Multitargeted Nanoparticles Deliver Synergistic Drugs across the Blood–Brain Barrier to Brain Metastases of Triple Negative Breast Cancer Cells and Tumor‐Associated Macrophages

Zhang, Tian; Lip, HoYin; He, Chunsheng; Cai, Ping; Wang, Zhigao; Henderson, Jeffrey T.; Rauth, Andrew M.; Wu, Xiao Yu

doi:10.1002/adhm.201900543

Cited by 59 publications

(58 citation statements)

References 70 publications

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“…All quantitative results were acquired from triplicate samples and data were expressed as the mean ± standard deviation (SD). Statistical analysis was performed using analysis of variance (ANOVA) and p < 0.05 was considered as the criterion of significance, as previously reported [37][38][39].…”

Section: Discussionmentioning

confidence: 99%

Salinomycin-Loaded Iron Oxide Nanoparticles for Glioblastoma Therapy

et al. 2020

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Salinomycin is an antibiotic introduced recently as a new and effective anticancer drug. In this study, magnetic iron oxide nanoparticles (IONPs) were utilized as a drug carrier for salinomycin for potential use in glioblastoma (GBM) chemotherapy. The biocompatible polyethylenimine (PEI)-polyethylene glycol (PEG)-IONPs (PEI-PEG-IONPs) exhibited an efficient uptake in both mouse brain-derived microvessel endothelial (bEnd.3) and human U251 GBM cell lines. The salinomycin (Sali)-loaded PEI-PEG-IONPs (Sali-PEI-PEG-IONPs) released salinomycin over 4 days, with an initial release of 44% ± 3% that increased to 66% ± 5% in acidic pH. The Sali-IONPs inhibited U251 cell proliferation and decreased their viability (by approximately 70% within 48 h), and the nanoparticles were found to be effective in reactive oxygen species-mediated GBM cell death. Gene studies revealed significant activation of caspases in U251 cells upon treatment with Sali-IONPs. Furthermore, the upregulation of tumor suppressors (i.e., p53, Rbl2, Gas5) was observed, while TopII, Ku70, CyclinD1, and Wnt1 were concomitantly downregulated. When examined in an in vitro blood–brain barrier (BBB)-GBM co-culture model, Sali-IONPs had limited penetration (1.0% ± 0.08%) through the bEnd.3 monolayer and resulted in 60% viability of U251 cells. However, hyperosmotic disruption coupled with an applied external magnetic field significantly enhanced the permeability of Sali-IONPs across bEnd.3 monolayers (3.2% ± 0.1%) and reduced the viability of U251 cells to 38%. These findings suggest that Sali-IONPs combined with penetration enhancers, such as hyperosmotic mannitol and external magnetic fields, can potentially provide effective and site-specific magnetic targeting for GBM chemotherapy.

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Section: Discussionmentioning

confidence: 99%

Salinomycin-Loaded Iron Oxide Nanoparticles for Glioblastoma Therapy

et al. 2020

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“…Meanwhile, this nanosystem also reduced the cardiotoxicity associated with the DOX/MMC combination. 118 Because many nanocarriers and targeting moieties can bind nonspecifically to tumor cells, as well as to extracellular and intravascular components, developing effective nano-drug preparations targeting tumor cells has always been challenging. The recently developed "DART" nanoparticles could effectively ameliorate this problem.…”

Section: Potential Precision Anti-tnbcbm Therapy: Nanotechnologymentioning

confidence: 99%

Understanding Patterns of Brain Metastasis in Triple-Negative Breast Cancer and Exploring Potential Therapeutic Targets

et al. 2021

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Triple-negative breast cancer (TNBC) is a highly malignant subtype of breast cancer. High invasiveness and heterogeneity, as well as a lack of drug targets, are the main factors leading to poor prognosis. Brain metastasis (BM) is a serious event threatening the life of breast cancer patients, especially those with TNBC. Compared with that for hormone receptor-positive and HER2-positive breast cancers, TNBC-derived BM (TNBCBM) occurs earlier and more frequently, and has a worse prognosis. There is no standard treatment for BM to date, and one is urgently required. In this review, we discuss the current knowledge regarding the developmental patterns of TNBCBM, focusing on the key events in BM formation. Specifically, we consider (i) the nature and function of TNBC cells; (ii) how TNBC cells cross the blood-brain barrier and form a fenestrated, more permeable bloodtumor barrier; (iii) the biological characteristics of TNBCBM; and (iv) the infiltration and colonization of the central nervous system (CNS) by TNBC cells, including the establishment of premetastatic niches, immunosurveillance escape, and metabolic adaptations. We also discuss putative therapeutic targets and precision therapy with the greatest potential to treat TNBCBM, and summarize the relevant completed and ongoing clinical trials. These findings may provide new insights into the prevention and treatment of BM in TNBC patients.

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“…In addition, co-encapsulation enables unfluctuating and concurrent delivery of drug combinations, preserving the integration of different drugs’ pharmacokinetics by precise synergistic drug ratios [ 32 , 33 ] or controlling sequenced drug release [ 34 ]. Many interesting solutions in this field are described in literature [ 29 , 35 , 36 , 37 , 38 , 39 , 40 , 41 ], e.g., Vyxeos ® , the first in a new class of liposomes approved in 2017 by the FDA and in 2018 by the EMA, enables the simultaneous delivery of two drugs, cytarabine and daunorubicin, in a fixed 5:1 molar ratio to increase treatment efficacy of acute myeloid leukemia (AML) with a lower cumulative dose [ 42 ]. The major challenge of aforementioned strategies is that safety and efficacy of drugs have to be proven for each individual drug, as well as for their combination.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Drugs—A Strategy for Overcoming Anticancer Drug Resistance?

2021

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Despite enormous progress in the treatment of many malignancies, the development of cancer resistance is still an important reason for cancer chemotherapy failure. Increasing knowledge of cancers’ molecular complexity and mechanisms of their resistance to anticancer drugs, as well as extensive clinical experience, indicate that an effective fight against cancer requires a multidimensional approach. Multi-target chemotherapy may be achieved using drugs combination, co-delivery of medicines, or designing hybrid drugs. Hybrid drugs simultaneously targeting many points of signaling networks and various structures within a cancer cell have been extensively explored in recent years. The single hybrid agent can modulate multiple targets involved in cancer cell proliferation, possesses a simpler pharmacokinetic profile to reduce the possibility of drug interactions occurrence, and facilitates the process of drug development. Moreover, a single medication is expected to enhance patient compliance due to a less complicated treatment regimen, as well as a diminished number of adverse reactions and toxicity in comparison to a combination of drugs. As a consequence, many efforts have been made to design hybrid molecules of different chemical structures and functions as a means to circumvent drug resistance. The enormous number of studies in this field encouraged us to review the available literature and present selected research results highlighting the possible role of hybrid drugs in overcoming cancer drug resistance.

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Multitargeted Nanoparticles Deliver Synergistic Drugs across the Blood–Brain Barrier to Brain Metastases of Triple Negative Breast Cancer Cells and Tumor‐Associated Macrophages

Cited by 59 publications

References 70 publications

Salinomycin-Loaded Iron Oxide Nanoparticles for Glioblastoma Therapy

Salinomycin-Loaded Iron Oxide Nanoparticles for Glioblastoma Therapy

Understanding Patterns of Brain Metastasis in Triple-Negative Breast Cancer and Exploring Potential Therapeutic Targets

Hybrid Drugs—A Strategy for Overcoming Anticancer Drug Resistance?

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