3D Tumor Models for Breast Cancer: Whither We Are and What We Need.

Three-dimensional (3D) models have led to a paradigm shift in disease modeling in vitro, particularly for cancer. The past decade has seen a phenomenal increase in the development of 3D models for various types of cancers with a focus on studying stemness, invasive behavior, angiogenesis, and chemoresistance of cancer cells, as well as contributions of its stroma, which has expanded our understanding of these processes. Cancer biology is moving into exploring the emerging hallmarks of cancer, such as inflammation, immune evasion, and reprogramming of energy metabolism. Studies into these emerging concepts have provided novel targets and treatment options such as antitumor immunotherapy. However, 3D models that can investigate the emerging hallmarks are few and underexplored. As commonly used immunocompromised mice and syngenic mice cannot accurately mimic human immunology, stromal interactions, and metabolism and require the use of prohibitively expensive humanized mice, there is tremendous scope to develop authentic 3D tumor models in these areas. Taking the specific case of breast cancer, we discuss the currently available 3D models, their applications to mimic signaling in cancer, tumor-stroma interactions, drug responses, and assessment of drug delivery systems and therapies. We discuss the lacunae in the development of 3D tumor models for the emerging hallmarks of cancer, for lesser-explored forms of breast cancer, and provide insights to develop such models. We discuss how the next generation of 3D models can provide a better mimic of human cancer modeling compared to xenograft models and the scope toward preclinical models and precision medicine.

Improved delivery of doxorubicin using rationally designed PEGylated platinum nanoparticles for the treatment of melanoma.

Efficient delivery of chemotherapeutic drugs to tumor cells is one of the crucial issues for modern day cancer therapy. In this article, we report the synthesis of poly ethylene glycol (PEG) assisted colloidal platinum nanoparticles (PtNPs) by borohydride reduction method at room temperature. PtNPs are stable at room temperature for more than 2 years and are stable in serum and phosphate buffer (pH = 7.4) solution for one week. PtNPs show biocompatibility in different normal cell lines (in vitro) and chicken egg embryonic model (ex vivo). Further, we designed and fabricated PtNPs-based drug delivery systems (DDS: PtNPs-DOX) using doxorubicin (DOX), a FDA approved anticancer drug. Various analytical techniques were applied to characterize the nanomaterials (PtNPs) and DDS (PtNPs-DOX). This DDS exhibits inhibition of cancer cell (B16F10 and A549) proliferation, observed by different in vitro assays. PtNPs-DOX induces apoptosis in cancer cells observed by annexin-V staining method. Intraperitoneal (IP) administration of PtNPs-DOX shows substantial reduction of tumor growth in subcutaneous murine melanoma tumor model compared to control group with free drug. Up-regulation of tumor suppressor protein p53 and down regulation of SOX2 and Ki-67 proliferation markers in melanoma tumor tissues (as observed by immunofluorescence and western blot analysis) indicates probable molecular mechanism for the anticancer activity of DDS. Considering the in vitro and pre-clinical (in vivo) results in murine melanoma, it is believed that platinum nanoparticle-based drug delivery formulation could be exploited to develop an alternative therapeutic nanomedicine for cancer therapy in the near future.

Silver Prussian Blue Analogue Nanoparticles: Rationally Designed Advanced Nanomedicine for Multifunctional Biomedical Applications.

The development of simple, cost-effective, and advanced multifunctional technology is the need of the hour to combat cancer as well as bacterial infections. There have been reports of silver nanoparticles (AgNPs), silver salts, and Prussian blue (PB) being used for medicinal purposes which are clinically approved. In this context, in the present communication, we incorporated PB and silver salts (silver nitrate) to develop silver PB analogue nanoparticles (SPBANPs), a new nanomedicine formulation as a safer and effective mode of treatment strategy (2-in-1) for both cancer and bacterial infections. Considering all fundamental issues of nanomedicine, along with understanding of the biological impact of PB, we designed a simple, fast, efficient, cheap, and eco-friendly method for the synthesis of [poly(N-vinyl-2-pyrrolidone)]-stabilized silver hexacyanoferrate nanoparticles (silver PB analogue: Ag3[Fe(CN)6] abbreviated as SPBANPs). Various analytical tools were used to analyze and characterize the nanomaterials (SPBANPs). The SPBANPs were highly stable for several weeks in various phosphate buffers with a range of physiological pH conditions (pH = 6-8). The nanoparticles showed biocompatibility in vivo in C57BL6/J mice that encouraged us to screen the nanoparticles for various biomedical applications. The SPBANPs themselves exhibited remarkable inhibition of cancer cell proliferation (B16F10, A549, MCF-7, and SK-OV-3) in vitro. Substantial inhibition of melanoma tumor growth was observed in the C57BL6/J mouse model (aggressive murine melanoma model: B16F10) after intraperitoneal administration of the SPBANPs without any anticancer drug. Additionally, the SPBANPs exhibited excellent antibacterial activity in various Gram-negative (Escherichia coli, Klebsiella pneumonia, and Pseudomonas aeruginosa) and Gram-positive (Bacillus subtilis) bacteria. Interestingly, this nanoformulation itself works as a drug delivery vehicle, as well as an anticancer and antibacterial agent. The in vitro and in vivo results together demonstrate that this biocompatible nanoformulation (SPBANPs) without an anticancer drug or antibiotic could be explored to develop as a multifunctional therapeutic agent (2-in-1) for the treatment of cancer and bacterial infections in the near future.

Restoration of p53 Function in Ovarian Cancer Mediated by Gold Nanoparticle-Based EGFR Targeted Gene Delivery System.

Targeted gene delivery of wild type tumor suppressor gene p53 is a promising approach to inhibit the progression of ovarian cancer. Although several gene delivery vehicles have been reported earlier, there is paucity for targeted delivery of wild type p53 to ovarian cancer using gold nanoparticles. As it is well-known that EGFR (epidermal growth factor receptor) is overexpressed in ovarian cancer, in this study we hypothesized that the FDA approved monoclonal antibody C225 (cetuximab) that targets EGFR could be used for targeted delivery of wild type p53 gene. With this impetus, we devised an approach wherein cationic gold nanoparticles (AuNPs) were employed to generate gold nanoparticle-based drug delivery system (DDS, Au-C225-p53DNA where p53DNA is pCMVp53 plasmid) that was formulated and characterized by biochemical and biophysical methods. The nanoconjugate complexed with DNA (Au-C225-p53DNA) is serum-stable and protects the bound DNA from digestion by DNase-I. Additionally, in vitro reporter gene expression assays demonstrated efficient and specific gene transfection in EGFR overexpressing SK-OV-3 cells. Further, the intraperitoneal administration of Au-C225-p53DNA in SK-OV-3 xenograft mouse model displayed significant tumor targeting and tumor regression. Altogether, these studies indicated a promising nanoparticle-based approach for targeting ovarian cancers caused by mutated p53.

Biosynthesized Gold Nanoparticles: In Vivo Study of Near-Infrared Fluorescence (NIR)-Based Bio-imaging and Cell Labeling Applications.

Near infrared (NIR) fluorescence imaging is a striking imaging modality for biomedical and clinical applications due to its deep tissue penetration and low phototoxicity. The major issue with NIR dyes is their non-specific distribution and requirement of tagging with biomolecules for specific tissue localization. Till now, there have been no imaging agents available that can distribute into a specific organ without the need for targeted ligands, which remains as an unmet clinical need. In the present study, we demonstrate that the Zinnia elegans plant extract (abbreviated as ZE) assisted synthesis of highly biocompatible gold nanoparticles (AuZE), leading to their non-invasive bio-imaging applications in the NIR region (red at 820 nm emission: NIR region). AuZE and ZE both exhibited green fluorescence at 350 nm excitation and red fluorescence in the NIR region (710 nm). We verified the source of this fluorescence, which originates from the fluorescent molecules present in the ZE extract. After intraperitoneal administration in C57BL6 mice, very interestingly, AuZE is distributed into the brain of C57BL6 mice without the need for any targeted ligand and exhibited bright red fluorescence in the NIR region (710 nm excitation, 820 nm emission) as evidenced by non-invasive imaging as well as ICPOES techniques. We further explored the activity of ZE and AuZE as cell labeling agents (B16F10 cells were pre-incubated with AuZE and implanted into mice, and the fluorescence was monitored), which could be applicable for graft transplantation biology. To the best of our knowledge, this is the first report that demonstrates the versatile applications of green synthesized gold nanoparticles using a ZE extract. Considering these exciting results and fruitful outcomes, the ZE and AuZE NPs would stand as an alternative imaging agent to commercially available NIR dyes and change the conventional fluorescence-based bio-imaging strategies. Therefore, the biosynthesized AuNPs open new directions for future research to explore these latest observations in the field of disease diagnosis and therapy.

Nanomedicine for Cancer Therapy Using Autophagy: An Overview.

Autophagy is an intracellular biological catabolic process of mammalian cells to maintain the homeostasis. It plays a wide role in the clearance of damaged cellular organelles, misfolded or aggregated proteins like alpha-synuclein, ß-amyloid peptides, Tau proteins and pathogens. Recent studies have clearly demonstrated that dysfunction in autophagy leads to the development of cancer, cardiomyopathy, chronic infection, neurodegenerative and other diseases. Therefore, modulation of autophagy has therapeutic value to cure the diseases including cancer using external stimuli. In this context, various researchers developed small molecules such as chloroquine, rapamycin, etc. for the treatment of cancer through autophagy. However, these molecules possess side effects which limit their use in the clinics. Therefore, nanomedicine approach could stand as an alternative treatment option to induce the autophagy in cancer therapy. Several investigators developed a variety of nanomaterials which themselves act as autophagy inducers or inhibitors. Considering this, the present review article will focus on the recent developments of nanomedicine in the area of autophagy that have been focused on the treatment of cancers. We also summarised the detailed mechanisms of nanoparticles mediated autophagy which could be helpful for developing new strategies to fight against cancer. Also, the present review article covers the current clinical status of nanomedicine and future challenges. Finally, we conclude with the future potential role of nanomedicine for autophagy induction in the cancer treatment.

Ag2[Fe(CN)5NO] Nanoparticles Exhibit Antibacterial Activity and Wound Healing Properties.

Therapeutic agents harboring both wound healing and antibacterial activities have much demand in biomedical applications. Development of such candidates with clinically approved materials adds more advantages toward these applications. Recently, silver metal complex nanomaterials have been playing a major role in medical uses especially for antibacterial activity and wound healing. In this report, we designed and synthesized silver nitroprusside complex nanoparticles (abbreviated as AgNNPs) using sodium nitroprusside and silver nitrate (both are FDA approved precursors). The nanoparticles (AgNNPs) were thoroughly characterized by various physicochemical techniques such as XRD, FTIR, TGA, DLS, EDAX, Raman, ICP-OES, HRTEM, and FESEM. The cell viability assay in normal cells (EA.hy 926 cells, NIH 3T3) using MTT reagents and CEA assay (CEA: Chick embryo angiogenesis assay) in fertilized eggs demonstrate the biocompatibility of AgNNPs. These nanoparticles show effective antibacterial activity against both Gram positive and Gram negative bacteria through membrane and DNA damage. Additionally, AgNNPs accelerate the wound healing in C57BL6 mice by altering the macrophages from M1 to M2. Considering the results together, the current study may offer the development of new silver nanocomplex nanomaterials that shows synergistic effect on antibacterial activity and wound healing (2-in-1-system). To the best of our knowledge, this is the first report for the synthesis, characterization, and biomedical applications of silver nitroprusside nanoparticles.

Au-CGKRK Nanoconjugates for Combating Cancer through T-Cell-Driven Therapeutic RNA Interference.

Numerous prior studies on fighting cancer have been based on using inhibitors of JAK-STAT pathway (signal transducer and activator of transcription 3 (STAT3) inhibitor in particular), a signaling pathway responsible for progression of many types of cancer cells. However, recent studies have shown that STAT3 activation leads to upregulation of program death receptor-ligand 1 (PD-L1, an immune checkpoint protein that plays a major role behind evasion of immune systems by growing tumors) expression levels in tumor cells, leading to enhanced immune suppression. This is why global efforts are being witnessed in combating cancer through use of immune checkpoint inhibitors. Herein, we report on the design, synthesis, physicochemical characterizations, and bioactivity evaluation of novel tumor- and tumor-vasculature-targeting noncytotoxic Au-CGKRK nanoconjugates (17-80 nm) for combating tumor. Using a syngeneic mouse tumor model, we show that intraperitoneal (i.p.) administration of the Au-CGKRK nanoparticles (NPs) complexed with both PD-L1siRNA (the immune checkpoint inhibitor) and STAT3siRNA (the JAK-STAT pathway inhibitor) results in significant (>70%) enhancement in overall survivability (OS) in melanoma-bearing mice (n = 5) when compared to the OS in the untreated mice group. The expression levels of CD8 and CD4 proteins in the tumor lysates of differently treated mice groups (by Western blotting) are consistent with the observed OS enhancement being a T-cell-driven process. Biodistribution study using near-infrared dye-loaded Au-CGKRK nanoconjugates revealed selective accumulation of the dye in mouse tumor. Notably, the overall survival benefits were significantly less (∼35%) when melanoma-bearing mice were treated (i.p.) with Au-CGKRK NPs complexed with only PD-L1siRNA or with STAT3siRNA alone. The presently described Au-CGKRK nanoconjugates are expected to find future use in therapeutic RNA-interference-based cancer immunotherapy.

Engineered fusion protein-loaded gold nanocarriers for targeted co-delivery of doxorubicin and erbB2-siRNA in human epidermal growth factor receptor-2+ ovarian cancer.

Designed recombinant proteins comprising functional domains offer selective targeting of cancer cells for the efficient delivery of therapeutic agents. The efficacy of these carriers can be further enhanced by conjugating engineered proteins to nanoparticle surfaces. However, recombinant protein-loaded nanoparticle-based drug delivery systems are not well addressed for ovarian cancer therapy. In the present study, using a combinatorial approach, we designed and fabricated a drug delivery system by combining gold nanoparticles (AuNPs) with an engineered bi-functional recombinant fusion protein TRAF(C) (TR), loaded with an anticancer drug, namely doxorubicin (DX), and erbB2-siRNA (si), to mediate target specific delivery into SK-OV-3, a model human ovarian cancer cell line over expressing HER2 receptors (i.e. human epidermal growth factor receptor-2). The nanoparticle-based targeted drug delivery system, designated as TDDS (Au-TR-DX-si), was found to be stable and homogenous as revealed by physicochemical and biochemical studies in vitro. In addition, TDDS was functional upon evaluation in vivo. Intraperitoneal administration of TDDS at 2.5 mg kg-1 of DX and 0.25 mg kg-1 of erbB2 siRNA into SK-OV-3 xenograft nude mice, revealed target specific uptake and consequent gene silencing resulting in significant tumor suppression. We attribute these results to specific co-delivery of erbB2 siRNA and DX mediated by TDDS into SK-OV-3 cells via HER2 receptors. Additionally, the biodistribution of TDDS, as quantitated by ICP-OES, confirmed tumor-specific accumulation of AuNPs primarily in tumor tissues, which firmly establishes the efficacy of the nanomedicine-based combinatorial approach for the treatment of ovarian cancer in a non-toxic manner. Based on these findings, we strongly believe that the nanomedicine-based combinatorial approach can be developed as a universal strategy for treatment of HER2+ ovarian cancers.

Synthesis and biological evaluation of novel 2-imino-4-thiazolidinone derivatives as potent anti-cancer agents.

A new series of 2-imino-4-thiazolidinone derivatives (7a-7t) has been synthesised and screened for their cytotoxicity against three cancer cell lines (B16F10, A549, PANC-1) and normal cell line (CHO). Among the compounds tested, compounds 7k, 7m, 7n showed potent cytotoxicity against B16F10 cell line with IC50 between 3.4 and 7µM. Interestingly these three compounds are non toxic to non cancerous CHO cells and induced apoptosis in B16F10 cells observed by DNA damage analysis through PI/Hoechst double staining method. Compounds 7k and 7n induced G0/G1 cell cycle arrest while compound 7m induced G2/M cell cycle arrest in B16F10 cells which confirms that these compounds have role in cancer cell cycle regulation. Additionally, compound 7m showed generation of intracellular reactive oxygen species (ROS) in B16F10 cells that may contribute in the cell cycle arrest whereas compounds 7k and 7n show anti-cancer activity through independent of ROS formation. Induction of apoptosis, cell cycle arrest in B16F10 cells are found to be the anti-cancer mechanism of these three compounds. The results all together demonstrate the potent cytotoxic nature of these compounds in cancer cells could be considered as new class of chemotherapeutic agents in near future.

Curcumin loaded mesoporous silica: an effective drug delivery system for cancer treatment.

In the present study, we report the delivery of anti-cancer drug curcumin to cancer cells using mesoporous silica materials. A series of mesoporous silica material based drug delivery systems (S2, S4 and S6) were first designed and developed through the amine functionalization of KIT-6, MSU-2 and MCM-41 followed by the loading of curcumin. The curcumin loaded materials were characterized with several physico-chemical techniques and thoroughly screened on cancer cells to evaluate their in vitro drug delivery efficacy. All the curcumin loaded silica materials exhibited higher cellular uptake and inhibition of cancer cell viability compared to pristine curcumin. The effective internalization of curcumin in cancer cells through the mesoporous silica materials initiated the generation of intracellular reactive oxygen species and the down regulation of poly ADP ribose polymerase (PARP) enzyme levels compared to free curcumin leading to the activation of apoptosis. This study shows that the anti-cancer activity of curcumin can be potentiated by loading onto mesoporous silica materials. Therefore, we strongly believe that mesoporous silica based curcumin loaded drug delivery systems may have future potential applications for the treatment of cancers.

Bis-arylidene oxindole-betulinic Acid conjugate: a fluorescent cancer cell detector with potent anticancer activity.

Molecules offering simultaneous detection and killing of cancer cells are advantageous. Hybrid of cancer cell-selective, ROS generator betulinic acid and bis-arylidene oxindole with amino propyl-linker is developed. With intrinsic fluorescence, the molecule exhibited cancer cell-specific residence. Further, it generated ROS, triggered apoptosis, and exhibited potent cytotoxicity in cancer cells selectively. We demonstrate the first example and use of isatins as betulinic acid conjugate for selective detection of cancer and subsequent killing of cancer cells via apoptosis.

A green chemistry approach for the synthesis of gold nanoconjugates that induce the inhibition of cancer cell proliferation through induction of oxidative stress and their in vivo toxicity study.

In this paper, we report the synthesis of gold nanoconjugates (b-Au-LM) using the aqueous leaf extract of Lantana montevidensis (LM), a naturally available medicinal plant. The biosynthesized b-Au-LM was biocompatible in both in vitro and in vivo systems. However, the LM extract as well as b-Au-LM exhibited significant inhibition of the proliferation of cancer cells. Interestingly, b-Au-LM showed enhanced anti-cancer activity compared to the pristine LM extract. Generation of reactive oxygen species (ROS) and oxidative stress, which triggered the upregulation of caspase-3, might be the plausible reason for anti-cancer activity. Cell cycle analysis demonstrated G2/M (in A549 cells) or Sub-G1 (in MCF-7) cell cycle arrest, which might lead to apoptosis. Together, the results support the future therapeutic application of an in situ biosynthesized gold nanoconjugates based drug delivery system (b-Au-LM) towards cancer therapy and other biomedical applications.

Potential theranostics application of bio-synthesized silver nanoparticles (4-in-1 system).

In this report, we have designed a simple and efficient green chemistry approach for the synthesis of colloidal silver nanoparticles (b-AgNPs) that is formed by the reduction of silver nitrate (AgNO3) solution using Olax scandens leaf extract. The colloidal b-AgNPs, characterized by various physico-chemical techniques exhibit multifunctional biological activities (4-in-1 system). Firstly, bio-synthesized silver nanoparticles (b-AgNPs) shows enhanced antibacterial activity compared to chemically synthesize silver nanoparticles (c-AgNPs). Secondly, b-AgNPs show anti-cancer activities to different cancer cells (A549: human lung cancer cell lines, B16: mouse melanoma cell line & MCF7: human breast cancer cells) (anti-cancer). Thirdly, these nanoparticles are biocompatible to rat cardiomyoblast normal cell line (H9C2), human umbilical vein endothelial cells (HUVEC) and Chinese hamster ovary cells (CHO) which indicates the future application of b-AgNPs as drug delivery vehicle. Finally, the bio-synthesized AgNPs show bright red fluorescence inside the cells that could be utilized to detect the localization of drug molecules inside the cancer cells (a diagnostic approach). All results together demonstrate the multifunctional biological activities of bio-synthesized AgNPs (4-in-1 system) that could be applied as (i) anti-bacterial & (ii) anti-cancer agent, (iii) drug delivery vehicle, and (iv) imaging facilitator. To the best of our knowledge, there is not a single report of biosynthesized AgNPs that demonstrates the versatile applications (4-in-1 system) towards various biomedical applications. Additionally, a plausible mechanistic approach has been explored for the synthesis of b-AgNPs and its anti-bacterial as well as anti-cancer activity. We strongly believe that bio-synthesized AgNPs will open a new direction towards various biomedical applications in near future.