Mini Reviews in Medicinal Chemistry - Volume 23, Issue 15, 2023

Discoidin domain receptor (DDR) 1, a collagen binding receptor kinase, is an intensively researched therapeutic target for cancer, fibrosis and other diseases. The majority of early known DDR1 inhibitors targeted the ATP binding pocket of this enzyme that shares structural similarities with other kinase pockets across the biological system. This structural similarity of DDR1 kinase with other protein kinases often leads to “off target “toxicity issues. Understanding of uniqueness in DDR:ATP–phosphate-binding loop (P-loop), DNA encoded library screen, structure-guided optimization studies, and machine learning drug design platforms that come under the umbrella of artificial intelligence has led to the discovery of a new array of inhibitors that are highly selective for DDR1 over DDR2 and other similar kinases. Most of the drug discovery platforms concentrated on the ATP binding region of DDR1 kinase and never looked beyond this region for novel therapeutic options. Recent findings have disclosed the kinase-independent functions of DDR1 in immune exclusion, which resides in the extracellular collagen-binding domain, thus opening avenues for the development of inhibitors that veer away from targeting ATP binding pockets. This recent understanding of the functional modalities of DDR1 opens the complexity of targeting this transmembrane protein as per its functional prominence in the respective disease and thus demands the development of specific novel therapeutics. The perspective gives a short overview of recent developments of DDR1 inhibitors with the aid of the latest technologies, future directions for therapeutic development, and possibility of combinational therapeutic treatments to completely disengage functions of DDR1.

A rising number of researchers are interested in thiophene-based analogs as they have wide possibilities of biological potential in the largely developing chemical world of the heterocyclic moiety. It also occupies a central position in synthetic organic chemistry and is of the highest theoretical and practical importance. It became an important moiety for researchers to discover combinatorial libraries and implement the efforts in search of the lead entity. Moreover, it helps medicinal chemists to improve sophisticated molecules with a broad range of pharmacological activities. Thiophene and its synthetic derivatives are a prominent heterocyclic compound class with intriguing uses in medical chemistry. It has been manifesting to be an effective drug in current respective diseases scenario. It has been discovered that thiophene had an extensive spectrum of pharmacological potential with numerous applications in academic interest, in the pharmaceutical industry, material science, and medicinal chemistry. Antimitotic, antimicrobial, anti-inflammatory, anticonvulsant, antipsychotic, antiarrhythmic, anti-anxiety, antifungal, antioxidant, estrogen receptor regulating, and anti-cancer are one of the pharmacological and physiological activities of thiophene moiety. However, there are some marketed formulations available such as Thiophenfurin, Teniposide, Cefoxitin, Ticaconazole, Sertaconazole, Suprofen, ketotifen, Brinzolamide, Dorzolamide, Tiotropium which contain thiophene nucleus. Thus, in brief, gathering recent data is necessary to comprehend the present scenario of thiophene moiety for scientific research purposes and highlights a broad view of the biological potential of compounds having a thiophene nucleus.

Tumors are a major cause of human mortality worldwide, and the rapid development of nanomaterials (NMs) for tumor therapy and drug delivery has provided new treatment methods. However, NMs’ high immunogenicity, short circulation time, and low specificity limit their application in tumor therapy. In recent years, bionanomaterials using cell membranes have emerged to overcome the shortcomings of monomeric NMs. Cell membrane-encapsulated NMs extracted from multiple cells not only retain the physicochemical properties of NMs but also inherit the biological functions of the source cells, aiding in drug delivery. The combination of the cell membrane and drug-loading NMs offers an efficient and targeted drug delivery system tailored to the tumor microenvironment. The research and application of this method have been widely carried out in the academic field of tumor diagnosis and treatment. This review presents the recent research progress of cell membrane-coated NMs as drug carriers in tumor therapy, including cell membrane extraction methods, encapsulation strategies, and the applications of cell membrane-encapsulated NMs in tumor therapy. We believe that biomimetic nanomaterials will be a promising and novel anticancer strategy in the future, and their wide application will certainly bring vitality to the field of tumor diagnosis and treatment. The combination of membrane and drug-loading nanomaterials embodies a highly efficient and target drug delivery system tailored to the tumor microenvironment, which broadens a new path of drug delivery for future cancer treatment. Meanwhile, it is also a perfect combination and application of biomedical nanomaterials, which is of great significance.

Adaptive responses to stressful stimuli in the environment are believed to restore homeostasis after stressful events. Stress activates the hypothalamic-pituitary-adrenocortical (HPA) axis, which releases glucocorticoids (GCs) into the bloodstream. Recently, agmatine, an endogenous monoamine was discovered to have the potential as a pharmacotherapy for stress. Agmatine is released in response to certain stress conditions, especially those involving GCs, and participates in establishing homeostasis disturbed by stress following GC activation. The therapeutic potential of agmatine for the management of psychological diseases involving stress and depression is promising based on a significant amount of literature. When exogenously applied, agmatine leads to reductions in levels of GCs and counteracts stress-related morphologic, synaptic, and molecular changes. However, the exact mechanism of action by which agmatine modifies the effects resulting from stress hormone secretion is not fully understood. This review aims to present the most possible mechanisms by which agmatine reduces the harmful effects of chronic and acute stress. Several studies suggest chronic stress exposure and repeated corticosteroid treatment lower agmatine levels, contributing to stress-related symptoms. Agmatine acts as an antistress agent by activating mTOR signaling, inhibiting NMDA receptors, suppressing iNOS, and maintaining bodyweight by activating α-2adrenergic receptors. Exogenous administration that restores agmatine levels may provide protection against stress-induced changes by reducing GCs release, stimulating anti-inflammatory processes, and releasing neuroprotective factors, which are not found in all therapies currently being used to treat stress-related disorders. The administration of exogenous agmatine should also be considered a therapeutic element that is capable of triggering a neural protective response that counters the effects of chronic stress. When combined with existing treatment strategies, this may have synergistic beneficial effects.

Background: Viral hemorrhagic fevers (VHFs) are a group of clinical syndromes caused by several different RNA virus families, including several members of the arenavirus, bunyavirus, filovirus, and flavivirus families. VHFs have high mortality rates, and they have been associated with vascular permeability, malaise, fever, variable degrees of hemorrhage, reduced plasma volume, and coagulation abnormalities. To treat such conditions, antigen-presenting cells target dysregulated immune reactions and productive infections. Monocytes and macrophages produce inflammatory cytokines that damage adaptive immunity, while infected dendritic cells fail to mature correctly, compromising adaptive immunity. Inflammation and uncontrolled virus replication are associated with vascular leakage and coagulopathy. Objective: VHF infects both humans and animals and if not treated, causes hemorrhagic manifestations and lethal platelet dysfunction. Besides pharmacological and immunological solutions, the intervention of natural products for VHF management is of great interest. In this review, we gathered current data about the effectiveness of natural products for VHF management. Methods: Data were extracted from Scopus, Google Scholar, PubMed, and Cochrane library in terms of clinical and animal studies published in English between 1981 to February 2022. Results: Several plants from diverse families and species were identified with antiviral activity against VHF. The combination of botanical therapeutics and multitarget synergistic therapeutic effects is now the widely accepted explanation for the treatment of VHF. Most of these herbal therapeutics have shown promising immunomodulatory effects in vivo and in vitro VHF models. They can probably modulate the immune system in VHF-infected subjects mainly by interfering with certain inflammatory mediators involved in various infectious diseases. Conclusion: Natural, in particular, herbal sources can be valuable for the management of various VHFs and their related complications.