Chitosan-Based Nanoparticles with Optimized Parameters for Targeted Delivery of a Specific Anticancer Drug-A Comprehensive Review

Melatonin-loaded lecithin and chitosan nanoparticles are cytotoxic to 4 T1 breast cancer cells and safe in a BALB/c mouse model

Melatonin is used as an adjuvant therapy in cancer treatment. However, its effectiveness is limited because of its low bioavailability. Polymeric nanoparticles (NPs) made of chitosan and lecithin have been developed to overcome this limitation and optimize localized drug delivery. These lecithin and chitosan-based NPs loaded with melatonin (NP-MEL) were evaluated for their cytotoxic potential in metastatic breast cancer cells and their safety profile in a murine model. Physicochemical characterization revealed efficient melatonin encapsulation (31 %), a positive zeta potential (48.6 mV), and controlled release at physiological pH. NP-MEL exhibited selective cytotoxicity in vitro, with a toxic concentration capable of killing 50 % of the cells (CC50) of 109.53 μg/mL for 4 T1 cancer cells and a significantly higher CC50 of 1460.59 μg/mL for normal VERO cells, resulting in a selectivity index of 13.33. In vivo experiments with BALB/c mice with tumor implantation treated with NP-MEL (2 mg/kg/day for 21 days) showed no significant changes in weight, clinical signs, or biochemical markers of liver and kidney function, except for changes in gamma-glutamyl transferase levels. Histopathological analyses confirmed the preservation of the liver and kidney architecture in the NP-MEL-treated group, in contrast to the moderate-to-severe kidney damage observed in animals treated with empty NPs. These findings highlight the low toxicity and therapeutic potential of NP-MEL as a controlled and targeted-release system for breast cancer treatment, indicating the need for further preclinical investigation.

Chitosan: An overview of its properties, solubility, functional technologies, food and health applications

The properties and potential applications of chitosan have attracted a lot of interest; each year, the number of publications and patents based on this polymer increases. A significant obstacle to the application of chitosan is its limited solubility in basic and neutral solutions. The fact that chitosan is a series of molecules with variations in size, content, and monomer distribution rather than a single polymer with a well-defined structure and a natural origin is another significant barrier. Some of the claimed biological qualities are distinct, and these characteristics have a fundamental effect on the polymer's technological and biological performance. The poor solubility of the polymer can be improved by chitosan chemistry, and in this assessment, we discuss the changes made to make chitosan more soluble and its possible uses. We concentrate on a few of the primary biological characteristics of chitosan and how they relate to the physicochemical characteristics of the polymer. The use of chitosan in the environmentally friendly manufacture of metallic nanoparticles as well as its usage as a booster for biocatalysts are two further applications of polymers that are linked to green processes that we revisit. This study also presents information about utilizing chitosan's technological advantages.

SLN and chitosan nano-delivery systems for antibacterial effect of black seed (Nigella sativa) oil against S. aureus

Staphylococcus aureus with current universal importance represents a main carrier of emerging antimicrobial resistance determinatives of global health concerns that have developed drug resistance mechanisms to the various available antibiotics. On the other hand, due to the antimicrobial potential of Nigella Sativa oil (NSO), it was hypothesized that incorporation of nano-carriers (NS-SLN and NS-chitosan (CH) nanoparticles) can enhance its antibacterial effects. This study evaluated the physico-chemical and antibacterial characteristics of NS-SLN and NS-CH. TEM images revealed a round shape with clear edges for both nanoparticles, and the average sizes were reported to be 196.4 and 446.6 nm for NS-SLN and NS-CH, respectively. The zeta potential and encapsulation efficiency were -28.9 and 59.4 mV and 73.22% and 88% for NS-SLN and NS-CH, respectively. The Minimum Inhibitory Concentrations for NSO, NS-SLN, and NS-CH against S. aureus were 480, 200, and 80 µg/mL, respectively. The results confirm significantly stronger antibacterial influences of NSO when loaded into chitosan nanoparticles as a potential candidate for nano-delivery of antimicrobial agents.

Harnessing the immunomodulatory potential of chitosan and its derivatives for advanced biomedical applications

The success of biomaterial applications in medicine, particularly in tissue engineering, relies on achieving a balance between promoting tissue regeneration and controlling the immune response. Due to its natural origin, high biocompatibility, and versatility, chitosan has emerged as a promising biomaterial especially for immunomodulation purposes. Immunomodulation, refers to the deliberate alteration of the immune system's activity to achieve a desired therapeutic effect either by enhancing or suppressing the function of specific immune cells, signaling pathways, or cytokine production. This modulation opens up the unlimited possibilities for the use of biomaterials, especially about the use of natural polymers such as chitosan. Although numerous chitosan-based immunoregulatory strategies have been demonstrated over the past two decades, the lack of in-depth exploration hinders the full potential of strategies that include chitosan and its derivatives in biomedical applications. Thus, in this review, the possible immunomodulatory effects of chitosan, chitosan derivatives and their potential combined with various agents and therapies are investigated in detail. Moreover, this report includes agents for localized immune response control, chitosan-based strategies with complementary immunomodulatory properties to create synergistic effects that will influence the success of cell therapies for enhanced tissue acceptance and regeneration. Finally, the challenges and outlook of chitosan-based therapies as a powerful tool for improving immunomodulatory applications are discussed for paving the way for further studies.

Optimized and Functionalized Carvacrol-Loaded Nanostructured Lipid Carriers for Enhanced Cytotoxicity in Breast Cancer Cells

Background/Objectives: Carvacrol, a monoterpenoid phenol found in essential oils, exhibits many biological activities, including anticancer properties through mechanisms such as induction of apoptosis. These properties can be enhanced if encapsulated within nanoparticles. This study focuses on producing functionalized carvacrol-loaded nanostructured lipid carriers (NLCs) applied to the treatment of breast cancer. Methods: NLCs were produced by hot emulsification with the sonication method and optimized by the Box-Behnken design, considering Precirol® (1, 4, 7%), carvacrol (1, 5, 9%), and Tween® (0.1, 0.5, 0.9%) as independent variables. Results: The optimized NLC containing 2% carvacrol had a particle size of 111 ± 2 nm, PdI of 0.26 ± 0.01, and zeta potential of -24 ± 0.8 mV. The solid lipid (Precirol®) was the variable that most influenced particle size. NLCs were functionalized with Pluronic® F68, cholesterol, chitosan, and polyethylene glycol (0.05-0.2%), with oNLC-Chol presenting the most promising results, with no significant increase in particle size (±12 nm) and high encapsulation efficiency (98%). Infrared spectra confirm effective carvacrol encapsulation, and stability tests showed no significant physicochemical changes for 120 days of storage at 4 °C. When incubated with albumin (5 mg/mL), NLCs showed overall good stability over 24 h, except for oNLC-Chol, which increased slightly in size after 24 h. In addition, oNLC increased the cytotoxic effect of carvacrol by 12-fold, resulting in an IC50 of 7 ± 1 μg/mL. Conclusions: Therefore, it was possible to produce stable, homogeneous NLCs with nanometric sizes containing 2% carvacrol that displayed improved anticancer efficacy, indicating their potential as a delivery system.

Yeast Cell Wall-Mediated Ileal Targeted Delivery System for IgA Nepharopathy Therapy

IgA nephropathy (IgAN) is a primary glomerulonephritis mediated by autoimmunity, characterized by an abnormal increase and the deposition of IgA in the glomeruli. In recent years, most studies have emphasized the crucial role of the gut-kidney axis in the pathogenesis of IgA nephropathy, and the ileal Peyer patches in the intestinal mucosal immune system are the main site for IgA production. Therefore, in this study, hydroxychloroquine (HCQ) and dexamethasone (DXM) were used as model drugs, and yeast cell wall (YCW)-coated oleic acid-grafted chitosan (CSO) was used as a carrier to construct a yeast cell wall oral drug delivery system HCQ/DXM@CSO@YCW. This delivery system achieves ileal targeted delivery through the yeast cell wall (YCW), reduces IgA production, and synergistically regulates the inflammatory pathological environment. The delivery system had good gastrointestinal stability and biocompatibility. In vitro cell experiments had shown the targeted uptake ability of dendritic cells and macrophages, and in vitro intestinal experiments showed that the YCW has ileal targeting properties. In vivo pharmacodynamic experiments showed that the HCQ/DXM@CSO@YCW delivery system could significantly reduce the serum IgA levels and IgA deposition in the renal tissue of IgAN mice, as well as the levels of IL-6, TNF-α, and TGF-β in the renal tissue, improving the pathological morphology of the renal tissue. Therefore, the DXM/HCQ@CSO@YCW oral administration system provided a new intestinal targeted delivery platform for intestinal mucosal immunotherapy in IgA nephropathy.

Effect of Surface Properties of Chitosan-Based Nanoparticles in the Skin-Diffusion Rate

Skin diseases may cause rash, inflammation, itchiness, and other important skin changes, including dysplasia. Some skin conditions may be due to genetic and lifestyle factors and immune-mediated factors. The current skin disease treatment can include oral medication, topical cream, or ointments. Nanotechnology is revolutionizing the drug delivery systems, increasing the time life of active therapeutic compounds and improving the treatment efficiency. This work hypothesizes that varying the surface properties of chitosan nanoparticles (Ch-NPs) can modulate their diffusion through dermal tissue. Thus, Ch-NPs were synthesized, and their surface was modified with polyethylene glycol, oxalic acid, and linoleic acid for transdermal therapy. The different Ch-NPs were labeled with a fluorophore, and the dermal diffusion was measured on human skin by histological preparations and fluorescent microscopy. The surface properties of nanoparticles were shown to play an essential role in skin diffusion rate. Surface modification with a lipophilic moiety such as linoleic fatty acid showed a diffusion rate of 7.23 mm2/h in human full-thickness abdominal flap, which is 2.7 times faster nanoparticle diffusion through dermal tissue when compared with the unmodified Ch-NPs (2.92 mm2/h). The positive (zeta potential +27.5 mV) or negative (zeta potential -2.2 mV) surface charge does not affect the chitosan nanoparticle diffusion. Polyethylene glycol surface modification slightly improved the nanoparticle diffusion rate (3.63 mm2/h). Thus, modulating the nanoparticle surface properties can control the skin diffusion rate. The implications of this finding on dermic drug delivery are discussed.

Functional potential of chitosan-metal nanostructures: Recent developments and applications

Chitosan (Cs), a naturally occurring biopolymer, has garnered significant interest due to its inherent biocompatibility, biodegradability, and minimal toxicity. This study investigates the effectiveness of various reaction strategies, including acylation, acetylation, and carboxymethylation, to enhance the solubility profile of Cs. This review provides a detailed examination of the rapidly developing field of Cs-based metal complexes and nanoparticles. It delves into the diverse synthesis methodologies employed for their fabrication, specifically focusing on ionic gelation and in-situ reduction techniques. Furthermore, the review offers a comprehensive analysis of the characterization techniques utilized to elucidate the physicochemical properties of these complexes. A range of analytical techniques are utilized, including Ultraviolet-Visible Spectroscopy (UV-Vis), Fourier-Transform Infrared Spectroscopy (FTIR), Scanning Electron Microscopy (SEM) and others. By comprehensively exploring a wide range of applications, the review emphasizes the significant potential of Cs in various scientific disciplines. Diagrams, figures, and tables effectively illustrate the synthesis processes, promoting a clear understanding for the reader. Chitosan-metal nanostructures/nanocomposites significantly enhance antimicrobial efficacy, drug delivery, and environmental remediation compared to standard chitosan composites. The integration of metal nanoparticles, such as silver or gold, improves chitosan's effectiveness against a range of pathogens, including resistant bacteria. These nanocomposites facilitate targeted drug delivery and controlled release, boosting therapeutic bioavailability. Additionally, they enhance chitosan's ability to absorb heavy metals and dyes from wastewater, making them effective for environmental applications. Overall, chitosan-metal nanocomposites leverage chitosan's biocompatibility while offering improved functionalities, making them promising materials for diverse applications. This paper sheds light on recent advancements in the applications of Cs metal complexes for various purposes, including cancer treatment, drug delivery enhancement, and the prevention of bacterial and fungal infections.

Preparation and characterizations of chitosan-octanoate nanoparticles for efficient delivery of curcumin into prostate cancer cells

The goal of the research was to develop a hydrophobic octanoate salt of chitosan (CS-OA) and use the salt as a nanoparticle platform for the delivery of curcumin (CUR) into prostate cancer cells. The nanoprecipitation technique was used to prepare the nanoparticles, which were measured for particle size and encapsulation efficacy relative to CUR-CS nanoparticles. The cytotoxicity of CUR-OA-CS nanoparticles was evaluated in prostate cancerous cells (PC3 and DU145) in comparison with the corresponding blank nanoparticles and hydroalcoholic CUR solution. PXRD, SEM, and TEM were also used to examine the CUR-CS-OA nanoparticles. The average diameters of the CUR-CS-OA and CUR-CS nanoparticles were 268.90 ± 3.77 nm and 221.90 ± 2.79 nm, respectively, with encapsulation efficiencies of 61.37 ± 1.70% and 60.20 ± 3.17%. PXRD and SEM suggested CUR amorphization in the CS-OA nanoparticles. The void nanoparticles exhibited concentration-dependent antiproliferative action, which was attributed to the cellular uptake of CS. CUR loading into these nanoparticles increased their cytotoxicity even more. The potential of CS-OA nanoparticles as a special delivery system for additional cytotoxic drugs into different malignant cells can be further explored.

Stability, challenges, and prospects of chitosan for the delivery of anticancer drugs and tissue regenerative growth factors

Chitosan, a biopolymer derived from chitin, offers significant potential for regulated anticancer drug administration and tissue regeneration growth factors, owing to its biocompatibility, low toxicity, biodegradability, and little immunogenicity. Moreover, its structure can be extensively modified, for example, to create scaffolds, hydrogels, nanoparticles, and membranes, allowing it to be engineered precisely to achieve specific outcomes However, the therapeutic utilisation of chitosan is impeded by significant challenges, such as its inadequate hemocompatibility, durability, and uniformity in commercial manufacturing. Additionally, there is insufficient research offering a thorough examination of the capabilities, limitations, and challenges related to chitosan as carriers for anticancer drugs and growth factors. This article examines the stability, challenges, and advanced application of chitosan as a drug carrier in anti-cancer therapy and growth factor delivery. The problems of unregulated chitosan degradation arising from unsuitable storage conditions are considered and potential solutions, and areas for future research, are proposed to deal with such problems. Consequently, this review is expected to be highly valuable for aspiring scientists studying chitosan-related systems for delivery of anti-cancer drugs and growth factors.

Superior remedy colon cancer HCT-116 cells via new chitosan Schiff base nanocomposites: Synthesis and characterization

Cancer is a serious worldwide health problem and colon cancer is the major cancer public prevailing form. The innovative pharmaceuticals with great cancer efficacy are metal nanoparticles. Therefore, the present study relies on developing chitosan Schiff base nanocomposites and investigating their antitumor ability against human colon carcinoma (HCT-116 cell line) using the MTT method. Thus, chitosan (CS) is modified with 9-ethyl-3-carbazolecarboxaldehyde (ECCA) in the absence or presence of the biomedical crosslinker poly(ethylene glycol) diglycidyl ether (PEGDGE) under microwave irradiation to afford CS-Schiff bases CS-SB-I and CS-SB-II, respectively. The assembly method is applied to formulate CS-Schiff base (Ag, Au and ZnO) nanocomposites. These new CS-Schiff bases and their nanocomposites are characterized by utilizing elemental analysis, FTIR, TGA, XRD, SEM, TEM and EDX. Cytotoxicity test showed that CS-SB-I (IC50 112.10 ± 4.23 μg/mL) and CS-SB-II (IC50 98.54 ± 4.09 μg/mL) inhibit the growth of HCT-116 more effectively than chitosan (IC50 181.38 ± 6.54 μg/mL). Additionally, CS-Schiff base nanocomposites revealed superior anticancer efficiency which displayed the lowest IC50 values CS-SB-I-Ag (IC50 10.99 ± 0.37 μg/mL), CS-SB-II-Ag (IC50 12.79 ± 0.49 μg/mL), CS-SB-I-Au (IC50 14.96 ± 0.51 μg/mL), CS-SB-II-Au (IC50 26.72 ± 1.57 μg/mL), CS-SB-I-ZnO (IC50 22.79 ± 1.28 μg/mL) and CS-SB-II-ZnO (IC50 22.24 ± 1.34 μg/mL). The findings demonstrated that CS-Schiff base nanocomposites are promising agents for the HCT-116 cell therapeutic.

Conjugated therapeutic proteins as a treatment for bacteria which trigger cancer development

In recent years, an increasing amount of research has focused on the intricate and complex correlation between bacterial infections and the development of cancer. Some studies even identified specific bacterial species as potential culprits in the initiation of carcinogenesis, which generated a great deal of interest in the creation of innovative therapeutic strategies aimed at addressing both the infection and the subsequent risk of cancer. Among these strategies, there has been a recent emergence of the use of conjugated therapeutic proteins, which represent a highly promising avenue in the field of cancer therapeutics. These proteins offer a dual-targeting approach that seeks to effectively combat both the bacterial infection and the resulting malignancies that may arise because of such infections. This review delves into the landscape of conjugated therapeutic proteins that have been intricately designed with the purpose of specifically targeting bacteria that have been implicated in the induction of cancer.

CRISPR/Cas9-mediated silencing of CD44: unveiling the role of hyaluronic acid-mediated interactions in cancer drug resistance

A comprehensive overview of CD44 (CD44 Molecule (Indian Blood Group)), a cell surface glycoprotein, and its interaction with hyaluronic acid (HA) in drug resistance mechanisms across various types of cancer is provided, where CRISPR/Cas9 gene editing was utilized to silence CD44 expression and examine its impact on cancer cell behavior, migration, invasion, proliferation, and drug sensitivity. The significance of the HA-CD44 axis in tumor microenvironment (TME) delivery and its implications in specific cancer types, the influence of CD44 variants and the KHDRBS3 (KH RNA Binding Domain Containing, Signal Transduction Associated 3) gene on cancer progression and drug resistance, and the potential of targeting HA-mediated pathways using CRISPR/Cas9 gene editing technology to overcome drug resistance in cancer were also highlighted.

On the Structural and Molecular Properties of PEO and PEO-PPG Functionalized Chitosan Nanoparticles for Drug Delivery

Chitosan nanoparticles (CS-NPs) are currently under investigation for a wide range of applications in nanomedicine. We investigated the structural, morphological, and molecular properties of CS-NPs synthesized via ionic gelation and designed specifically for drug delivery. The CS-NPs were prepared at concentrations ranging from 0.25 to 1.0% w/v. The 1.0% w/v CS-NPs were also functionalized with polyethylene oxide (PEO) alone and with a diblock copolymer of PEO and polypropylene glycol (PPG). The average nanoparticle size determined from TEM imaging is in the 11.3 to 14.8 nm range. The XRD and TEM analyses reveal a semi-crystalline structure with a degree of crystallinity dependent upon the nature of CS-NP functionalization. Functionalizing with PEO had no effect, whereas functionalizing with PEO-PPG resulted in a significant increase in the crystallinity of the 1.0% w/v CS-NPs. Additionally, the CS/TPP concentration (CS:TPP fixed at a 1:1 ratio) did not impact the degree of crystallinity of the CS-NPs. FTIR analysis confirmed the incorporation of TPP with CS and an increase in hydrogen bonding in more crystalline CS-NPs.

Chitosan-based nanofibrous scaffolds for biomedical and pharmaceutical applications: A comprehensive review

Nowadays, there is a wide range of deficiencies in treatment of diseases. These limitations are correlated with the inefficient ability of current modalities in the prognosis, diagnosis, and treatment of diseases. Therefore, there is a fundamental need for the development of novel approaches to overcome the mentioned restrictions. Chitosan (CS) nanoparticles, with remarkable physicochemical and mechanical properties, are FDA-approved biomaterials with potential biomedical aspects, like serum stability, biocompatibility, biodegradability, mucoadhesivity, non-immunogenicity, anti-inflammatory, desirable pharmacokinetics and pharmacodynamics, etc. CS-based materials are mentioned as ideal bioactive materials for fabricating nanofibrous scaffolds. Sustained and controlled drug release and in situ gelation are other potential advantages of these scaffolds. This review highlights the latest advances in the fabrication of innovative CS-based nanofibrous scaffolds as potential bioactive materials in regenerative medicine and drug delivery systems, with an outlook on their future applications.

Therapeutic applications of sustainable new chitosan derivatives and its nanocomposites: Fabrication and characterization

Chitosan (CS) is a biologically active biopolymer used in different medical applications due to its biodegradability, biocompatibility, and nontoxicity. Nanotechnology is an exciting and quick developing field in medical applications. Nanoparticles have shown great potential in the treatment of cancer and inflammation. In the present work modification of chitosan and its (Ag, Au, or ZnO) nanocomposites by N-aminophthalimide (NAP) occurred through the reaction with epichlorohydrin (ECH) as a crosslinker in the presence or absence of glutaraldehyde (GA) under different reaction conditions using microwave irradiation to give modified chitosan derivatives CS-2, CS-6, and their nanocomposites. Modified chitosan derivatives were characterized using different tools. CS-2 and CS-6 derivatives displayed enhancement of thermal stability and crystallinity compared to chitosan. Additionally, CS-2, CS-6, and their nanocomposites exhibited improvements in antitumor activity against HeLa cancer cells and enzymatic inhibitory against trypsin and α-chymotrypsin enzymes compared to chitosan. However, CS-2 revealed the highest cell growth inhibition% toward HeLa cells (89.02 ± 1.46 %) and the enzymatic inhibitory toward α-chymotrypsin enzyme (17.13 ± 1.59 %). Furthermore, CS-Au-2 showed the highest enzymatic inhibitory against trypsin enzyme (28.14 ± 1.76 %). These results suggested that the new chitosan derivatives CS-2, CS-6, and their nanocomposites could be a platform for medical applications against HeLa cells, trypsin, and α-chymotrypsin enzymes.

Recent advances in chitosan-based materials; The synthesis, modifications and biomedical applications

The attention to polymer-based biomaterials, for instance, chitosan and its derivatives, as well as the techniques for using them in numerous scientific domains, is continuously rising. Chitosan is a decomposable naturally occurring polymeric material that is mostly obtained from seafood waste. Because of its special ecofriendly, biocompatible, non- toxic nature as well as antimicrobial properties, chitosan-based materials have received a lot of interest in the field of biomedical applications. The reactivity of chitosan is mainly because of the amino and hydroxyl groups in its composition, which makes it further fascinating for various uses, including biosensing, textile finishing, antimicrobial wound dressing, tissue engineering, bioimaging, gene, DNA and drug delivery and as a coating material for medical implants. This study is an overview of the different types of chitosan-based materials which now a days have been fabricated by applying different techniques and modifications that include etherification, esterification, crosslinking, graft copolymerization and o-acetylation etc. for hydroxyl groups' processes and acetylation, quaternization, Schiff's base reaction, and grafting for amino groups' reactions. Furthermore, this overview summarizes the literature from recent years related to the important applications of chitosan-based materials (i.e., thin films, nanocomposites or nanoparticles, sponges and hydrogels) in different biomedical applications.

In Silico Investigation on the Molecular Behavior and Structural Stability of the Rosette Nanotubes as the Drug Vehicles for Paclitaxel, an Anti-Cancer Drug

Most anticancer drugs affect healthy cells in addition to cancer cells, causing severe side effects. Targeted delivery by nano-based drug delivery systems (NDDS) can reduce these severe side effects while maintaining therapeutic efficacy. This work introduced rosette nanotube (RNT) as a potential drug vehicle for paclitaxel (PTX) due to its self-assembling property, biocompatibility, amphiphilicity, and low toxicity. Molecular dynamics (MD) simulations aided with molecular mechanics Poisson Boltzmann surface area (MMPBSA) analysis are used here to investigate the molecular behavior and the loading energetics of each type of RNT (K1, xK1, and iEt-xK1) with PTX. Analysis showed that the most probable configuration of PTX is on either end of each RNT. The binding free energies (-117.74 to -69.29 kJ/mol) when PTX is closer to one end were stronger than when it is in the inner channel (-53.51 to -40.88 kJ/mol). The latter alludes to the encapsulation of the PTX by each RNT. Thus, loading is possible by encapsulation during the self-assembly process given the favorable estimated binding free energies. Based on the results, RNT has potential as a drug vehicle for PTX, which warrants further investigation.

Hybrid chitosan/molecularly imprinted polymer hydrogel beads doped with iron for selective ibuprofen adsorption

Pharmaceutical pollutants are a group of emerging contaminants frequently found in water streams. In this study, the composite chitosan beads with incorporated molecularly imprinted polymers (monoliths or microparticles) and iron(III) hydroxide were fabricated to remove ibuprofen from aqueous solutions. The adsorptive properties were investigated in different conditions to evaluate the influence of solution pH, adsorbent dose, ibuprofen initial concentration, adsorption time, and temperature. The highest adsorption capacity (79.41 mg g-1), about twice as large as that for the chitosan beads without polymers (39.42 mg g-1), was obtained for the ones containing monoliths imprinted with ibuprofen. The theoretical maximum adsorption capacity of 103.93 mg g-1 was obtained based on the experiments in optimal pH 5. The adsorption of ibuprofen on the hybrid hydrogel beads followed the Freundlich isotherm and pseudo-second-order kinetic models. The process was found as endothermic and thermodynamically spontaneous. The adsorbent with a molecularly imprinted polymer retained its selectivity in the presence of other molecules. The imprinted cavities, chitosan functional groups, and iron hydroxide were presumably responsible for interactions with ibuprofen molecules. Additionally, the effectiveness of the adsorbent did not change significantly in real water samples and remained at a satisfactory level for up to four desorption-adsorption cycles.

Magnetic chitosan oligomer-sulfonate-stearic acid triple combination as cisplatin carrier for site-specific targeted on MCF-7 cancer cells: Preparation, characterization and in vitro experiments

In this study, a new amphiphilic target-specific adsorbent, chitosan oligomer-sulfonate-stearic acid triple combination (S-Cho-SA), and magnetic chitosan oligomer-sulfonate-stearic acid triple combination (M-S-Cho-SA) by oleic acid (OA)-modified Fe3 O4 via hydrophobic interaction are fabricated. By modifying the nanoparticle surfaces and having the ability to magnetically allow the target region, these particles attract attention as important particles used in targeting mechanisms in cancer therapy. With magnetic nanoparticles and an external magnetic field, it is possible to transport therapeutic agents to the target site and keep them in the desired effect zone for a longer period of time. These new adsorbents are characterized by scanning electron microscopy (SEM), attenuated total reflection Fourier transform infrared (ATR FT-IR) spectroscopy, nuclear magnetic resonance (NMR), X-ray diffraction (XRD), vibrating sample magnetometer (VSM), and thermogravimetric analysis (TG/DTA). After chemical characterization, it is complexed with cisplatin (CDDP). The magnetic adsorbents were loaded with high efficiency (>50%), and the release experiments exhibited that cisplatin is released more at pH 4.5 compared with pH 7.4 at 37°C. It showed better drug release results under a magnetic field for magnetic adsorbents (36% for pH 4.5 and 3.6% for pH 7.4). The biocompatibility of the prepared adsorbents was demonstrated via the XTT assay in MCF-7 cell lines. The results also exhibited that S-Cho-SA and M-S-Cho-SA were biocompatible, and free cisplatin and cisplatin-complexed adsorbents showed an antiproliferative effect. The results showed that these new cisplatin-loaded (M-S-Cho-SA) nanoparticles are good candidates for thermotherapy in cancer treatment in the future, as they can provide selectivity by site-specific targeting and hold onto an alternative magnetic field due to the magnetic nature of the nanoparticles.

Targeted delivery of a short antimicrobial peptide (CM11) against Helicobacter pylori gastric infection using concanavalin A-coated chitosan nanoparticles

Helicobacter pylori is the cause of most cases of stomach ulcers and also causes some digestive cancers. The emergence and spread of antibiotic-resistant strains of H. pylori is one of the most important challenges in the treatment of its infections. The present study aims to develop a concanavalin A (ConA) coated chitosan (CS) nanocarrier-based drug delivery for the targeted release of peptides to the site of H. pylori infection. Accordingly, chitosan was used as an encapsulating agent for CM11 peptide delivery by applying ionotropic gelation method. Con-A was used for coating CS nanoparticles to target H. pylori. The CS NPs and ConA-CS NPs were characterized by FTIR, dynamic light scattering (DLS), and scanning electron microscopy (SEM). The MIC of CM11-loaded ConA-CS NPs against H. pylori SS1 strain was analyzed in vitro. In order to evaluate the treatment efficiency in vivo, a gastric infection model of H. pylori SS1 strain was established in mice and histopathological studies and IL-1β cytokine assay were performed. Based on the results, the size frequency for CS NPs and ConA-CS NPs was about 200 and 350 nm, respectively. The prepared CM11-loaded ConA-CS NPs exhibited antibacterial activity against H. pylori SS1 strain with a concentration of 32 µg/ml. The highest healing process was observed in synthesized CM11-loaded ConA-CS NPs treatments and a significant decrease in IL-1β was observed. Our findings highlight the potential of chitosan nanoparticles as a drug delivery vehicle in the treatment of gastric infection model of H. pylori SS1 strain.

Amelioration of Cancer Employing Chitosan, Its Derivatives, and Chitosan-Based Nanoparticles: Recent Updates

The limitations associated with the conventional treatment of cancer have necessitated the design and development of novel drug delivery systems based mainly on nanotechnology. These novel drug delivery systems include various kinds of nanoparticles, such as polymeric nanoparticles, solid lipid nanoparticles, nanostructured lipid carriers, hydrogels, and polymeric micelles. Among the various kinds of novel drug delivery systems, chitosan-based nanoparticles have attracted the attention of researchers to treat cancer. Chitosan is a polycationic polymer generated from chitin with various characteristics such as biocompatibility, biodegradability, non-toxicity, and mucoadhesiveness, making it an ideal polymer to fabricate drug delivery systems. However, chitosan is poorly soluble in water and soluble in acidic aqueous solutions. Furthermore, owing to the presence of reactive amino groups, chitosan can be chemically modified to improve its physiochemical properties. Chitosan and its modified derivatives can be employed to fabricate nanoparticles, which are used most frequently in the pharmaceutical sector due to their possession of various characteristics such as nanosize, appropriate pharmacokinetic and pharmacodynamic properties, non-immunogenicity, improved stability, and improved drug loading capacity. Furthermore, it is capable of delivering nucleic acids, chemotherapeutic medicines, and bioactives using modified chitosan. Chitosan and its modified derivative-based nanoparticles can be targeted to specific cancer sites via active and passive mechanisms. Based on chitosan drug delivery systems, many anticancer drugs now have better effectiveness, potency, cytotoxicity, or biocompatibility. The characteristics of chitosan and its chemically tailored derivatives, as well as their use in cancer therapy, will be examined in this review.

Sodium alginate encapsulated iron oxide decorated with thymoquinone nanocomposite induces apoptosis in human breast cancer cells via PI3K-Akt-mTOR pathway

The present study investigated the cytotoxicity and proapoptotic properties of iron oxide-sodium-alginate-thymoquinone nanocomposites against breast cancer MDA-MB-231 cells in vitro and in silico. This study used chemical synthesis to formulate the nanocomposite. Electron microscopies such as scanning (SEM) and transmission (TEM), Fourier transform infrared (FT-IR), Ultraviolet-Visible, Photoluminescence spectroscopy, selected area (electron) diffraction (SAED), energy dispersive X-ray analysis (EDX), and X-ray diffraction studies (XRD) were used to characterize the synthesized ISAT-NCs and the average size of them was found to be 55 nm. To evaluate the cytotoxic, antiproliferative, and apoptotic potentials of ISAT-NCs on MDA-MB-231 cells, MTT assays, FACS-based cell cycle studies, annexin-V-PI staining, ELISA, and qRT-PCR were used. PI3K-Akt-mTOR receptors and thymoquinone were predicted using in-silico docking studies. Cell proliferation is reduced in MDA-MB-231 cells due to ISAT-NC cytotoxicity. As a result of FACS analysis, ISAT-NCs had nuclear damage, ROS production, and elevated annexin-V levels, which resulted in cell cycle arrest in the S phase. The ISAT-NCs in MDA-MB-231 cells were found to downregulate PI3K-Akt-mTOR regulatory pathways in the presence of inhibitors of PI3K-Akt-mTOR, showing that these regulatory pathways are involved in apoptotic cell death. We also predicted the molecular interaction between thymoquinone and PI3K-Akt-mTOR receptor proteins using in-silico docking studies which also support PI3K-Akt-mTOR signaling inhibition by ISAT-NCs in MDA-MB-231 cells. As a result of this study, we can conclude that ISAT-NCs inhibit the PI3K-Akt-mTOR pathway in breast cancer cell lines, causing apoptotic cell death.

High cancer selectivity and improving drug release from mesoporous silica nanoparticles in the presence of human serum albumin in cisplatin, carboplatin, oxaliplatin, and oxalipalladium treatment

In this project, drug release was examined based on the adsorption of cisplatin, carboplatin, oxaliplatin, and oxalipalladium on aminated mesoporous silica nanoparticles (N-HMSNs) and human serum albumin (HSA). These compounds were characterized by different techniques where three clinical Pt-drugs, cisplatin, carboplatin, oxaliplatin, plus oxalipalladium were loaded and investigated for release. Based on loading analysis, the loading ability of the mentioned metallodrug on N-HMSNs was dependent on the nature of the drug structure as well as hydrophobic or hydrophilic interactions. Different adsorption and release profiles were observed for all mentioned compounds via dialysis and ICP method analysis. Although the maximum to minimum loading occurred for oxalipalladium, cisplatin, and oxaliplatin to carboplatin, respectively, release from a surface with greater control belonged to carboplatin to cisplatin systems in the absence and presence of HSA to 48 hours due to weak interaction for carboplatin drug. The quick release of all mentioned compounds from the protein level at high doses of the drug during chemotherapy occurred very fast within the first 6 hours. In addition, the cytotoxic activity of both free drugs and drug-loaded@N-HMSNs samples on cancerous MCF-7, HCT116, A549, and normal HFF cell lines was evaluated by MTT assay. It was found that free metallodrugs exhibited more active cytotoxic behavior on both cancerous and normal cell lines than drug-loaded@N-HMSNs. Data demonstrated that the Cisplatin@N-HMSNs with SI=6.0 and 6.6 for MCF7 and HCT116 cell lines, respectively, and Oxaliplatin@N-HMSNs with SI=7.4 for HCT116 cell line can be good candidates as an anticancer drug with minimal side effects by protecting cytotoxic drugs as well as controlled release and high selectivity.

Surface engineering of chitosan nanosystems and the impact of functionalized groups on the permeability of model drug across intestinal tissue

Surface attributes of nanocarriers are crucial to determine their fate in the gastrointestinal (GI) tract. Herein, we have functionalized chitosan with biochemical moieties including rhamnolipid (RL), curcumin (Cur) and mannose (M). FTIR spectra of functionalized chitosan nanocarriers (FCNCs) demonstrated successful conjugation of M, Cur and RL. The functional moieties influenced the entrapment of model drug i.e., coumarin-6 (C6) in FCNCs with payload-hosting and non-leaching behavior i.e., >91 ± 2.5 % with negligible cumulative release of <2 % for 5 h in KREB, which was further verified in the simulated gastric and intestinal fluids. Consequently, substantial difference in the size and zeta potential was observed for FCNCs with different biochemical moieties. Scanning electron microscopy and atomic force microscopy of FCNCs displayed well-dispersed and spherical morphology. In addition, in vitro cytotoxicity results of FCNCs confirmed their hemocompatibility. In the ex-vivo rat intestinal models, FCNCs displayed a time-dependent-phenomenon in cellular-uptake and adherence. However, apparent-permeability-coefficient and flux values were in the order of C6-RL-FCNCs > C6-M-FCNCs > C6-Cur-FCNCs = C6-CNCs > Free-C6. Furthermore, the transepithelial electrical resistance revealed the FCNCs mediated recovery of membrane-integrity with reversible tight junctions opening. Thus, FCNCs have the potential to overcome the poor solubility and/or permeability issues of active pharmaceutical ingredients and transform the impact of functionalized-nanomedicines in the biomedical industry.