Breast Cancer Gene Therapy Research Articles

Synergistic pH-responsive MUC-1 aptamer-conjugated Ag/MSN Janus nanoparticles for targeted chemotherapy, photothermal therapy, and gene therapy in breast cancer

Drug resistance in cancer treatment, primarily attributed to the overexpression of the multidrug resistance (MDR) gene, significantly hampers the effectiveness of chemotherapy. This mechanism, driven by the increased production of P-glycoprotein (P-gp) efflux pumps, highlights the urgent need for innovative strategies to combat drug resistance in cancer patients. This study explores the application of antisense technology to suppress MDR gene expression, while addressing the challenges of instability and limited cellular uptake associated with antisense oligonucleotides. We synthesized Janus silver-mesoporous silica nanoparticles (Ag/MSN JNPs) using a sol-gel method, characterized by transmission electron microscopy (TEM) and dynamic light scattering (DLS), revealing uniformly sized, dumbbell-shaped nanoparticles with an average size of 285 ± 5.12 nm. Doxorubicin (DOX) was loaded into the porous structure of the mesoporous silica, and JNPs were functionalized with chitosan (CS) to incorporate P-gp antisense and a MUC-1 aptamer, serving as a pH-responsive gatekeeper. Our findings indicate that the Ap-As-DOX-JNPs achieved a remarkable 89 ± 0.59 % cell death in drug-resistant MCF-7/ADR cells after 48 h, alongside an 80 % reduction in P-gp expression. The combination of DOX, antisense technology, and photothermal therapy utilizing these JNPs demonstrates a promising strategy to effectively overcome drug resistance. Notably, normal MCF-7 cells exhibited reduced viability from 39.11 ± 1.12 % to 30.05 ± 1.07 % when treated with DOX-JNPs under near-infrared (NIR) irradiation. These results underscore the potential of utilizing MUC-1 aptamer-conjugated Janus nanoparticles in conjunction with chitosan as a gatekeeper to enhance the efficacy of chemotherapy, photothermal therapy, and gene therapy in overcoming multidrug resistance in cancer treatment.

Combination of magnetic hyperthermia and gene therapy for breast cancer.

This study presented a novel breast cancer therapy model that uses magnetic field-controlled heating to trigger gene expression in cancer cells. We created silica- and amine-modified superparamagnetic nanoparticles (MSNP-NH2) to carry genes and release heat under an alternating current (AC) magnetic field. The heat-inducible expression plasmid(pHSP-Azu) was designed to encode anti-cancer azurin and was delivered by magnetofection. MCF-7 cells demonstrated over 93% cell viability and 12% transfection efficiency when exposed to 75µg/ml of MSNP-NH2, 3µg of DNA, and PEI at a 0.75 PEI/DNA ratio (w: w), unlike non-tumorigenic cells (MCF-10A). Magnetic hyperthermia (MHT) increased azurin expression by heat induction, leading to cell death in dual ways. The combination of MHT and heat-regulated azurin expression induced cell death, specifically in cancer cells, while having negligible effects on MCF-10A cells. The proposed strategy clearly shows that simultaneous use of MHT and MHT-induced azurin gene expression may selectively target and kill cancer cells, offering a promising direction for cancer therapy.

Exploiting a tumor softening targeted bomb for mechanical gene therapy of chemoresistant Triple-Negative breast cancer

Triple-negative breast cancer (TNBC)-the most aggressive and refractory subtype of breast cancer-plagues many patients. The tumor physical microenvironment (TPME) is characterized by altered stromal composition and extracellular matrix (ECM), which may contribute to tissue stiffness and compromise therapeutic efficacy. Here, based on clinical data analysis and preclinical model validation, we discover that chemoresistant TNBC tends to have a stiffer TPME with a more aggressive genomic landscape, in which lysyl oxidase (LOX) exerts pivotal effects. Anlotinib (An), a multi-targeted tyrosine kinase inhibitor, has great promising potential in the treatment of TNBC. In this regard, we developed a tumor-softening nanobomb (An&siLOX@NPs) that remodels TPME by co-delivering small interfering siRNAs silencing LOX and the anti-angiogenic drug, anlotinib (An). The improved cytosolic delivery of siLOX enables TPME remodeling via reducing deposition and cross-linking between collagen and fibronectin, thereby promoting enrichment of An to improve its therapeutic outcomes. In chemoresistant TNBC, we confirm the An&siLOX@NPs nanobomb-mediated mechanical gene therapy results in obvious inhibition of local tumor outgrowth and prolongs survival. Additionally, softened TPME reactivates intratumoral immune milieu to bolster sensitivity to anti-PD-L1 immunotherapy, completely curing 33.3% of the metastatic tumors, further generating a synergistic anti-tumor efficacy. Collectively, our mechanical gene therapy strategy represents a highly efficient, safe, and versatile anti-drug resistance modality, which not only can solve the snag problem of TNBC treatment but also provides a new demonstration for other tumor treatments.

Stimuli-sensitive Chitosan-based Nanosystems-immobilized Nucleic Acids for Gene Therapy in Breast Cancer and Hepatocellular Carcinoma.

Chitosan-based nanoparticles have emerged as a promising tool in the realm of cancer therapy, particularly for gene delivery. With cancer being a prevalent and devastating disease, finding effective treatment options is of utmost importance. These nanoparticles provide a unique solution by encapsulating specific genes and delivering them directly to cancer cells, offering immense potential for targeted therapy. The biocompatibility and biodegradability of chitosan, a naturally derived polymer, make it an ideal candidate for this purpose. The nanoparticles protect the genetic material during transportation and enhance its cellular uptake, ensuring effective delivery to the site of action. Furthermore, the unique properties of chitosan-based nanoparticles allow for the controlled release of genes, maximizing their therapeutic effect while minimizing adverse effects. By advancing the field of gene therapy through the use of chitosan-based nanoparticles, scientists are making significant strides toward more humane and personalized treatments for cancer patients.

Inducible caspase 9-mediated suicide gene therapy using AAV6 vectors in a murine model of breast cancer

Breast carcinoma has one of the highest incidence rates (11.7%), with significant clinical heterogeneity. Although conventional chemotherapy and surgical resection are the current standard of care, the resistance and recurrence, after these interventions, necessitate alternate therapeutic approaches. Cancer gene therapy for breast cancer with the suicide gene is an attractive option due to their directed delivery into the tumor. In this study, we have developed a novel treatment strategy against breast cancer with recombinant adeno-associated virus (AAV) serotype 6 vectors carrying a suicide gene, inducible Caspase 9 (iCasp9). Upon treatment with AAV6-iCasp9 vectors and the chemical inducer of dimerizer, AP20187, the viability of murine breast cancer cells (4T1) was significantly reduced to ∼40%-60% (mock control 100%). Following intratumoral delivery of AAV6-iCasp9 vectors in an orthotopic breast cancer mouse model, we observed a significant increase in iCasp9 transgene expression and a significant reduction in tumor growth rate. At the molecular level, immunohistochemical analysis demonstrated subsequent activation of the effector caspase 3 and cellular death. These data highlight the potential of AAV6-iCasp9-based suicide gene therapy for aggressive breast cancer in patients.

Designing Nanomedicines for Breast Cancer Therapy.

In 2020, breast cancer became the most diagnosed cancer worldwide. Conventional chemotherapies have major side effects due to their non-specific activities. Alternatively, short interfering RNA(siRNA)-carrying nanoparticles (NPs) have a high potential to overcome this non-specificity. Lipid-substituted polyethyleneimine (PEI) polymers (lipopolymers) have been reported as efficient non-viral carriers of siRNA. This study aims to engineer novel siRNA/lipopolymer nanocomplexes by incorporating anionic additives to obtain gene silencing through siRNA activity with minimal nonspecific toxicity. We first optimized our polyplexes in GFP+ MDA-MB-231 cells to effectively silence the GFP gene. Inclusion of phosphate buffer with pH 8.0 as complex preparation media and N-Lauroylsarcosine Sodium Salt as additive, achieved ~80% silencing with the least amount of undesired cytotoxicity, which was persistent for at least 6 days. The survivin gene was then selected as a target in MDA-MB-231 cells since there is no strong drug (i.e., small organic molecule) for inhibition of its oncogenic activity. The qRT-PCR, flow cytometry analysis and MTT assay revealed >80% silencing, ~95% cell uptake and >70% cell killing by the same formulation. We conclude that our lipopolymer can be further investigated as a lead non-viral carrier for breast cancer gene therapy.

Breast Cancer: An Overview of Current Therapeutic Strategies, Challenge, and Perspectives.

Breast cancer is the most commonly diagnosed cancer and the leading cause of death among female patients, which seriously threatens the health of women in the whole world. The treatments of breast cancer require the cooperation of a multidisciplinary setting and taking tumor load and molecular makers into account. For early breast cancer, breast-conserving surgery with radiotherapy or mastectomy alone remains the standard management, and the administration of adjuvant systemic therapy is decided by the status of lymph nodes, hormone receptors, and human epidermal growth factor receptor-2. For metastatic breast cancer, the goal of treatments is to prolong survival and maintain quality of life. This review will present the current advances and controversies of surgery, chemotherapy, radiotherapy, endocrine therapy, targeted therapy, immunotherapy, gene therapy, and other innovative treatment strategies in early-stage and metastatic breast cancer.

Profiling of microRNA as a tool to introduce rAAV vectors in gene therapy of breast cancer: A preliminary report.

Despite the wide range of diagnostic and therapeutic methods, breast cancer is responsible for many deaths each year. One of the original and novel cancer therapeutic approaches is gene therapy based on recombinant adeno-associated viral vectors. Among the molecular factors with the potential to become useful diagnostic biomarkers, microRNA (miRNA) molecules are being considered for personalized therapies. The aim of the study was to examine the utility of miRNA profiling in the design of personalized recombinant adeno-associated virus (rAAV)-based gene therapy for breast cancer patients. The analysis of 754 miRNAs in 7 breast cancer samples and control samples was performed using real-time polymerase chain reaction (PCR) based on TaqMan® Low-density Array (TLDA) cards. Online repositories were used to explore the relationship between miRNAs and genes encoding rAAV receptors (KIAA0319L, HSPG2, FGFR1, c-MET, PDGFRA, ITGB5, and RPSA). Then, we performed a comparative analysis of the results to examine the possibility of using miRNA profiling in the design of rAAV-based therapeutic protocols. Fifty-two percent of tested miRNAs were noted in at least 1 analyzed breast cancer and control tissue. Thirteen miRNAs were selected due to being outliers in the tested samples. In total, 155 miRNAs targeted genes encoding rAAV receptors in the tested samples (29 miRNAs for KIAA0319L, 60 miRNAs for c-MET, 31 miRNAs for HSPG2, 43 miRNAs for FGFR1, 36 miRNAs for PDGFRA, 18 miRNAs for RPSA, and 25 miRNAs for ITGB5). The expression of the selected miRNAs was not homogeneous across the 7 samples. Profiling of microRNA could be a significant factor in the design of rAAV-based personalized gene therapy for breast cancer patients.

A Review of Different Types of Liposomes and Their Advancements as a Form of Gene Therapy Treatment for Breast Cancer.

Breast cancer incidence and mortality rates have increased exponentially during the last decade, particularly among female patients. Current therapies, including surgery and chemotherapy, have significant negative physical and mental impacts on patients. As a safer alternative, gene therapy utilising a therapeutic gene with the potential to treat various ailments is being considered. Delivery of the gene generally utilises viral vectors. However, immunological reactions and even mortality have been recorded as side effects. As a result, non-viral vectors, such as liposomes, a system composed of lipid bilayers formed into nanoparticles, are being studied. Liposomes have demonstrated tremendous potential due to their limitless ability to combine many functions into a system with desirable characteristics and functionality. This article discusses cationic, anionic, and neutral liposomes with their stability, cytotoxicity, transfection ability, cellular uptake, and limitation as a gene carrier suitable for gene therapy specifically for cancer. Due to the more practical approach of employing electrostatic contact with the negatively charged nucleic acid and the cell membrane for absorption purposes, cationic liposomes appear to be more suited for formulation for gene delivery and therapy for breast cancer treatment. As the other alternatives have numerous complicated additional modifications, attachments need to be made to achieve a functional gene therapy system for breast cancer treatment, which were also discussed in this review. This review aimed to increase understanding and build a viable breast cancer gene therapy treatment strategy.

Erratum to "Tumor Microenvironment-Specific Chemical Internalization for Enhanced Gene Therapy of Metastatic Breast Cancer".

Erratum to "Tumor Microenvironment-Specific Chemical Internalization for Enhanced Gene Therapy of Metastatic Breast Cancer".

Reduced polydopamine coated graphene for delivery of Hset1 antisense as A photothermal and gene therapy of breast cancer

Breast cancer is the most prevalent type of cancer in women; hence, many researches have been focused on developing effective treatment protocols. In this study, a novel nanocarrier was fabricated for gene and photothermal combination cancer therapy by conjugating histone methyltransferase complex subunit SET1 (hSET1) on reduced polydopamine coated graphene oxide nanosheets (rGO-PDA).The rGO-PDA nanocarriers provide higher near-infrared absorption and further integrating with hSET1 antisense as an anticancer gene that down-regulates the amount of hSET1 overexpressed and suppresses the proliferation of cancer cells.The nanoplatform was prepared by polymerizing of dopamine, a mussel adhesive protein, on graphene oxide nanosheets in alkaline media, followed by conjugation of hSET1 antisense on rGO-PDA nanocarriers which was examined by gel retardation assay. After Laser irradiation, the amount of hSET1 was estimated in overexpressed cells treated with this formulation by real-time reverse transcription-polymerase chain reaction (RT-PCR).The size and zeta potential of prepared nanocarriers were 140 nm and −29.4 mv respectively. In vitro cellular tests confirmed that the prepared nanoplatform was biocompatible with no cell toxicity. The nanocarrier as a photothermal agent generating hyperthermia, led to a better release of hSET1 antisense under NIR (near-infrared) and more apoptosis of cancer cells and RT-PCR implied a considerable decrease of hSET1 expression. Outstanding photothermal conversion and suitable potential of rGO-PDA for interaction with oligonucleotides is expected as a suitable system for gene delivery and photoresponsive therapy of solid tumors simultaneously.

Amphiphilic cationic triblock polymers for p53-mediated triple-negative breast cancer gene therapy

Polycationic vectors are a promising class of gene delivery systems. To improve delivery efficiency and reduce cytotoxicity, hydrophobic modification has been proposed as an effective way. Herein, we synthesized a class of terpolymer vectors with various hydrophobicities as well as multiple biodegradable disulfide bonds and cationic side chains. The chemical structure and hydrophobic modification ratio of polymers were characterized. The amphiphilic vectors were able to condense pDNA to form flexible and uniform nanoparticles with a size of 60–85 nm. The shielding effect of hydrophobic side chains led to a lower zeta potential and reduced cytotoxicity. The endocytosis efficiency of amphiphilic vectors was significantly increased and the endocytosis pathway shifted from mainly via the clathrin pathway to clathrin/caveolae/lipid raft co-mediated endocytosis. The amphiphilic vectors demonstrated significantly higher transfection efficiency. In addition, the hydrophobic structural domain of polymers could improve serum stability, alleviating the serum inhibition commonly seen in cationic polymers. Then, we tested the tumor-suppressor gene wtp53 delivered by the amphiphilic vectors in triple-negative breast cancer models both in vitro and in vivo. Tumor cell cycle arrest and apoptosis were triggered through the regulation of downstream cell cycle proteins and apoptosis proteins, inhibiting tumor growth with an excellent safety profile.

Poly(N-vinylpyrrolidone)-block-Poly(dimethylsiloxane)-block-Poly(N-vinylpyrrolidone) Triblock Copolymer Polymersomes for Delivery of PARP1 siRNA to Breast Cancers.

Nearly 20% of HER2-positive breast cancers develop resistance to HER2-targeted therapies requiring the use of advanced therapies. Silencing RNA therapy may be a powerful modality for treating resistant HER2 cancers due to its high specificity and low toxicity. However, the systemic administration of siRNAs requires a safe and efficient delivery platform because of siRNA's low stability in physiological fluids, inefficient cellular uptake, immunoreactivity, and rapid clearance. We have developed theranostic polymeric vesicles to overcome these hurdles for encapsulation and delivery of small functional molecules and PARP1 siRNA for in vivo delivery to breast cancer tumors. The 100 nm polymer vesicles were assembled from biodegradable and non-ionic poly(N-vinylpyrrolidone)14-block-poly(dimethylsiloxane)47-block-poly(N-vinylpyrrolidone)14 triblock copolymer PVPON14-PDMS47-PVPON14 using nanoprecipitation and thin-film hydration. We demonstrated that the vesicles assembled from the copolymer covalently tagged with the Cy5.5 fluorescent dye for in vivo imaging could also encapsulate the model drug with high loading efficiency (40%). The dye-loaded vesicles were accumulated in tumors after 18 h circulation in 4TR breast tumor-bearing mice via passive targeting. We found that PARP1 siRNA encapsulated into the vesicles was released intact (13%) into solution by the therapeutic ultrasound treatment as quantified by gel electrophoresis. The PARP1 siRNA-loaded polymersomes inhibited the proliferation of MDA-MB-361TR cells by 34% after 6 days of treatment by suppressing the NF-kB signaling pathway, unlike their scrambled siRNA-loaded counterparts. Finally, the treatment by PARP1 siRNA-loaded vesicles prolonged the survival of the mice bearing 4T1 breast cancer xenografts, with the 4-fold survival increase, unlike the untreated mice after 3 weeks following the treatment. These biodegradable, non-ionic PVPON14-PDMS47-PVPON14 polymeric nanovesicles capable of the efficient encapsulation and delivery of PARP1 siRNA to successfully knock down PARP1 in vivo can provide an advanced platform for the development of precision-targeted therapeutic carriers, which could help develop highly effective drug delivery nanovehicles for breast cancer gene therapy.

Laser activatable nanographene colloids for chemo-photothermal combined gene therapy of triple-negative breast cancer

This investigation reports the green approach for developing laser activatable nanoscale-graphene colloids (nGC-CO-FA) for chemo-photothermal combined gene therapy of triple-negative breast cancer (TNBC). The nano colloid was found to be nanometric as characterized by SEM, AFM, and zeta sizer (68.2 ± 2.1 nm; 13.8 ± 1.2 mV). The doxorubicin (Dox) loaded employing hydrophobic interaction/π-π stacking showed >80% entrapment efficiency with a sustained pH-dependent drug release profile. It can efficiently incorporate siRNA and Dox and successfully co-localize them inside TNBC cells to obtain significant anticancer activity as evaluated using CCK-8 assay, apoptosis assay, cell cycle analysis, cellular uptake, fluorescence assay, endosomal escape study, DNA content analysis, and gene silencing efficacy studies. nGC-CO-FA/Dox/siRNA released the Dox in temperature- and a pH-responsive manner following NIR-808 laser irradiation. The synergistic photo-chemo-gene therapy using near infrared-808 nm laser (NIR-808) irradiation was found to be more effective as compared to without NIR-808 laser-treated counterparts (∆T: 37 ± 1.1 °C → to 49.2 ± 3.1 °C; 10 min; 0.5 W/cm2), suggesting the pivotal role of photothermal combined gene-therapy in the treatment of TNBC.

MiR-622 Induces Breast Cancer Cell MCF-7 Proliferation, Migration, and Invasion by Directly Negatively Targeting EYA1

Breast cancer is the most common female cancer in the world. Breast cancer patients are currently treated with a combination of surgery, chemotherapy, radiotherapy, and targeted therapy, but the 5-year overall survival rate is still low. Therefore, we plan to explore the potential interaction mechanism between miR-622 and EYA1 in the breast cancer cells and their effect on proliferation, migration, and invasion of breast cancer, to lay a foundation for the gene therapy of breast cancer and improve the therapeutic effect. This study found that miR-622 was highly expressed in breast cancer cell lines, while EYA1 was poorly. In MCF-7 cell line, miR-622 had the highest expression level, while EYA1 had the lowest. Besides, the bioinformatics analysis showed that EYA1 possesses putative miR-622 binding sites within its 3 ′ UTR. The increased miR-622 significantly enhanced the proliferation, migration, and invasion of MCF-7 cell line and inhibited luciferase reporter activity in the 3 ′ UTR of EYA1-WT. When upregulating the expression of miR-622, the mRNA and protein expression levels of EYA1 were significantly decreased. We also found that the silencing of EYA1 promoted the proliferation, migration, and invasion of breast cancer MCF-7 cell line. These results indicate that miRNA-622 plays a tumor-promoting role in breast cancer through targeted negative regulation of EYA1, suggesting that miRNA-622 may become a potential target for breast cancer treatment.

Gene mutation can be treated in breast cancer by gene therapy

Breast cancer or carcinoma is mostly characterized by a series of genetic mutations or gene mutations and is therefore ideally place for gene therapy intervention. The aim of gene therapy is to deliver a nucleic acid based drug to either correct or destroy the cells harbouring the genetic aberration. More recently cancer gene therapy has evolved to also encompass delivery of RNA interference technologies, as well as cancer DNA vaccines. However the bottleneck in creating such nucleic acid pharmaceuticals lies in the delivery. Deliverability of DNA is limited as it is circulating nucleases, therefore numerous strategies have been employed to aid with biological transport. This review will discuss some of viral and non viral approaches to breast to breast cancer therapy an present the findings of clinical trials of these therapies in breast cancer patients. Also detailed are some of the most recent developments in non viral approaches to targeting in breast cancer gene therapy. This include transcriptional control, and the development of recombinant, multifunctional bio- inspired system.

Use of cellular exosomes as a new carrier in breast cancer gene therapy.

Breast cancer is recognized as a major clinical challenge in gynecological diseases worldwide. Exosomes are small vesicles derived from multicellular bodies that are secreted by many cells into the extracellular environment and thus participate in intercellular communication through the transfer of genetic information such as encoded and non-encoded RNAs to target cells. Tumor-derived exosomes are thought to be a rich source of microRNAs (miRs) that can regulate the function of other cancer cells in the tumor microenvironment. However, the exact mechanisms by which tumor cell-derived exosomes affect their neighboring cells, as well as the bio-logical function of exosomal miRs in receptor cells, are not well understood. In this study, after the overexpression of MiR-205 in breast cancer cells (MDA-MB-231 class), cell-derived exosomes were successfully isolated and characterized by electron microscopy and dynamic light scattering. The determination of MiR-205 expression levels in exosomes secreted from engineered cells confirmed the high expression of this miR in exosomes. It was also found that the treatment of tumor exosomes carrying this miR had an apoptotic induction effect and also had a significant effect on reducing the expression of Bcl-2 gene transcript in a time-dependent manner in breast cancer cells (P < 0.001). Overall, this study suggests that exosomal transfer of tumor suppressor miRs to cancer cells could be a suitable platform for nucleic acid transfer to these cells and be highly effective in cancer treatment.

Enhanced endosomal escape of dendrigraft poly-L-lysine polymers for the efficient gene therapy of breast cancer

Enhanced endosomal escape of dendrigraft poly-L-lysine polymers for the efficient gene therapy of breast cancer

Suicide gene therapy-mediated purine nucleoside phosphorylase/fludarabine system for in vitro breast cancer model with emphasis on evaluation of vascular endothelial growth factor promoter efficacy.

In this study, a suicide gene therapy approach was optimized by a non-viral polyplex system based on pEGFP-N1 vector harboring purine nucleoside phosphorylase gene conducted by vascular endothelial growth factor promoter for an in vitro breast cancer model (4T1 cell line). The VEGF promoter and purine nucleoside phosphorylase gene were cloned into the vector from the source of 4T1 and E. coli genomic DNA, respectively. A gene construct was developed by replacing VEGF promoter instead of CMV promoter in pEGFP-N1vector. PNP gene was integrated in to the multiple cloning site of the obtained vector. On the other hand, a construct from pEGFP-N1 harboring PNP gene under the control of the original CMV promoter was developed. The transfection method using cationic polymer was optimized based on N/P ratio, cell cytotoxicity, polyplex size, zeta potential and the green fluorescent protein (GFP) expression by fluorescent microscopy and flowcytometry. Also, the effect of hypoxia condition induced by 0.5mM H2O2 on the promoter efficiency was investigated. The results showed that the performed gene delivery system is capable of the gene transfection to more than 30% of the cancer cells with both VEGF-PNP-pEGFP-N1 and PNP-pEGFP-N1 plasmids. The hypoxia condition did not show a significant effect on the VEGF promoter. But, it revealed that bystander effect can improve the efficacy of this system and reduce drug IC50 to 2 and fourfold for plasmids VEGF-PNP-pEGFP-N1 and PNP-pEGFP-N1, respectively. These results showed that the bystander effect could almost compensate the low efficiency of non-viral gene delivery systems. We suggest that the tumor-specific gene expression system mediated by the VEGF promoter can be especially useful in the present model of breast cancer gene therapy.

Controlled Synthesis and Surface Engineering of Janus Chitosan‐Gold Nanoparticles for Photoacoustic Imaging‐Guided Synergistic Gene/Photothermal Therapy

The unsymmetrical morphology and unique properties of Janus nanoparticles (JNPs) provide superior performances for biomedical applications. In this work, a general and facile strategy is developed to construct a series of symmetrical and unsymmetrical chitosan/gold nanoparticles. Taking advantage of the active motion derived from Janus structure, selective surface functionalization of polysaccharide domain, and photothermal effect of gold nanorods, Janus chitosan/gold nanoparticles (J-Au-CS) are selected as a model system to construct Janus-structured chitosan/gold nanohybrids (J-ACP). Near-infrared (NIR)-responsive J-ACP composed of polycationic chitosan nanospheres and PEGylated gold nanorods hold great potential to realize photoacoustic (PA) imaging-guided complementary photothermal therapy (PTT)/gene therapy for breast cancer. The morphology effect of chitosan/gold nanostructures on enhanced PTT, cellular uptake, and gene transfection is investigated. The feasibility of PA imaging to track the accumulation of J-ACP and guide PTT is also explored. Notably, synergistic therapy is achieved based on PTT-enhanced gene therapy. In addition, the loading function of chitosan/gold nanoparticles for fluorescence imaging is demonstrated. The current work extends the application of JNPs for imaging-guided synergistic cancer therapy and provides flexible candidates with distinct structures for diverse biomedical applications.