Current Medicinal Chemistry - Volume 29, Issue 38, 2022

There is a wide variety of neurodegenerative diseases, among which frontotemporal dementia stands out. These are the second most frequent cause of dementia in the world and demand the search for an effective treatment. This disease is linked to the abnormal behavior of proteins, which group together to form insoluble aggregates. It has been shown that the tau protein and TDP-43 are the main proteins involved in these pathologies. This article details 11 compounds already used in different neuropathologies, which may serve as potential drugs against these proteins. The mechanism of how most of these molecules inhibited the tau and TDP-43 aggregation process was highlighted. Importantly, Curcumin, Proanthocyanidin B2, Oleocanthal, Oleuropein Aglycone, Thionine, and Resveratrol had been reported as direct inhibitors of tau. While 4-aminoquinoline, Dimethoxycurcumin, and Auranofin directly inhibited TDP-43. Epigallocatechin- 3- gallate and Methylene Blue were described as tau and TDP-43 inhibitors. In this review, it is proposed that future research could elucidate the detailed inhibition mechanisms of these compounds to obtain relevant data to advance in treatments search for these coexisting proteins in frontotemporal dementia.

The COVID-19 outbreak caused by the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) continues to have high incidence and mortality rate globally. To meet the increasingly growing demand for new therapeutic drugs and vaccines, researchers are developing different diagnostic techniques focused on screening new drugs in clinical use, developing an antibody targeting a SARS-CoV-2 receptor, or interrupting infection/replication mechanisms of SARS-CoV-2. Although many prestigious research publications are addressing this subject, there is no open access platform where all experimental techniques for COVID-19 research can be seen as a whole. Many researchers have accelerated the development of in silico methods, high-throughput screening techniques, and in vitro assays. This development has played an important role in the emergence of improved, innovative strategies, including different antiviral drug development, new drug discovery protocols, combinations of approved drugs, and setting up new drug classes during the COVID-19 outbreak. Hence, the present review discusses the current literature on these modalities, including virtual in silico methods for instant ligand- and target-driven based techniques, nucleic acid amplification tests, and in vitro models based on sensitive cell cultures, tissue equivalents, organoids, and SARS-CoV-2 neutralization systems (lentiviral pseudotype, viral isolates, etc.). This pack of complementary tests informs researchers about the accurate, most relevant emerging techniques available and in vitro assays allow them to understand their strengths and limitations. This review could be a pioneer reference guide for the development of logical algorithmic approaches for new drugs and vaccine strategies against COVID-19.

Preparations for topical application are highly important for therapeutic and cosmetic use since the skin has an extensive and accessible application area. Among the many advantages, this route avoids the systemic effects of the substances and, therefore, fewer adverse reactions are observed. However, the skin is an organ with a remarkable barrier effect, which can compromise the administration of pharmacologically / cosmetologically active molecules. Thus, the skin permeability of substances is a challenge that is only achieved through the preparation of formulations capable of overcoming that same barrier. Nanotechnology was introduced in the pharmaceutical and cosmetic areas to enable the development of systems for the delivery of substances and the optimization of already existing formulations. Among the several benefits and advantages of nanotechnology for topical application is the increased penetration of the drug in the skin, the improvement of the stability of the active, decrease in the active substances (reducing the possible toxic effects and allergic reactions caused by the high concentration of these compounds), and even the intensification of the drug action. This manuscript reviews the topical delivery technologies based on polymeric nanocarriers (PNC) as nanoparticles (NP) and nanogels (NG) and their benefits for better efficacy in most common cutaneous disorders. It starts with skin properties, the aspects for the penetration of active ingredients in the skin and cutaneous penetration challenges, followed by a summary of strategies for skin penetration/permeation of drugs. Then, the focus of the current research was to review NPs and NGs explored for skin disorders management published during the last years.

The microenvironment of the tumor cells is central to its phenotypic modification. One of the essential elements of this milieu is thermal regulation. An augment in local temperature has been reported to augment the tumor cell's responsiveness to chemoand radiation treatment. Cold shock proteins are RNA/DNA binding proteins identified by the existence of one or more cold shock domains. In humans, the best studied components of this group of proteins are called Y-box binding proteins, such as Y-box binding protein-1 (YB-1), but several other proteins have been recognized. Biological functions of these proteins extend from the control of transcription, translation and splicing to the regulation of exosomal RNA content. Several findings correlate an altered cold shock protein expression profile with tumor diseases. In this review we summarize the data for a causative participation of cold shock proteins in cancer onset and diffusion. Furthermore, the possible use of cold shock proteins for diagnostics, prognosis, and as targets for cancer treatment is exposed.

Since the inception of antibodies as magic bullets for targeting antigens with high specificity for various in vitro and in-vivo detection and therapy applications, the field has evolved, and remarkable success has been achieved not only in the methods of development of these targeting agents but also in their applications. The utilization of these moieties for the development of antibody-based radiopharmaceuticals for diagnostic and therapy (theranostic) purposes has resulted in the availability of various cancer-targeting agents suitable for clinical applications. The high affinity and specificity of antibodies towards the target antigens overexpressed on tumors render them an excellent carrier molecules for radionuclide delivery. Although intact antibodies have high potential as imaging and therapeutic agents, a major drawback of intact antibody-based radionuclide targeting is their slow pharmacokinetics and poor penetration into solid tumors. In contrast to large intact antibodies, engineered antibody fragments, such as minibodies, diabodies, single-chain variable region fragments (scFvs), nanobodies, and non-antibody protein scaffolds-based moieties, retain the specificities and affinities of intact antibodies in addition to improved pharmacokinetics for imaging and therapy of solid tumors. These engineered carrier molecules are not only amenable for simple and robust radiolabeling procedures but also provide high contrast images with minimal radiotoxicity to vital organs. However, in various instances, rapid clearance with sub-optimal tumor accumulation, limiting renal dose, and cross-reactivity of these radiolabeled engineered smaller molecules have also been observed. Herein, we review current knowledge of the recent methods for the development of antibody-based targeting moieties, the suitability of various engineered formats for targeting tumors, and radiolabeling strategies for the development of radioformulations. We discuss promising antibody-based and non-antibody- based affibody radiopharmaceuticals reported for clinical applications. Finally, we highlight how emerging technologies in antibody engineering and drug development can be amalgamated for designing novel strategies for cancer imaging and therapy.