Preparation and characterisation of silica-based nanoparticles for cisplatin release on cancer brain cells

Therapeutic potential of silica nanoparticles, cisplatin, and quercetin on ovarian cancer: In vivo model

The present study evaluated the effect of silica nanoparticles, quercetin, and cisplatin against ovarian cancer. Cisplatin is a potent antineoplastic agent but has greater toxicity against cancer. Quercetin is a powerful flavonoid with remarkable anti-cancer activity due to its anti-apoptotic nature. Forty female albino rats were randomly divided into eight groups, with five rats per group. Group 1 (G1) was normal control, G2 received Carboxymethylcellulose; G3 was the normal control and treated with quercetin, G4 was given silica nanoparticles, G5 was treated with cisplatin. G6 was the tumor control. Tumor induction was done by 7, 12-dimethylbenz (a) anthracene (DMBA), G7 was treated with quercetin-cisplatin-silica nanoparticles, and in G8 quercetin-cisplatin silica nanoparticles were used to treat the induced tumor. Chemically synthesized silica nanoparticles were characterized by scanning electron microscopy (SEM), energy dispersive X-ray (EDX), and Fourier Transform Infrared (FTIR). After the treatment, animals were sacrificed and tested for biochemical and hormonal assays. G6 displayed increased body weight and a significant rise in CA125 as compared to G1. G6 also exhibited an altered hormonal profile, with a particular increase in estrogen, FSH, and testosterone, along with reduced LH and progesterone levels. Lipid profile, liver enzymes, and renal parameters (urea and creatinine) increased in G6, but G8 significantly ameliorated all damaging effects of DMBA as observed in G6. The current study revealed that silica nanoparticles combined with cisplatin and quercetin demonstrated greater protection against drastic changes induced by carcinogens in ovarian cancer mice models.

Platinum as both a drug and its modulator - Do platinum nanoparticles influence cisplatin activity?

Breast cancer was the most frequent cause of cancer death in females in 2022. Despite the development of personalized therapies, chemotherapy frequently remains the only available treatment method. However, the administration of classic antineoplastic drugs, like cisplatin (CDDP), often causes severe side effects and may lead to drug resistance making the therapy inefficient. Therefore, there is a great need for new, effective treatment regimens development. For this reason, we applied platinum nanoparticles (PtNPs) to verify if they can influence the CDDP activity with particular emphasis on the differences due to nanoparticles' sizes. We employed a broad spectrum of physicochemical methods, including Dynamic Light Scattering, Atomic Force Microscopy, Isothermal Titration Calorimetry, Fourier Transform Infrared Spectroscopy, and Near Infrared Spectroscopy and also Differential Scanning Calorimetry, to characterize the possible interactions between nanoparticles and CDDP. Moreover, the impact of PtNPs on CDDP biological activity was investigated using the Ames mutagenicity test on Salmonella enterica serovar Typhimurium TA102 and MTT assay on two breast cancer cell lines MDA-MB-231 and SKBR3. The obtained results revealed PtNPs direct interactions with CDDP dependent on the nanoparticles' size. Despite the lack of explicit confirmation of PtNPs aggregation by AFM imaging and DLS, further physicochemical methods indicated structural changes between nanoparticles alone and PtNPs-CDDP mixtures. Moreover, the biological assays confirmed that PtNPs decrease CDDP mutagenicity and also slightly increase its cytotoxicity on the chosen cell lines. The latter effects are ambiguous, nevertheless, provide a valuable basis for further research.

Nanocarriers in glioblastoma treatment: a neuroimmunological perspective

Glioblastoma multiforme (GBM) is the most fatal brain tumor with a poor prognosis with current treatments, mainly because of intrinsic resistance processes. GBM is also referred to as grade 4 astrocytoma, that makes up about 15.4 % of brain cancers globally as well as 60-75 % of astrocytoma. The most prevalent therapeutic choices for GBM comprise surgery in combination with radiotherapy and chemotherapy, providing patients with an average survival of 6-14 months. Nanocarriers provide various benefits such as enhanced drug solubility, biocompatibility, targeted activity, as well as minimized side effects. In addition, GBM treatment comes with several challenges such as the presence of the blood-brain barrier (BBB), blood-brain tumor barrier (BBTB), overexpressed efflux pumps, infiltration, invasion, drug resistance, as well as immune escape due to tumor microenvironment (TME) and cancer stem cells (CSC). Recent research has focused on nanocarriers due to their ability to self-assemble, improve bioavailability, provide controlled release, and penetrate the BBB. These nano-based components could potentially enhance drug accumulation in brain tumor tissues and reduce systemic toxicity, making them a compelling solution for GBM therapy. This review captures the complexities associated with multi-functional nano drug delivery systems (NDDS) in crossing the blood-brain barrier (BBB) and targeting cancer cells. In addition, it presents a succinct overview of various types of targeted multi-functional nano drug delivery system (NDDS) which has exhibited promising value for improving drug delivery to the brain.

Nanoarchitectonics: Complexes and Conjugates of Platinum Drugs with Silicon Containing Nanocarriers. An Overview

The development in the area of novel anticancer prodrugs (conjugates and complexes) has attracted growing attention from many research groups. The dangerous side effects of currently used anticancer drugs, including cisplatin and other platinum based drugs, as well their systemic toxicity is a driving force for intensive search and presents a safer way in delivery platform of active molecules. Silicon based nanocarriers play an important role in achieving the goal of synthesis of the more effective prodrugs. It is worth to underline that silicon based platform including silica and silsesquioxane nanocarriers offers higher stability, biocompatibility of such the materials and pro-longed release of active platinum drugs. Silicon nanomaterials themselves are well-known for improving drug delivery, being themselves non-toxic, and versatile, and tailored surface chemistry. This review summarizes the current state-of-the-art within constructs of silicon-containing nano-carriers conjugated and complexed with platinum based drugs. Contrary to a number of other reviews, it stresses the role of nano-chemistry as a primary tool in the development of novel prodrugs.

Lipid, polymeric, inorganic-based drug delivery applications for platinum-based anticancer drugs

The three main FDA-approved platinum drugs in chemotherapy such as carboplatin, cisplatin, and oxaliplatin are extensively applied in cancer treatments. Although the clinical applications of platinum-based drugs are extremely effective, their toxicity profile restricts their extensive application. Therefore, recent studies focus on developing new platinum drug formulations, expanding the therapeutic aspect. In this sense, recent advances in the development of novel drug delivery carriers will help with the increase of drug stability and biodisponibility, concomitantly with the reduction of drug efflux and undesirable secondary toxic effects of platinum compounds. The present review describes the state of the art of platinum drugs with their biological effects, pre- and clinical studies, and novel drug delivery nanodevices based on lipids, polymers, and inorganic.

Emerging Nanopharmaceuticals and Nanonutraceuticals in Cancer Management

Nanotechnology is the science of nanoscale, which is the scale of nanometers or one billionth of a meter. Nanotechnology encompasses a broad range of technologies, materials, and manufacturing processes that are used to design and/or enhance many products, including medicinal products. This technology has achieved considerable progress in the oncology field in recent years. Most chemotherapeutic agents are not specific to the cancer cells they are intended to treat, and they can harm healthy cells, leading to numerous adverse effects. Due to this non-specific targeting, it is not feasible to administer high doses that may harm healthy cells. Moreover, low doses can cause cancer cells to acquire resistance, thus making them hard to kill. A solution that could potentially enhance drug targeting and delivery lies in understanding the complexity of nanotechnology. Engineering pharmaceutical and natural products into nano-products can enhance the diagnosis and treatment of cancer. Novel nano-formulations such as liposomes, polymeric micelles, dendrimers, quantum dots, nano-suspensions, and gold nanoparticles have been shown to enhance the delivery of drugs. Improved delivery of chemotherapeutic agents targets cancer cells rather than healthy cells, thereby preventing undesirable side effects and decreasing chemotherapeutic drug resistance. Nanotechnology has also revolutionized cancer diagnosis by using nanotechnology-based imaging contrast agents that can specifically target and therefore enhance tumor detection. In addition to the delivery of drugs, nanotechnology can be used to deliver nutraceuticals like phytochemicals that have multiple properties, such as antioxidant activity, that protect cells from oxidative damage and reduce the risk of cancer. There have been multiple advancements and implications for the use of nanotechnology to enhance the delivery of both pharmaceutical and nutraceutical products in cancer prevention, diagnosis, and treatment.