Current Pharmaceutical Design - Volume 30, Issue 41, 2024

In recent years, microbial infections have emerged as a serious global health problem, necessitating the search for novel and effective treatments. Medicinal plants contain phytochemicals that can be used to prevent and treat various infections. Traditional medicinal practices have long relied on the healing properties of herbs, and Nepal is particularly rich in this knowledge. Bioactive compounds found in plants possess antibacterial, antifungal, and antiviral properties, making them a valuable resource for the fight against microbial infections. This review focuses on three medicinal plants native to Nepal, Amomum subulatum, Cymbopogon jwarancusa, and Cinnamomum glaucescens, which contain potent antimicrobial phytochemicals. The traditional uses, bioactive components, and biological activities of these plants are discussed, providing valuable insights into their potential as natural remedies to combat microbial infections.

Wound healing is a complex cascade and is governed through a number of crucial factors. Conventional wound dressing possesses numerous limitations which hinder wound healing process and may result in serious infections and even mortality. A lot of effort have been put in through researchers to develop a multifaceted dressing which can address these limitations and facilitate accelerated wound healing. Among various newly developed dressings, electrospun hydrogel nanofibers have emerged as a promising class of biomaterials for advanced wound care and tissue engineering applications. These biomimetic fibers closely mimic the architect of the native extracellular matrix, providing an optimal environment that facilitates cellular proliferation and fast generation required for effective wound healing. Electrospinning offers versatility in precisely controlling fiber attributes such as diameter, alignment, and surface morphology and can entrap a variety of drugs with high efficacy. Recently, such dressings have advanced through the incorporation of smart features such as stimuli-responsive components, real-time wound monitoring sensors, and smart closed-loop systems. The electrospun hydrogels are bestowed with extreme porosity, water-retention attribute, biocompatibility, and modified drug release which make them superior over other wound dressings. The review gives an insight of electrospun hydrogel fibers and their application in wound healing and the studies assessing wound healing potential with underlying mechanisms have been critically analysed. Electrospun hydrogel fibers have significant potential to revolutionize wound care through their biomimetic structure, versatile customization, and capacity for integrating therapeutic and sensing capabilities, outlining future research directions toward next-generation wound care products.

The 21^st century has shown us how rapidly the pandemic can evolve and devastate the life of human beings without differentiating between the continents. Even after the global investment of billions of dollars into the healthcare sector, we are still lacking multiple therapeutics against emerging viruses. World Health Organization (WHO) has listed a number of viruses that could take the form of pandemics at anytime, depending upon their mutations. Among those listed, the SARS-CoV, Ebola, Zika, Nipah, and Chikungunya virus (CHIKV) are the most known viruses in terms of their number of outbreaks. The common feature among these viruses is their RNA-based genome. Developing a new therapeutic candidate for these RNA viruses in a short period of time is challenging. In silico drug designing techniques offer a simple solution to these problems by implementing supercomputers and complicated algorithms that can evaluate the inhibition activity of proposed synthetic compounds without actually doing the bioassays. A vast collection of protein crystal structures and the data on binding affinity are useful tools in this process. Taking this into account, we have summarized the in silico based therapeutic advances against SARS-CoV, Ebola, Zika, Nipah, and CHIKV viruses by encapsulating state-of-art research articles into different sections. Specifically, we have shown that computer-aided drug design (CADD) derived synthetic molecules are the pillars of upcoming therapeutic strategies against emerging and neglected viruses.