N-Succinyl-chitosan nanoparticles induced mitochondria-dependent apoptosis in K562

Effect of chitosan nanoparticles conjugated with the cell free supernatant of Bifidobacterium bifidum on the expression of genes related to colorectal cancer in colon adenocarcinoma (Caco-2) cell line

BACKGROUND

Colorectal cancer (CRC) is emerged as a global problem with high mortality rate; hence, finding of alternative treatment approaches is essential. The purposes of this research are to assess the impact of chitosan nanoparticles conjugated with the cell free supernatant of Bifidobacterium bifidum (CTNP/B.b-sup) on genes associated with CRC signaling pathways.

METHODS

The novel nano-drug were fabricated via an ionic gelation technique and analyzed using transmission electron microscopy (TEM) and dynamic light scattering (DLS) methods. The release of protein and entrapment efficiency (EE) of CTNP/B.b-sup were assessed using a BCA protein assay. Following an investigation into the toxicity of CTNP/B.b-sup on Caco-2 cells by MTT assay, the expression of genes associated with CRC signaling pathways was evaluated utilizing real-time PCR method.

RESULTS

CTNP/B.b-sup exhibited a suitable morphology with a particle size of 453.1 ± 230.8 nm and zeta potential of 9.11 ± 3.6 mV. The protein released was 75.5% at pH ~ 6.8 within 48 h with 83.3% of EE. The viability of Caco-2 cells against CTNP/B.b-sup was 90.3%. The effects of CTNP/B.b-sup on the expression levels of various oncogenes reveal a significant decrease in the expression of β-Catenin, PI3K, TGF-α, Bcl2, TLR4, CEA, and TGF-β oncogenes by 0.96, 0.37, 0.03, 0.41, 0.88, 0.69, and 0.71-fold, respectively. CTNP/B.b-sup induced the most significant reduction in TGF-α oncogene expression, with a decrease of 0.03-fold. Conversely, the strongest induction was observed in the expression of Caspase9 suppressor, with a 73.4-fold increase.

CONCLUSION

In the present study, the CTNP/B.b-sup was demonstrated to possess the capability of modulating genes associated with CRC progression, thereby highlighting its significant pro-apoptotic potential. It can be concluded that CTNP/B.b-sup is a suitable drug delivery system with anticancer properties, which can be regarded as a complementary therapeutic approach for the treatment of CRC.

Chitosan-based hydrogels in cancer therapy: Drug and gene delivery, stimuli-responsive carriers, phototherapy and immunotherapy

Nanotechnology has transformed the oncology sector by particularly targeting cancer cells and enhancing the efficacy of conventional therapies, not only improving efficacy of conventional therapeutics, but also reducing systemic toxicity. Environmentally friendly materials are the top choice for treating cancer. Chitosan, sourced from chitin, is widely used with its derivatives for the extensive synthesis or modification of nanostructures. Chitosan has been deployed to develop hydrogels, as 3D polymeric networks capable of water absorption with wide biomedical application. The chitosan hydrogels are biocompatible and biodegradable structures that can deliver drugs, genes or a combination of them in cancer therapy. Increased tumor ablation, reducing off-targeting feature and protection of genes against degradation are benefits of using chitosan hydrogels in cancer therapy. The efficacy of cancer immunotherapy can be improved by chitosan hydrogels to prevent emergence of immune evasion. In addition, chitosan hydrogels facilitate photothermal and photodynamic therapy for tumor suppression. Chitosan hydrogels can synergistically integrate chemotherapy, immunotherapy, and phototherapy in cancer treatment. Additionally, chitosan hydrogels that respond to stimuli, specifically thermo-sensitive hydrogels, have been developed for inhibiting tumors.

Nanoparticle Effects on Stress Response Pathways and Nanoparticle-Protein Interactions

Nanoparticles (NPs) are increasingly used in a wide variety of applications and products; however, NPs may affect stress response pathways and interact with proteins in biological systems. This review article will provide an overview of the beneficial and detrimental effects of NPs on stress response pathways with a focus on NP-protein interactions. Depending upon the particular NP, experimental model system, and dose and exposure conditions, the introduction of NPs may have either positive or negative effects. Cellular processes such as the development of oxidative stress, the initiation of the inflammatory response, mitochondrial function, detoxification, and alterations to signaling pathways are all affected by the introduction of NPs. In terms of tissue-specific effects, the local microenvironment can have a profound effect on whether an NP is beneficial or harmful to cells. Interactions of NPs with metal-binding proteins (zinc, copper, iron and calcium) affect both their structure and function. This review will provide insights into the current knowledge of protein-based nanotoxicology and closely examines the targets of specific NPs.

Application of chitosan modified nanocarriers in breast cancer

As per the WHO, every year around 2.1 million women are detected with breast cancer. It is one of the most invasive cancer in women and second most among all, contributing around 15% of death worldwide. The available anticancer therapies including chemo, radio, and hormone therapy are associated with a high load of reversible and irreversible adverse effects, limited therapeutic efficacy, and low chances of quality survival. To minimize the side effects, improving therapeutic potency and patient compliance promising targeted therapies are highly desirable. In this sequence, various nanocarriers and target modified systems have been explored by researchers throughout the world. Among these chitosan-based nanocarriers offers one of the most interesting, flexible, and biocompatible systems. The unique characteristics of chitosan like surface flexibility, biocompatibility, hydrophilicity, non-toxic and cost-effective behavior assist to overcome the inadequacy of existing therapy. The present review throws light on the successes, failures, and current status of chitosan modified novel techniques for tumor targeting of bioactives. It also emphasizes the molecular classification of breast cancer and current clinical development of novel therapies. The review compiles most relevant works of the past 10 years focusing on the application of chitosan-based nanocarrier against breast cancer.

Binary-copolymer system base on low-density lipoprotein-coupled N-succinyl chitosan lipoic acid micelles for co-delivery MDR1 siRNA and paclitaxel, enhances antitumor effects via reducing drug

The development of effective and stable carriers of small interfering RNA (siRNA) is important for treating cancer with multidrug resistance (MDR). We developed a new gene and drug co-delivery system and checked its characteristics. Low-density lipoprotein (LDL) was coupled with N-succinyl chitosan (NSC) Lipoic acid (LA) micelles and co-delivered MDR1 siRNA and paclitaxel (PTX-siRNA/LDL-NSC-LA) to enhance antitumor effects by silencing the MDR gene of tumors (Li et al., Adv Mater 2014;26:8217-8224). In our study, we developed a new type of containing paclitaxel-loaded micelles and siRNA-loaded LDL nanoparticle. This "binary polymer" is pH and reduction dual-sensitive core-crosslinked micelles. PTX-siRNA/LDL-NSC-LA had an average particle size of (171.6 ± 6.42) nm, entrapment efficiency of (93.92 ± 1.06) %, and drug-loading amount of (12.35% ± 0.87) %. In vitro, MCF-7 cells, high expressed LDL receptor, were more sensitive to this delivery system than to taxol^® and cell activity was inhibited significantly. Fluorescence microscopy showed that PTX-siRNA/LDL-NSC-LA was uptaken very conveniently and played a key role in antitumor activity. PTX-siRNA/LDL-NSC-LA protected the siRNA from degradation by macrophage phagocytosis and evidently down-regulated the level of mdr1 mRNA as well as the expression of P-gp. We tested the target ability of PTX-siRNA/LDL-NSC-LA in vivo in tumor-bearing nude mice. Results showed that this system could directly deliver siRNA and PTX to cancer cells. Thus, new co-delivering siRNA and antitumor drugs should be explored for solving MDR in cancer. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 1114-1125, 2017.

N-succinyl chitosan preparation, characterization, properties and biomedical applications: a state of the art review

N-succinyl chitosan (NSC) remains a promising chitosan derivative to develop targeted drug delivery, wound dressings, and tissue engineering systems. All these systems are important in life sciences. NSC is an amphiprotic derivative obtained from the N-acylation of chitosan. NSC exhibits extraordinary biocompatibility, significantly increased aqueous solubility in acidic and basic media without affecting the biological properties, appreciable transfection efficiency, and the ability to stimulate osteogenesis. NSC shows enhanced bioavailability, which highlights its potential applications in the biomedical field. This review briefly introduces chitosan, including its limitations as a biomaterial, and modifications of chitosan with a particular focus on acylation, along with a comprehensive overview of the synthesis, characterization, properties, biodistribution, and toxicological/biopharmaceutical profile of NSC. Furthermore, it extensively surveys current state-of-the-art NSC-based formulations for drug delivery with special emphasis on protein delivery, anti-cancer activity in the colon, as well as nasal and ophthalmic targeted gene/drug delivery. Moreover, it discusses NSC-based biomaterial applications in articular, adipose, and bone tissue engineering. In addition, it describes recent contributions of NSC-based hydrogels in wound dressings along with a brief account of drug delivery in combination with tissue engineering. Finally, it presents potential current challenges and future perspectives of NSC-based formulations in the biomedical field.

Chitosan nanoparticles cause pre- and postimplantation embryo complications in mice

Embryo development is a complex and tightly controlled process. Nanoparticle injury can affect normal development and lead to malformation or miscarriage of the embryo. However, the risk that these nanoparticles may pose to reproduction is not clear. In this study, chitosan nanoparticles (CSNP) of near uniform size, in the range of 100 nm, were synthesized and confirmed by a particle size analyzer and transmission electron microscopy. Morulae-stage embryo exposure to CSNP during in vitro culture caused blastocyst complications that had either no cavity or a small cavity. Furthermore, CSNP-treated embryos showed lower expression of not only trophectoderm-associated genes but also pluripotent marker genes. When blastocysts developed in both media with and without CSNP were transferred to recipients, the percentage of blastocysts resulting in viable pups was significantly reduced. These detrimental effects are linked to the reduction of total cell numbers, enhanced apoptosis, and abnormal blastocoels forming at the blastocyst stage, indicating that CSNP treatment might have long-term adverse biological effects in view of pregnancy outcome.

Differential internalization of amphotericin B--conjugated nanoparticles in human cells and the expression of heat shock protein 70

Although a variety of nanoparticles (NPs) functionalized with amphotericin B, an antifungal agent widely used in the clinic, have been studied in the last years their cytotoxicity profile remains elusive. Here we show that human endothelial cells take up high amounts of silica nanoparticles (SNPs) conjugated with amphotericin B (AmB) (SNP-AmB) (65.4 ± 12.4 pg of Si per cell) through macropinocytosis while human fibroblasts internalize relatively low amounts (2.3 ± 0.4 pg of Si per cell) because of their low capacity for macropinocytosis. We further show that concentrations of SNP-AmB and SNP up to 400 μg/mL do not substantially affect fibroblasts. In contrast, endothelial cells are sensitive to low concentrations of NPs (above 10 μg/mL), in particular to SNP-AmB. This is because of their capacity to internalize high concentration of NPs and high sensitivity of their membrane to the effects of AmB. Low-moderate concentrations of SNP-AmB (up to 100 μg/mL) induce the production of reactive oxygen species (ROS), LDH release, high expression of pro-inflammatory cytokines and chemokines (IL-8, IL-6, G-CSF, CCL4, IL-1β and CSF2) and high expression of heat shock proteins (HSPs) at gene and protein levels. High concentrations of SNP-AmB (above 100 μg/mL) disturb membrane integrity and kill rapidly human cells (60% after 5 h). This effect is higher in SNP-AmB than in SNP.