RESUMO
Self-assembly provides access to non-covalently synthesized supramolecular materials with distinct properties from a single building block. However, dynamic switching between functional states still remains challenging, but holds enormous potential in material chemistry to design smart materials. Herein, we demonstrate a chemical fuel-mediated strategy to dynamically switch between two distinctly emissive aggregates, originating from the self-assembly of a naphthalimide-appended peptide building block. A molecularly dissolved building block shows very weak blue emission, whereas, in the assembled state (Agg-1), it shows cyan emission through π stacking-mediated excimer emission. The addition of a chemical fuel, ethyl-3-(3-(dimethylamino)propyl)carbodiimide (EDC), converts the terminal aspartic acid present in the building block to an intra-molecularly cyclized anhydride in situ forming a second aggregated state, Agg-2, by changing the molecular packing, thereby transforming the emission to strong blue. Interestingly, the anhydride gets hydrolyzed gradually to reform Agg-1 and the initial cyan emission is restored. The kinetic stability of the strong blue emissive aggregate, Agg-2, can be regulated by the added concentration of the chemical fuel. Moreover, we expand the scope of this system within an agarose gel matrix, which allows us to gain spatiotemporal control over the properties, thereby producing a self-erasable writing system where the chemical fuel acts as the ink.
RESUMO
In this review paper, we have analyzed the potential and issues associated with Pharmacovigilance (PV). The analysis is divided into four sections: background, stakeholders, data sources, and medicinal chemistry. Each section discusses the current state, the future trends, and the best practices of Pharmacovigilance (PV). The main purpose, methods, results, and implications of our analysis are summarized. BACKGROUND: Pharmacovigilance (PV) is the science and practice of monitoring, evaluating, understanding, and preventing adverse drug reactions. Pharmacovigilance (PV) was established by the World Health Organization in response to the thalidomide tragedy of 1961. The main purpose of Pharmacovigilance (PV) is to ensure the safety and efficacy of drugs in clinical practice. Stakeholders: Pharmacovigilance (PV) involves various stakeholders, such as patients, pharmacists, pharmaceutical companies, healthcare professionals, and regulatory authorities. Each stakeholder has a different role and responsibility in reporting, processing, analyzing, and communicating information about adverse drug reactions. Patient engagement is a key factor for enhancing Pharmacovigilance (PV) practices. DATA SOURCES: Pharmacovigilance (PV) relies on data from various sources, such as clinical trials, spontaneous reports, electronic medical records, biomedical literature, and patient-reported data in online health forums. These data sources can provide valuable insights into the real-world use and safety of drugs, as well as the preferences and needs of patients. However, these data sources also pose challenges in terms of quality, validity, reliability, and accessibility. Medicinal Chemistry: Medicinal chemistry is the branch of chemistry that deals with the design, synthesis, and evaluation of new drugs and their biological effects. Medicinal chemistry can enhance Pharmacovigilance (PV) practices by finding new therapeutic indications for existing drugs or compounds that have already been tested for safety and efficacy. Medicinal chemistry also requires careful design and evaluation of covalent inhibitors, bi-substrate inhibitors, stabilizers of protein non-effective conformations, and hydrophobic pocket modifiers to ensure their safety and efficacy. IMPLICATIONS: Pharmacovigilance (PV) is a dynamic and evolving discipline that requires collaboration, regulation, education, and innovation to improve patient safety and care. This review aims to provide a comprehensive overview of the potential and issues associated with Pharmacovigilance (PV) practices.