Application of nanoparticles in breast cancer treatment: a systematic review.

It is estimated that cancer is the second leading cause of death worldwide. The primary or secondary cause of cancer-related mortality for women is breast cancer. The main treatment method for different types of cancer is chemotherapy with drugs. Because of less water solubility of chemotherapy drugs or their inability to pass through membranes, their body absorbs them inadequately, which lowers the treatment's effectiveness. Drug specificity and pharmacokinetics can be changed by nanotechnology using nanoparticles. Instead, targeted drug delivery allows medications to be delivered to the targeted sites. In this review, we focused on nanoparticles as carriers in targeted drug delivery, their characteristics, structure, and the previous studies related to breast cancer. It was shown that nanoparticles could reduce the negative effects of chemotherapy drugs while increasing their effectiveness. Lipid-based nanocarriers demonstrated notable results in this instance, and some products that are undergoing various stages of clinical trials are among the examples. Nanoparticles based on metal or polymers demonstrated a comparable level of efficacy. With the number of cancer cases rising globally, many researchers are now looking into novel treatment approaches, particularly the use of nanotechnology and nanoparticles in the treatment of cancer. In order to help clinicians, this article aimed to gather more information about various areas of nanoparticle application in breast cancer therapy, such as modifying their synthesis and physicochemical characterization. It also sought to gain a deeper understanding of the mechanisms underlying the interactions between nanoparticles and biologically normal or infected tissues.

Design and synthesis of multi-targeted nanoparticles for gene delivery to breast cancer tissues.

Biocompatibility of nanoparticles is the most essential factor in their use in clinical applications. In this study, hyperbranched spermine (HS), hyperbranched spermine-polyethylene glycol-folic acid (HSPF), and hyperbranched spermine-polyethylene glycol-glucose (HSPG) were synthesized for DNA protection and gene delivery to breast cancer cells. The synthesis of HSPG and HSPF was confirmed using proton nuclear magnetic resonance (H-NMR), Fourier-transform infrared spectroscopy (FTIR), and thermogravimetric analysis (TGA) spectroscopy. The HS/DNA, HSPF/DNA, HSPG/DNA, and hyperbranched spermine-polyethylene glycol-folic acid/glucose/DNA (HSPFG/DNA) nanoparticles were prepared by combining different concentrations of HS, HSPF, and HSPG with the same amount of DNA. The ability of HS, HSPF, and HSPG to interact with DNA and protect it against plasm digestion was evaluated using agarose gel. Moreover, in vivo and in vitro biocompatibility of HSPF/DNA, HSPG/DNA, and HSPFG/DNA was investigated using MTT assay and calculating weight change and survival ratio of BALB/c mice, respectively. The results of agarose gel electrophoresis showed that HS, HSPF, and HSPG have the high ability to neutralize the negative charge of DNA and protect it against plasma degradation. The results of in vivo cytotoxicity assay revealed that the HSPF/DNA, HSPG/DNA, and HSPFG/DNA nanoparticles have good biocompatibility on female BALB/c mice. In vitro and in vivo transfection assays revealed that functionalization of the surface of HS using polyethylene glycol-folic acid (HSPF) and polyethylene glycol-glucose (HSPG) significantly increases gene delivery efficiency in vitro and in vivo. These results also showed that gene transfer using both HSPF and HSPG copolymers increases gene transfer efficiency compared to when only one of them is used. The HSPFG/DNA nanoparticles have a high potential for use in therapeutic applications because of their excellent biocompatibility and high gene transfer efficiency to breast cancer tissue.

Design and Invitro Characterization of Green Synthesized Magnetic Nanoparticles Conjugated with Multitargeted Poly Lactic Acid Copolymers for Co-delivery of siRNA and Paclitaxel.

BACKGROUND: The self-assembling of various amphipathic copolymers is a simple method that allows the preparation of complex nanoparticles with several useful properties. In the present study, the polylactic acid-polyethylene glycol-folate (PLA-PEG-FA) (PPF), PLA-PEG-T7 peptide (PPT) and PLA-Chitosan-Spermine (PCS) copolymers were synthesized separately. METHODS: These copolymers combined with Fe3O4 magnetic core and loaded with paclitaxel (PTX)/siRNA-FAM to form magnetic PCS/PPF/PPT/PTX/siRNA micelles (MPCSFT/PTX/siRNA) and were characterized using physicochemical and biological analysis. RESULTS: The results revealed that the MPCSPFT/PTX/siRNA had spherical morphology with particle size and zeta potential about 197 nm and -7.8 mV, respectively. Release assay was determined under neutral (pH=7.4) and acidic pH (pH=6) conditions to simulate PTX and siRNA release profile from MPCSPFT/PTX/siRNA micelles in normal and cancerous tissues. The ability of MPCSPFT for co-delivery of PTX and siRNA into MCF-7 cells was determined by MTT and flow cytometry tests, respectively. The results revealed that the release rate of siRNA and PTX from MPCSPFT/PTX/siRNA nanoparticles under an acidic environment (pH=6) was significantly higher than that of their release rate in a neutral medium (pH=7.4). CONCLUSION: Conjugation of both folic acid and T7-peptide on the surface of micelles compared to separate conjugation of one of these ligands, increased the efficiency of drug and siRNA delivery to breast cancer cells.

Design and preparation of a new multi-targeted drug delivery system using multifunctional nanoparticles for co-delivery of siRNA and paclitaxel.

Drug resistance is a great challenge in cancer therapy using chemotherapeutic agents. Administration of these drugs with siRNA is an efficacious strategy in this battle. Here, the present study tried to incorporate siRNA and paclitaxel (PTX) simultaneously into a novel nanocarrier. The selectivity of carrier to target cancer tissues was optimized through conjugation of folic acid (FA) and glucose (Glu) onto its surface. The structure of nanocarrier was formed from ternary magnetic copolymers based on FeCo-polyethyleneimine (FeCo-PEI) nanoparticles and polylactic acid-polyethylene glycol (PLA-PEG) gene delivery system. Biocompatibility of FeCo-PEI-PLA-PEG-FA(NPsA), FeCo-PEI-PLA-PEG-Glu (NPsB) and FeCo-PEI-PLA-PEG-FA/Glu (NPsAB) nanoparticles and also influence of PTX-loaded nanoparticles on in vitro cytotoxicity were examined using MTT assay. Besides, siRNA-FAM internalization was investigated by fluorescence microscopy. The results showed the blank nanoparticles were significantly less cytotoxic at various concentrations. Meanwhile, siRNA-FAM/PTX encapsulated nanoparticles exhibited significant anticancer activity against MCF-7 and BT-474 cell lines. NPsAB/siRNA/PTX nanoparticles showed greater effects on MCF-7 and BT-474 cells viability than NPsA/siRNA/PTX and NPsB/siRNA/PTX. Also, they induced significantly higher anticancer effects on cancer cells compared with NPsA/siRNA/PTX and NPsB/siRNA/PTX due to their multi-targeted properties using FA and Glu. We concluded that NPsAB nanoparticles have a great potential for co-delivery of both drugs and genes for use in gene therapy and chemotherapy.

Novel multi-targeted nanoparticles for targeted co-delivery of nucleic acid and chemotherapeutic agents to breast cancer tissues.

Selective delivery of drugs to damaged tissues favorable to reduce the side effects while enhancing the therapeutic efficacy. The purpose of the present study was the design and synthesis of multi-targeted nanoparticles for co-delivery of both drug and nucleic acid to cancer cells. In this study biocompatible compounds such as chitosan, polyethylene glycol (PEG), polycaprolactone (PCL), folic acid (FA) and glucose (Glu) were used to synthesize the FA-PEG-Chitosan-PCL-Chitosan-PEG-FA (FPCP) and Glu-PEG-Chitosan-PCL-Chitosan-PEG-Glu (GPCP) copolymers. Then, paclitaxel (PTX), oleic acid-coated FeCO nanoparticles (FeCO-OA) and 6-carboxy-fluorescein phosphoramidate (FAM)-labeled siRNA (siRNA-FAM) were encapsulated into either FPCP or GPCP, or both FPCP and GPCP (GFPCP), using the solvent evaporation technique. In vitro and in vivo biocompatibility and drug delivery efficiency of FPCP/FeCO-OA/PTX, GPCP/FeCO-OA/PTX and GFPCP/FeCO-OA/PTX nanoparticles were determined by recording the MTT assay, weight loss and tumor volume respectively. In addition, the ability of FPCP/FeCO-OA/siRNA-FAM, GPCP/FeCO-OA/siRNA-FAM, and GFPCP/FeCO-OA/siRNA-FAM gene transfer was determined using flow cytometry analysis. Moreover, the effects of applying an external magnetic field to the tumor site on the efficiency of drug delivery using FPCP/FeCO-OA/siRNA-FAM/PTX (NPsA), GPCP/FeCO-OA/siRNA-FAM/PTX (NPsB) and GFPCP/FeCO-OA/siRNA-FAM/PTX (NPsAB) were also investigated in the present study. No significant toxicity was observed for the FPCP and GPCP copolymers. Meanwhile, PTX encapsulated FPCP, GPCP and GFPCP exhibited greater anticancer activities against MCF-7 cells. The in vivo and in vitro results showed that the nanoparticles targeted with both folic acid and glucose increased drug and RNA transfer efficiency compared to when folic acid or glucose alone used. Also, the efficiency of PTX and siRNA-FAM delivery to tumor tissues by nanoparticles increased significantly by applying an external magnetic field to the tumor area. The hydrophobic interactions between different amphipathic copolymers in appropriate is an efficient and easy technique to synthesize complex and multifunctional nanoparticles.

Preparation and Characterization of PLA-PEG-PLA/PEI/DNA Nanoparticles for Improvement of Transfection Efficiency and Controlled Release of DNA in Gene Delivery Systems.

Tri-block poly (lactide) poly(ethylene glycol) poly(lactide) (PLA-PEG-PLA) copolymers are among the most attractive nano-carriers for gene delivery into mammalian cells, due to their biocompatibility and biodegradability properties. However, the low efficiency of the gene delivery by these copolymers is an obstacle to gene therapy. Here, we have investigated nanoparticles formulated using the polyethylenimine (PEI) associated with PLA-PEG-PLA copolymer for efficient DNA encapsulation and delivery. PLA-PEG-PLA/DNA and PLA-PEG-PLA/PEI/DNA nanoparticles with different concentrations of PEI were prepared by the double emulsion-solvent evaporation technique. PLA-PEG-PLA/PEI/DNA were characterized for particle size, zeta potential, morphology, biocompatibility, DNA protection, DNA release, and their ability for gene delivery into MCF-7 cells. We found that enhancing the mass ratio of PEI: (PLA-PEG-PLA) (w/w%) in the PLA-PEG-PLA/PEI/DNA nanoparticles results in an increase in particles size, zeta potential, encapsulation efficiency, and DNA release. The electrophoretic analysis confirmed that the PLA-PEG-PLA and PLA-PEG-PLA/PEI could protect DNA from ultrasound damage and nuclease degradation. MTT assay showed that the PLA-PEG-PLA/PEI/DNA had low cytotoxicity than PEI complexes. The potential of PLA-PEG-PLA/PEI/DNA nanoparticles with different concentrations of PEI as a non-viral gene delivery vector for transferring pEGFP-N1 to MCF-7 cells was examined by fluorescent microscopy and flow cytometry. The flow cytometry analysis revealed that by increasing the mass ratio of PEI: (PLA-PEG-PLA) (w/w%) in PLA-PEG-PLA/PEI/DNA nanoparticles, the efficiency of the gene delivery into MCF-7 cells was improved. The results also demonstrated that PLA-PEG-PLA/PEI/DNA nanoparticles in the serum medium improved the efficiency of gene delivery more than two-fold, compared to PEI/DNA complex.