumab in metastatic renal cell carcinoma: results of an investigator-initiated phase I-IIa clinical trial. , 2016, Annals of oncology : official journal of the European Society for Medical Oncology.

[44]  S. Nie,et al.  A reexamination of active and passive tumor targeting by using rod-shaped gold nanocrystals and covalently conjugated peptide ligands. , 2010, ACS nano.

[45]  Jeong-Seok Nam,et al.  Targeting cancer stem cells by using the nanoparticles , 2015, International journal of nanomedicine.

[46]  D. Howard,et al.  Thermal Effect of J-Plasma® Energy in a Porcine Tissue Model: Implications for Minimally Invasive Surgery. , 2014, Surgical technology international.

[47]  Xiaoyang Xu,et al.  Cancer nanotechnology: the impact of passive and active targeting in the era of modern cancer biology. , 2014, Advanced drug delivery reviews.

[48]  Zhiwei Hu,et al.  Selective and effective killing of angiogenic vascular endothelial cells and cancer cells by targeting tissue factor using a factor VII-targeted photodynamic therapy for breast cancer , 2011, Breast Cancer Research and Treatment.

[49]  A. Sudhakar,et al.  History of Cancer, Ancient and Modern Treatment Methods. , 2009, Journal of cancer science & therapy.

[50]  A. Mencalha,et al.  Targeting Cellular Signaling Pathways in Breast Cancer Stem Cells and its Implication for Cancer Treatment. , 2016, Anticancer research.

[51]  Yingying Zhang,et al.  Polymer-Lipid Hybrid Theranostic Nanoparticles Co-Delivering Ultrasmall Superparamagnetic Iron Oxide and Paclitaxel for Targeted Magnetic Resonance Imaging and Therapy in Atherosclerotic Plaque. , 2016, Journal of biomedical nanotechnology.

[52]  Mengjiao Qi,et al.  Dual pH/redox responsive and CD44 receptor targeting hybrid nano-chrysalis based on new oligosaccharides of hyaluronan conjugates. , 2017, Carbohydrate polymers.

[53]  M. Kester,et al.  Targeting cancer cells in the tumor microenvironment: opportunities and challenges in combinatorial nanomedicine. , 2016, Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology.

[54]  M. Weller,et al.  Hypoxia-induced cell death in human malignant glioma cells: energy deprivation promotes decoupling of mitochondrial cytochrome c release from caspase processing and necrotic cell death , 2003, Cell Death and Differentiation.

[55]  Wenxin Qin,et al.  Synergistic Cisplatin/Doxorubicin Combination Chemotherapy for Multidrug-Resistant Cancer via Polymeric Nanogels Targeting Delivery. , 2017, ACS applied materials & interfaces.

[56]  Natallia V. Katenka,et al.  Comparative Study of Tumor Targeting and Biodistribution of pH (Low) Insertion Peptides (pHLIP® Peptides) Conjugated with Different Fluorescent Dyes , 2016, Molecular Imaging and Biology.

[57]  Yaping Li,et al.  Inhibition of metastasis and growth of breast cancer by pH-sensitive poly (β-amino ester) nanoparticles co-delivering two siRNA and paclitaxel. , 2015, Biomaterials.

[58]  Jie Gao,et al.  Therapeutic PEG-ceramide nanomicelles synergize with salinomycin to target both liver cancer cells and cancer stem cells. , 2017, Nanomedicine.

[59]  M. Jaafari,et al.  Targeting CD44 expressing cancer cells with anti-CD44 monoclonal antibody improves cellular uptake and antitumor efficacy of liposomal doxorubicin. , 2015, Journal of controlled release : official journal of the Controlled Release Society.

[60]  V. Torchilin,et al.  Anti-cancer activity of doxorubicin-loaded liposomes co-modified with transferrin and folic acid. , 2016, European journal of pharmaceutics and biopharmaceutics : official journal of Arbeitsgemeinschaft fur Pharmazeutische Verfahrenstechnik e.V.

[61]  S. Ku,et al.  PEGylated lipid bilayer-supported mesoporous silica nanoparticle composite for synergistic co-delivery of axitinib and celastrol in multi-targeted cancer therapy. , 2016, Acta biomaterialia.

[62]  V. Catalano,et al.  Genetic modulation of the interleukin 6 (IL-6) system in patients with advanced gastric cancer: a background for an alternative target therapy , 2014, BMC Cancer.

[63]  Xiaoyang Xu,et al.  Cancer Nanomedicine: From Targeted Delivery to Combination Therapy , 2015, Trends in molecular medicine.

[64]  S. Sivasubramanian,et al.  Combinatorial nanocarrier based drug delivery approach for amalgamation of anti-tumor agents in bresat cancer cells: an improved nanomedicine strategies , 2016, Scientific Reports.

[65]  Wenbin Zeng,et al.  Integrin (αvβ3) Targeted RGD Peptide Based Probe for Cancer Optical Imaging. , 2016, Current protein & peptide science.

[66]  Songbin Fu,et al.  microRNA-128 plays a critical role in human non-small cell lung cancer tumourigenesis, angiogenesis and lymphangiogenesis by directly targeting vascular endothelial growth factor-C. , 2014, European journal of cancer.

[67]  Mingwu Shen,et al.  Dendrimer-entrapped gold nanoparticles modified with RGD peptide and alpha-tocopheryl succinate enable targeted theranostics of cancer cells. , 2015, Colloids and surfaces. B, Biointerfaces.

[68]  J. Benoit,et al.  The rise and rise of stealth nanocarriers for cancer therapy: passive versus active targeting. , 2010, Nanomedicine.

[69]  Yitao Wang,et al.  Hyaluronic acid-coated PEI-PLGA nanoparticles mediated co-delivery of doxorubicin and miR-542-3p for triple negative breast cancer therapy. , 2016, Nanomedicine : nanotechnology, biology, and medicine.

[70]  Jing Sun,et al.  Synthesis and characterization of biocompatible Fe3O4 nanoparticles. , 2007, Journal of biomedical materials research. Part A.

[71]  D. H. Burke,et al.  Toward the Selection of Cell Targeting Aptamers with Extended Biological Functionalities to Facilitate Endosomal Escape of Cargoes , 2017, Biomedicines.

[72]  R. Pochampally,et al.  The combined effect of encapsulating curcumin and C6 ceramide in liposomal nanoparticles against osteosarcoma. , 2014, Molecular pharmaceutics.

[73]  J. Qian,et al.  Albumin-based nanoparticles as methylprednisolone carriers for targeted delivery towards the neonatal Fc receptor in glomerular podocytes , 2017, International journal of molecular medicine.

[74]  A. Moshnikova,et al.  Targeting breast tumors with pH (low) insertion peptides. , 2014, Molecular pharmaceutics.

[75]  L. Prodi,et al.  Applications of nanoparticles in cancer medicine and beyond: optical and multimodal in vivo imaging, tissue targeting and drug delivery , 2015, Expert opinion on drug delivery.

[76]  K. O'Byrne,et al.  VEGF-mediated cell survival in non-small-cell lung cancer: implications for epigenetic targeting of VEGF receptors as a therapeutic approach. , 2015, Epigenomics.

[77]  Yu Zhang,et al.  Multi-modal Mn-Zn ferrite nanocrystals for magnetically-induced cancer targeted hyperthermia: a comparison of passive and active targeting effects. , 2016, Nanoscale.

[78]  M. Kibbe,et al.  Targeted Nanotherapies for the Treatment of Surgical Diseases , 2016, Annals of surgery.

[79]  K. Braeckmans,et al.  Effect of covalent fluorescence labeling of plasmid DNA on its intracellular processing and transfection with lipid-based carriers. , 2014, Molecular pharmaceutics.

[80]  S. Suresh,et al.  Folic acid functionalized long-circulating co-encapsulated docetaxel and curcumin solid lipid nanoparticles: In vitro evaluation, pharmacokinetic and biodistribution in rats , 2016, Drug delivery.

[81]  Y. Barenholz,et al.  Prolonged circulation time and enhanced accumulation in malignant exudates of doxorubicin encapsulated in polyethylene-glycol coated liposomes. , 1994, Cancer research.

[82]  M. Karin,et al.  Tissue injury and hypoxia promote malignant progression of prostate cancer by inducing CXCL13 expression in tumor myofibroblasts , 2014, Proceedings of the National Academy of Sciences.

[83]  F. Liu,et al.  Chemotherapeutic drug delivery to cancer cells using a combination of folate targeting and tumor microenvironment-sensitive polypeptides. , 2013, Biomaterials.

[84]  M. T. Neves-Petersen,et al.  A new paradigm for antiangiogenic therapy through controlled release of bevacizumab from PLGA nanoparticles , 2017, Scientific Reports.

[85]  R. Kerbel,et al.  Preclinical Efficacy of Bevacizumab with CRLX101, an Investigational Nanoparticle-Drug Conjugate, in Treatment of Metastatic Triple-Negative Breast Cancer. , 2016, Cancer research.

[86]  Gert Storm,et al.  Endosomal escape pathways for delivery of biologicals. , 2011, Journal of controlled release : official journal of the Controlled Release Society.

[87]  Can Zhang,et al.  Reversal of multidrug resistance by co-delivery of paclitaxel and lonidamine using a TPGS and hyaluronic acid dual-functionalized liposome for cancer treatment. , 2015, Biomaterials.

[88]  B. Lai,et al.  Labeling TiO2 nanoparticles with dyes for optical fluorescence microscopy and determination of TiO2-DNA nanoconjugate stability. , 2009, Small.

[89]  Y. Bang,et al.  Combination of EGFR and MEK1/2 inhibitor shows synergistic effects by suppressing EGFR/HER3-dependent AKT activation in human gastric cancer cells , 2009, Molecular Cancer Therapeutics.

[90]  E. Kokkoli,et al.  Dual‐ligand &agr;5&bgr;1 and &agr;6&bgr;4 integrin targeting enhances gene delivery and selectivity to cancer cells , 2017, Journal of controlled release : official journal of the Controlled Release Society.

[91]  Rebecca L. Siegel Mph,et al.  Cancer statistics, 2016 , 2016 .

[92]  Dawen Dong,et al.  Tumor-targeting dual peptides-modified cationic liposomes for delivery of siRNA and docetaxel to gliomas. , 2014, Biomaterials.

[93]  L. Tutar,et al.  Therapeutic Targeting of microRNAs in Cancer: Future Perspectives , 2015, Drug development research.

[94]  P. de Souza,et al.  Dual-drug delivery of curcumin and platinum drugs in polymeric micelles enhances the synergistic effects: a double act for the treatment of multidrug-resistant cancer. , 2015, Biomaterials science.

[95]  E. N. Lebedenko,et al.  Passive and active targeting of quantum dots for whole‐body fluorescence imaging of breast cancer xenografts , 2012, Journal of biophotonics.

[96]  Wei Zhao,et al.  Drug Delivery Using Nanoparticles for Cancer Stem-Like Cell Targeting , 2016, Front. Pharmacol..

[97]  Z. Su,et al.  One-Step Self-Assembling Nanomicelles for Pirarubicin Delivery To Overcome Multidrug Resistance in Breast Cancer. , 2016, Molecular pharmaceutics.

[98]  T. Saliev,et al.  Novel Small Molecule Inhibitors of Cancer Stem Cell Signaling Pathways , 2015, Stem Cell Reviews and Reports.

[99]  Xian‐Zheng Zhang,et al.  Tumor-Triggered Drug Release with Tumor-Targeted Accumulation and Elevated Drug Retention To Overcome Multidrug Resistance , 2016 .

[100]  Y. Reshetnyak Imaging Tumor Acidity: pH-Low Insertion Peptide Probe for Optoacoustic Tomography , 2015, Clinical Cancer Research.

[101]  A Facile Way of Modifying Layered Double Hydroxide Nanoparticles with Targeting Ligand-Conjugated Albumin for Enhanced Delivery to Brain Tumour Cells. , 2017, ACS applied materials & interfaces.

[102]  Tuck-yun Cheang,et al.  Anticancer drug-loaded multifunctional nanoparticles to enhance the chemotherapeutic efficacy in lung cancer metastasis , 2014, Journal of Nanobiotechnology.

[103]  Haixing Xu,et al.  Hyaluronic acid and Arg-Gly-Asp peptide modified Graphene oxide with dual receptor-targeting function for cancer therapy , 2017, Journal of biomaterials applications.

[104]  Baoan Chen,et al.  Poly(lactic acid) (PLA) based nanocomposites—a novel way of drug-releasing , 2007, Biomedical materials.

[105]  N. Cordes,et al.  The cancer cell adhesion resistome: mechanisms, targeting and translational approaches , 2017, Biological chemistry.

[106]  K. Somasundaram,et al.  Biotin Decorated Gold Nanoparticles for Targeted Delivery of a Smart-Linked Anticancer Active Copper Complex: In Vitro and In Vivo Studies. , 2016, Bioconjugate chemistry.

[107]  D. Engelman,et al.  pHLIP-FIRE, a Cell Insertion-Triggered Fluorescent Probe for Imaging Tumors Demonstrates Targeted Cargo Delivery In Vivo , 2014, ACS chemical biology.

[108]  Xin Luan,et al.  Engineering exosomes as refined biological nanoplatforms for drug delivery , 2017, Acta Pharmacologica Sinica.

[109]  Hong-Xia Wang,et al.  Combination therapy with epigenetic-targeted and chemotherapeutic drugs delivered by nanoparticles to enhance the chemotherapy response and overcome resistance by breast cancer stem cells. , 2015, Journal of controlled release : official journal of the Controlled Release Society.

[110]  Yanxiu Li,et al.  Tumor-targeted co-delivery of mitomycin C and 10-hydroxycamptothecin via micellar nanocarriers for enhanced anticancer efficacy , 2015 .

[111]  G. Kibria,et al.  Anti-tumor effect via passive anti-angiogenesis of PEGylated liposomes encapsulating doxorubicin in drug resistant tumors. , 2016, International journal of pharmaceutics.

[112]  Abraham H. Abouzeid,et al.  The effect of co-delivery of paclitaxel and curcumin by transferrin-targeted PEG-PE-based mixed micelles on resistant ovarian cancer in 3-D spheroids and in vivo tumors. , 2014, European journal of pharmaceutics and biopharmaceutics : official journal of Arbeitsgemeinschaft fur Pharmazeutische Verfahrenstechnik e.V.

[113]  R. Somani,et al.  Targeting Angiogenesis for Treatment of Human Cancer , 2013, Indian journal of pharmaceutical sciences.

[114]  Zhenzhong Zhang,et al.  In vitro and in vivo chemo-phototherapy of magnetic TiO2 drug delivery system formed by pH-sensitive coordination bond , 2016, Journal of biomaterials applications.

[115]  Min-hao Lv,et al.  A dual-targeting liposome conjugated with transferrin and arginine-glycine-aspartic acid peptide for glioma-targeting therapy , 2014, Oncology letters.

[116]  He Lian,et al.  Dual targeting folate-conjugated hyaluronic acid polymeric micelles for paclitaxel delivery. , 2011, International journal of pharmaceutics.

[117]  Dimitrios N. Bikiaris,et al.  Surface Modified Multifunctional and Stimuli Responsive Nanoparticles for Drug Targeting: Current Status and Uses , 2016, International journal of molecular sciences.

[118]  B. Seon,et al.  Facilitation of endoglin‐targeting cancer therapy by development/utilization of a novel genetically engineered mouse model expressing humanized endoglin (CD105) , 2015, International journal of cancer.

[119]  Liangzhu Feng,et al.  Drug‐induced co‐assembly of albumin/catalase as smart nano‐theranostics for deep intra‐tumoral penetration, hypoxia relieve, and synergistic combination therapy , 2017, Journal of controlled release : official journal of the Controlled Release Society.

[120]  Xun Hu,et al.  Down-regulation of P-glycoprotein expression in MDR breast cancer cell MCF-7/ADR by honokiol. , 2006, Cancer letters.

[121]  R. Zhang,et al.  RGD peptide conjugated liposomal drug delivery system for enhance therapeutic efficacy in treating bone metastasis from prostate cancer. , 2014, Journal of controlled release : official journal of the Controlled Release Society.

[122]  L. Qiu,et al.  Enhanced combination therapy effect on paclitaxel-resistant carcinoma by chloroquine co-delivery via liposomes , 2015, International journal of nanomedicine.

[123]  Yongjin Li,et al.  Enhanced degradation in nanocomposites of TiO2 and biodegradable polymer. , 2008, Environmental science & technology.

[124]  Rijun Gui,et al.  Facile synthesis of gold nanorods/hydrogels core/shell nanospheres for pH and near-infrared-light induced release of 5-fluorouracil and chemo-photothermal therapy. , 2015, Colloids and surfaces. B, Biointerfaces.

[125]  S. Mendrinos,et al.  The metabolic interactions between tumor cells and tumor-associated stroma (TAS) in prostatic cancer , 2012, Cancer biology & therapy.

[126]  D. Cunningham,et al.  Targeting Angiogenic Pathways in Colorectal Cancer: Complexities, Challenges and Future Directions. , 2016, Current drug targets.

[127]  Chen Li,et al.  Co-delivery of doxorubicin and curcumin by pH-sensitive prodrug nanoparticle for combination therapy of cancer , 2016, Scientific Reports.

[128]  Vladimir Torchilin,et al.  Enhanced Cytotoxicity of Folic Acid-Targeted Liposomes Co-Loaded with C6 Ceramide and Doxorubicin: In Vitro Evaluation on HeLa, A2780-ADR, and H69-AR Cells. , 2016, Molecular pharmaceutics.

[129]  Tom C. Karagiannis,et al.  Transferrin Receptor-Mediated Endocytosis: A Useful Target for Cancer Therapy , 2014, The Journal of Membrane Biology.

[130]  Z. Tian,et al.  Hybrid nanoparticles coated with hyaluronic acid lipoid for targeted co-delivery of paclitaxel and curcumin to synergistically eliminate breast cancer stem cells. , 2017, Journal of materials chemistry. B.

[131]  N. Dubrawsky Cancer statistics , 1989, CA: a cancer journal for clinicians.

[132]  G. Pagès,et al.  Targeting the pro-angiogenic forms of VEGF or inhibiting their expression as anti-cancer strategies , 2016, Oncotarget.

[133]  Qiang Zhang,et al.  The antitumor activity of tumor-homing peptide-modified thermosensitive liposomes containing doxorubicin on MCF-7/ADR: in vitro and in vivo , 2015, International journal of nanomedicine.

[134]  C. Brayton,et al.  Pharmacokinetics, microscale distribution, and dosimetry of alpha-emitter-labeled anti-PD-L1 antibodies in an immune competent transgenic breast cancer model , 2017, EJNMMI Research.

[135]  Aitziber L Cortajarena,et al.  Multifunctionalized iron oxide nanoparticles for selective drug delivery to CD44-positive cancer cells , 2016, Nanotechnology.

[136]  A. Misra,et al.  cRGD grafted liposomes containing inorganic nano-precipitate complexed siRNA for intracellular delivery in cancer cells. , 2014, Journal of controlled release : official journal of the Controlled Release Society.

[137]  A. Sneider,et al.  Engineering Remotely Triggered Liposomes to Target Triple Negative Breast Cancer , 2017, Oncomedicine.

[138]  A. Joe,et al.  Mechanisms of Disease: oncogene addiction—a rationale for molecular targeting in cancer therapy , 2006, Nature Clinical Practice Oncology.

[139]  Hong Sun,et al.  Co-delivery of doxorubicin and pH-sensitive curcumin prodrug by transferrin-targeted nanoparticles for breast cancer treatment. , 2017, Oncology reports.

[140]  S. Fiering,et al.  Antibody-mediated targeting of iron oxide nanoparticles to the folate receptor alpha increases tumor cell association in vitro and in vivo , 2015, International journal of nanomedicine.

[141]  Juan Wu,et al.  Synthesis and in vitro evaluation of pH-sensitive magnetic nanocomposites as methotrexate delivery system for targeted cancer therapy. , 2017, Materials science & engineering. C, Materials for biological applications.

[142]  Ming Qin,et al.  Significantly enhanced tumor cellular and lysosomal hydroxychloroquine delivery by smart liposomes for optimal autophagy inhibition and improved antitumor efficiency with liposomal doxorubicin , 2016, Autophagy.

[143]  Eun Seong Lee,et al.  Doxorubicin and paclitaxel co-bound lactosylated albumin nanoparticles having targetability to hepatocellular carcinoma. , 2017, Colloids and surfaces. B, Biointerfaces.

[144]  Bing Wang,et al.  Overexpression of ILK promotes temozolomide resistance in glioma cells. , 2017, Molecular medicine reports.

[145]  Qiqing Zhang,et al.  Development of both methotrexate and mitomycin C loaded PEGylated chitosan nanoparticles for targeted drug codelivery and synergistic anticancer effect. , 2014, ACS applied materials & interfaces.

[146]  Xiangyang Shi,et al.  RGD peptide-modified multifunctional dendrimer platform for drug encapsulation and targeted inhibition of cancer cells. , 2015, Colloids and surfaces. B, Biointerfaces.

[147]  Peng Zhang,et al.  Synergistic and complete reversal of the multidrug resistance of mitoxantrone hydrochloride by three-in-one multifunctional lipid-sodium glycocholate nanocarriers based on simultaneous BCRP and Bcl-2 inhibition , 2016, International journal of nanomedicine.

[148]  Yu Liang,et al.  Tumor-specific expression of shVEGF and suicide gene as a novel strategy for esophageal cancer therapy. , 2016, World journal of gastroenterology.

[149]  S. Lam,et al.  The Effect of Tumor Microenvironment on Autophagy and Sensitivity to Targeted Therapy in EGFR-Mutated Lung Adenocarcinoma , 2015, Journal of Cancer.

[150]  Liu Junbo,et al.  Preparation and properties evaluation of a novel pH-sensitive liposomes based on imidazole-modified cholesterol derivatives. , 2017, International journal of pharmaceutics.

[151]  Using PEGylated nano-liposomes to target tissue invaded by a foreign body , 2008, Journal of drug targeting.

[152]  Gang Zheng,et al.  Investigating the impact of nanoparticle size on active and passive tumor targeting efficiency. , 2014, ACS nano.