How can Fullerenes Help in the Treatment of Diseases? A Review Article on Pharmaceutical Usage of Fullerenes as Carriers.

Drug degradation is a process that can render pharmaceuticals inactive without causing any visible distortion. This can disrupt the therapeutic process, and on occasion, when the process produces toxic metabolites, it can have much more fatal consequences. Light is one of the most significant components that might cause deterioration, and several attempts have been made to improve and increase the practical photosensitizing of nano-scaled pharmaceuticals. Considering this, the insolubility and aggregating qualities of fullerenes have received significant attention. Fullerene is considered to have a unique carbon structure. In order to gain improved water solubility and biocompatible properties, fullerenes have been combined with water-soluble, biodegradable, and adjustable polymers. More specifically, these linkers exhibit increased tumor cell identification and greater tumor cell suppression when linked to therapeutic ligands (tumor-targeting) or stimuliresponsive polymers. According to scientific studies, fullerene-drug combinations can be used in certain complex diseases, like infectious and viral types. Several studies have combined fullerenes into nano-emulsions or liposomes for various pharmacological objectives. In the current work, fullerene/polymer nanomaterials are discussed for potential therapeutic techniques for the treatment of various diseases, particularly cancer and AIDS. According to the research studies, fullerene is a suitable element with outstanding physical and chemical properties that has a wide range of potential applications in the pharmaceutical industry, including drug delivery system design, photodynamic cancer therapy, and antioxidant therapy.

The effect of PEGylation on drugs' pharmacokinetic parameters; from absorption to excretion.

When drugs enter the field of human life, they face problems in the area of delivery, delivery to the destination, and metabolism. These problems can cause reducing drug's therapeutic effect and even increase its side effects. Together, these cases can reduce the patient's compliance with the treatment and complicate the treatment process. Much work has been done to solve or at least reduce these problems. For example, using different forms of a single drug molecule (like Citalopram and Escitalopram); a bit changes in the drug's molecule like Meperidine and α-Prodine, and using carriers (like Tigerase®). PEGylation is a recently presented method that can use for many targets. Poly Ethylene Glycol or PEG is a polymer that can attach to drugs by using different methods and causing sustained release, controlled metabolism, targeted delivery, and other cases. All of them, although they will not necessarily lead to an increase in the effect of the drug, will lead to the improvement of the treatment process in certain ways. In this article, the team of authors has tried to collect and carefully review the best cases based on the PEGylation of drugs that can help the readers of this article.

Different Types of Naturally based Drug Delivery Carriers: An Explanation and Expression of Some Anti-cancer Effects.

Cancer remains one of the leading causes of death worldwide and a major impediment to increasing life expectancy. However, survival rates with average standard cancer treatment strategies have not significantly improved in recent decades, with tumor metastasis, adverse drug reactions, and drug resistance still posing major challenges. Replacement therapies are essential for treating this terrible disease. Recently, there has been a dramatic increase in the use of phytochemical-derived conjugated chemotherapeutic agents due to their biocompatibility, low cytotoxicity, low resistance, and dynamic physiochemical properties that distinguish normal cells in treating various types of cancer. The use of plant-based carriers has many advantages, such as the availability of raw materials, lower cost, lower toxicity in most cases, and greater compatibility with the body's structure compared to chemical and mineral types of carriers. Unfortunately, several challenges complicate the efficient administration of herbal medicines, including physicochemical disadvantages such as poor solubility and instability, and pharmacokinetic challenges such as poor absorption and low bioavailability that can cause problems in clinical trials. Novel delivery systems such as liposomes, phytosomes, nanoparticles, and nanocapsules are more suitable as delivery systems for phytomedicinal components compared to conventional systems. The use of these delivery systems can improve bioavailability, pharmacological activity, prolonged delivery, and provide physical and chemical stability that increases half-life. This article discusses different types of phytocompounds used in cancer treatment.

Oral Insulin Delivery: A Review On Recent Advancements And Novel Strategies.

BACKGROUND: Due to the lifestyle of people in the community in recent years, the prevalence of diabetes mellitus has increased, so New drugs and related treatments are also being developed. INTRODUCTION: One of the essential treatments for diabetes today is injectable insulin forms, which have their problems and limitations, such as invasive and less admission of patients and high cost of production. According to the mentioned issues, Theoretically, Oral insulin forms can solve many problems of injectable forms. METHODS: Many efforts have been made to design and introduce Oral delivery systems of insulin, such as lipid-based, synthetic polymer-based, and polysaccharide-based nano/microparticle formulations. The present study reviewed these novel formulations and strategies in the past five years and checked their properties and results. RESULTS: According to peer-reviewed research, insulin-transporting particles may preserve insulin in the acidic and enzymatic medium and decrease peptide degradation; in fact, they could deliver appropriate insulin levels to the intestinal environment and then to blood. Some of the studied systems increase the permeability of insulin to the absorption membrane in cellular models. In most investigations, in-vivo results revealed a lower ability of formulations to reduce BGL than subcutaneous form, despite promising results in in-vitro and stability testing. CONCLUSION: Although taking insulin orally currently seems unfeasible, future systems may be able to overcome mentioned obstacles, making oral insulin delivery feasible and producing acceptable bioavailability and treatment effects in comparison to injection forms.

Polyphenol nanoformulations for cancer therapy: experimental evidence and clinical perspective.

Cancer is defined as the abnormal cell growth that can cause life-threatening malignancies with high financial costs for patients as well as the health care system. Natural polyphenols have long been used for the prevention and treatment of several disorders due to their antioxidant, anti-inflammatory, cytotoxic, antineoplastic, and immunomodulatory effects discussed in the literature; thus, these phytochemicals are potentially able to act as chemopreventive and chemotherapeutic agents in different types of cancer. One of the problems regarding the use of polyphenolic compounds is their low bioavailability. Different types of formulations have been designed for the improvement of bioavailability of these compounds, nanonization being one of the most notable approaches among them. This study aimed to review current data on the nanoformulations of natural polyphenols as chemopreventive and chemotherapeutic agents and to discuss their molecular anticancer mechanisms of action. Nanoformulations of natural polyphenols as bioactive agents, including resveratrol, curcumin, quercetin, epigallocatechin-3-gallate, chrysin, baicalein, luteolin, honokiol, silibinin, and coumarin derivatives, in a dose-dependent manner, result in better efficacy for the prevention and treatment of cancer. The impact of nanoformulation methods for these natural agents on tumor cells has gained wider attention due to improvement in targeted therapy and bioavailability, as well as enhancement of stability. Today, several nanoformulations are designed for delivery of polyphenolic compounds, including nanosuspensions, solid lipid nanoparticles, liposomes, gold nanoparticles, and polymeric nanoparticles, which have resulted in better antineoplastic activity, higher intracellular concentration of polyphenols, slow and sustained release of the drugs, and improvement of proapoptotic activity against tumor cells. To conclude, natural polyphenols demonstrate remarkable anticancer potential in pharmacotherapy; however, the obstacles in terms of their bioavailability in and toxicity to normal cells, as well as targeted drug delivery to malignant cells, can be overcome using nanoformulation-based technologies, which optimize the bioefficacy of these natural drugs.