Design of prodrugs to enhance colonic absorption by increasing lipophilicity and blocking ionization

Characterization of Pro-Drug Metabolism and Drug Permeability Kinetics in a Microphysiological In Vitro Model of the Human Small Intestinal Barrier Incorporating Mucus-Generating Cells Coupled with LC-MS/MS Analysis

A micro-physiological model of the human small intestinal barrier incorporating mucus-generating cells has been developed. The established barrier was utilized to assess the absorption kinetics of three selected therapeutic compounds: Doxycycline, Ganciclovir, and its prodrug Valganciclovir, following the implementation of a thorough LC-MS/MS validation protocol. The co-culture of Caco-2 cells, representing absorptive enterocytes, and HT-29 MTX cells, modeling goblet cells, enabled the in-situ generation of a sufficiently thick mucus layer covering the entire cell monolayer. The presence of HT-29 MTX cells, which exhibit weaker tight junctions than enterocytes, contributed to the observed lower transepithelial electrical resistance (TEER) and higher FITC-dextran flux. The permeability of all the compounds was higher when tested in the co-culture system containing mucus-generating cells, compared to the Caco-2 monoculture, demonstrating the impact of mucus on intestinal drug transport kinetics. The permeability of ganciclovir following its generation from the prodrug valganciclovir was significantly higher than the permeability of ganciclovir itself, as the active metabolite ganciclovir exhibited an enhanced transport rate compared to when administered without metabolic activation. The developed microfluidic-based intestinal barrier model has demonstrated the capability to reliably simulate drug absorption and prodrug metabolism, and its impact on drug permeation kinetics across the small intestine.

Resistance to Antihypertensive Drugs: Is Gut Microbiota the Missing Link?

Microbiota colonization begins at birth and continuously reshapes throughout the course of our lives, resulting in tremendous interindividual heterogeneity. Given that the gut microbiome, similar to the liver, houses many categories of catalytic enzymes, there is significant value in understanding drug-bacteria interactions. The discovery of this link could enhance the therapeutic value of drugs that would otherwise have a limited or perhaps detrimental effect on patients. Resistant hypertension is one such subset of the hypertensive population that poorly responds to antihypertensive medications, resulting in an increased risk for chronic cardiovascular illnesses and its debilitating effects that ultimately have a detrimental impact on patient quality of life. We recently demonstrated that the gut microbiota is involved in the metabolism of antihypertensive drugs and thus contributes to the pathophysiology of resistant hypertension. Due to a lack of knowledge of the mechanisms, novel therapeutic approaches that account for the gut microbiota may allow for better therapeutic outcomes in resistant hypertension. Therefore, the purpose of this review is to summarize our current, albeit limited, understanding of how the gut microbiota may possess particular enzymatic activities that influence the efficacy of antihypertensive drugs.

Investigation of cannabidiol gastro retentive tablets based on regional absorption of cannabinoids in rats

The cannabis plant has been widely researched for many therapeutic indications and found to be effective in many chronic conditions such as epilepsy, neuropathic or chronic pain and more. However, biased opinion against compounds of the plant, regulatory as well as compounding challenges have led to very few approved cannabinoid medicinal products. Those formulations which are approved are dosed several times a day, creating an unmet need for controlled release (CR) formulations of cannabinoids. Conventional CR formulations rely on prolonged absorption of the drug, including absorption from the colon. The purpose of this work is to investigate regional absorption of major cannabinoids THC and CBD from the colon and develop a suitable CR formulation. As hypothesized by researchers, THC and CBD have poor absorption from the colon compared to small intestine, suggesting that these compounds have a narrow absorption window. The suggested CR formulation examined in-vitro was a floating gastro retentive tablet based on egg albumin matrix, gas generating agents and surfactants. In-vivo investigation of CBD containing formulation in the freely moving rat model proved a prolonged absorption phase with a substantial increase in bioavailability compared to CBD solution. The findings of this paper answer a crucial question regarding potential application of CR dosage forms for cannabinoids and shed light on the regional intestinal absorption of these compounds. Ultimately, these results cement the way for future development of cannabinoid gastro retentive dosage forms.

Molecular modeling approaches of selective adenosine receptor type 2A agonists as potential anti-inflammatory drugs

Adenosine A_2A receptor (A_2AR) is the predominant receptor in immune cells, where its activation triggers cAMP-mediated immunosuppressive signaling and the underlying inhibition of T cells activation and T cells-induced effects mediated by cAMP-dependent kinase proteins mechanisms. In this study, were used ADME/Tox, molecular docking and molecular dynamics simulations to investigate selective adenosine A_2AR agonists as potential anti-inflammatory drugs. As a result, we obtained two promising compounds (A and B) that have satisfactory pharmacokinetic and toxicological properties and were able to interact with important residues of the A_2AR binding cavity and during the molecular dynamics simulations were able to keep the enzyme complexed.Communicated by Ramaswamy H. Sarma.

Recent strategies towards the surface modification of liposomes: an innovative approach for different clinical applications

Liposomes are very useful biocompatible tools used in diverse scientific disciplines, employed for the vehiculation and delivery of lipophilic, ampiphilic or hydrophilic compounds. Liposomes have gained the importance as drug carriers, as the drugs alone have limited targets, higher toxicity and develop resistance when used in higher doses. Conventional liposomes suffer from several drawbacks like encapsulation inefficiencies and partially controlled particle size. The surface chemistry of liposome technology started from simple conventional vesicles to second generation liposomes by modulating their lipid composition and surface with different ligands. Introduction of polyethylene glycol to lipid anchor was the first innovative strategy which increased circulation time, delayed clearance and opsonin resistance. PEGylated liposomes have been found to possess higher drug loading capacity up to 90% or more and some drugs like CPX-1 encapsuled in such liposomes have increased the disease control up to 73% patients suffering from colorectal cancer. The surface of liposomes have been further liganded with small molecules, vitamins, carbohydrates, peptides, proteins, antibodies, aptamers and enzymes. These advanced liposomes exhibit greater solubility, higher stability, long-circulating time and specific drug targeting properties. The immense utility and demand of surface modified liposomes in different areas have led their way to the modern market. In addition to this, the multi-drug carrier approach of targeted liposomes is an innovative method to overcome drug resistance while treating ceratin tumors. Presently, several second-generation liposomal formulations of different anticancer drugs are at various stages of clinical trials. This review article summarizes briefly the preparation of liposomes, strategies of disease targeting and exclusively the surface modifications with different entities and their clinical applications especially as drug delivery system.

Ion-pair approach coupled with nanoparticle formation to increase bioavailability of a low permeability charged drug

Atenolol is a drug widely used for the treatment of hypertension. However, the great drawback it presents is a low bioavailability after oral administration. To obtain formulations that allow to improve the bioavailability of this drug is a challenge for the pharmaceutical technology. The objective of this work was to increase the rate and extent of intestinal absorption of atenolol as model of a low permeability drug, developing a double technology strategy. To increase atenolol permeability an ion pair with brilliant blue was designed and the sustained release achieved through encapsulation in polymeric nanoparticles (NPs). The in vitro release studies showed a pH-dependent release from NPs, (particle size 437.30 ± 8.92) with a suitable release profile of drug (atenolol) and counter ion (brilliant blue) under intestinal conditions. Moreover, with the in vivo assays, a significant increase (2-fold) of atenolol bioavailability after administering the ion-pair NPs by oral route was observed. In conclusion, the combination of ion-pair plus polymeric NPs have proved to be a simple and very useful approach to achieve a controlled release and to increase the bioavailability of a low permeability charged drugs.

Discovery of 2-Pyridinone Aminals: A Prodrug Strategy to Advance a Second Generation of HIV-1 Integrase Strand Transfer Inhibitors

The search for new molecular constructs that resemble the critical two-metal binding pharmacophore required for HIV integrase strand transfer inhibition represents a vibrant area of research within drug discovery. Here we present the discovery of a new class of HIV integrase strand transfer inhibitors based on the 2-pyridinone core of MK-0536. These efforts led to the identification of two lead compounds with excellent antiviral activity and preclinical pharmacokinetic profiles to support a once-daily human dose prediction. Dose escalating PK studies in dog revealed significant issues with limited oral absorption and required an innovative prodrug strategy to enhance the high-dose plasma exposures of the parent molecules.