Thermodynamic and mechanistic analytical effect of albumin coated gold nanosystems for antibiotic drugs binding and interaction with deoxyribonucleic acid

Interaction of solid lipid nanoparticles with bovine serum albumin: physicochemical mechanistic insights

This study investigates the interaction of solid lipid nanoparticles (SLNs) with the transport protein bovine serum albumin (BSA) in terms of thermodynamic signatures, employing both spectroscopic and calorimetric techniques. When nanoparticles are exposed to biological media, proteins are adsorbed on their surfaces, leading to protein corona formation. Therefore, controlling the formation of the protein corona is essential for in vivo therapeutic efficacy. Although SLNs have previously been explored solely as potential nano-carriers for drug delivery, no prior efforts have been made to study their interactions with biomolecules from a biophysical and mechanistic perspective. SLNs are colloidal dispersions of the solid lipid in an aqueous solution stabilized by surfactants. Herein, a hot emulsification methodology was employed to formulate SLNs, and their interactions with BSA were analyzed. The SLNs were characterized using transmission electron microscopy (TEM) and dynamic light scattering (DLS) techniques to obtain information on their size, zeta potential, and shape. Fluorescence data suggested the presence of weak interactions between the SLNs and BSA. Static quenching is confirmed using time-correlated single-photon counting (TCSPC) experiments. Differential scanning calorimetric (DSC) and fluorescence spectroscopic experiments suggest the thermal stabilization of BSA by the SLNs. This stabilization results from the enhancement of the secondary structure of the protein without significantly altering the tertiary structure. Isothermal calorimetry (ITC) results suggest weak interactions between the SLNs and BSA, although not in a site-specific manner. Overall, mechanistic insights into lipid nanoparticle-protein interactions obtained from such studies efficiently overcome the hurdles associated with targeted drug delivery.

Antimicrobial Feature of Nanoparticles in the Antibiotic Resistance Era: From Mechanism to Application

The growth of nanoscale sciences enables us to define and design new methods and materials for a better life. Health and disease prevention are the main issues in the human lifespan. Some nanoparticles (NPs) have antimicrobial properties that make them useful in many applications. In recent years, NPs have been used as antibiotics to overcome drug resistance or as drug carriers with antimicrobial features. They can also serve as antimicrobial coatings for implants in different body areas. The antimicrobial feature of NPs is based on different mechanisms. For example, the oxidative functions of NPs can inhibit nucleic acid replication and destroy the microbial cell membrane as well as interfere with their cellular functions and biochemical cycles. On the other hand, NPs can disrupt the pathogens' lifecycle by interrupting vital points of their life, such as virus uncoating and entry into human cells. Many types of NPs have been tested by different scientists for these purposes. Silver, gold, copper, and titanium have shown the most ability to inhibit and remove pathogens inside and outside the body. In this review, the authors endeavor to comprehensively describe the antimicrobial features of NPs and their applications for different biomedical goals.

Binding and displacement study of gentamicin, 5-fluorouracil, oxytetracycline and rolitetracycline with (BSA: Drug2) complex using spectroscopic and calorimetric techniques: Biophysical approach

Understanding of energetics of interactions between drug and protein is essential in pharmacokinetics and pharmacodynamics study. The binding affinity (K) helps in investigating how tightly or loosely drug is bound to protein. The binding, displacement, conformational change and stability study of drugs- gentamicin (GM), 5-fluorouracil (5FU), oxytetracycline (OTC) and rolitetracycline (RTC) with bovine serum albumin (BSA) has been carried out in presence of each other drug by fluorescence, UV-visible spectroscopy, molecular docking, circular dichroism techniques and thermal denaturation method. The site marker study and docking methods have confirmed that 5FU and GM are able to bind at site 1 and OTC and RTC at site II of BSA. The order of their binding affinities with BSA for the binary system were as GM <5FU < OTC < RTC with the order of 102 < 103 < 105 < 105-6 M-1. The displacement study has shown that higher affinity drug decreases the equilibrium constant of another drug already in bound state with BSA if both these drugs are having the same binding site. Therefore 5FU, GM (binding site 1) drugs were not able to displace OTC and RTC (binding site 2) and vice-versa as they are binding at two different sites. The binding constant values were found to be decreasing with increasing temperature for all the systems involved which suggests static or mixed type of quenching, however can only confirmed with the help of TCSPC technique. The ΔG0 (binding energy) obtained from docking method were in accordance with the ITC method. From molecular docking we have determined the amino acid residues involved in binding process for binary and ternary systems by considering first rank minimum binding energy confirmation. From CD it has been observed that RTC causes most conformational change in secondary and tertiary structure of BSA due to the presence of pyrrole ring. OTC-RTC with higher affinity showed highest melting temperature Tm values while low affinity drugs in (5FU-GM) combination showed lowest Tm value. 5FU showed large endothermic denaturation enthalpy ΔHd0 due to the presence of highly electronegative fluorine atom in the pyridine analogue.

Hybrid Nanosystems of Antibiotics with Metal Nanoparticles-Novel Antibacterial Agents

The appearance and increasing number of microorganisms resistant to the action of antibiotics is one of the global problems of the 21st century. Already, the duration of therapeutic treatment and mortality from infectious diseases caused by pathogenic microorganisms have increased significantly over the last few decades. Nanoscale inorganic materials (metals and metal oxides) with antimicrobial potential are a promising solution to this problem. Here we discuss possible mechanisms of pathogenic microorganisms' resistance to antibiotics, proposed mechanisms of action of inorganic nanoparticles on bacterial cells, and the possibilities and benefits of their combined use with antibacterial drugs. The prospects of using metal and metal oxide nanoparticles as carriers in targeted delivery systems for antibacterial compositions are also discussed.