The majority of the localized drug delivery systems are based on polymeric or polypeptide scaffolds, as weak intermolecular interactions of low molecular weight hydrogelators (LMHGs, Mw <500 Da) are significantly perturbed in the presence of anticancer drugs. Here, we present l-alanine derived low molecular weight hydrogelators (LMHGs) that remain injectable even after entrapping the anticancer drug doxorubicin (DOX). These DOX containing nanoassemblies (DOX-Gel) showed promising anticancer activity in mice models. Subcutaneous injection of DOX-Gel near the tumor achieved a greater decrease in tumour load than by intravenous injection of DOX (DOX-IV), and local injection of DOX alone (DOX-Local) at the tumor site. We noticed that DOX-Gel nanocarriers are especially effective when injected during the early stage of tumor progression, and achieve a substantial decrease in tumor load in the long term.
Biomineralization is a mineral precipitation process occurring in the presence of organic molecules and used by various organisms to serve a structural and/or a functional role. Many biomineralization processes occur in the presence of extracellular matrices that are composed of proteins and polysaccharides. Recently, there is growing evidence that bacterial biofilms induce CaCO3 mineralization and that this process may be related with their extracellular matrix (ECM). In this study we explore, in vitro, the effect of two bacterial ECM proteins, TasA and TapA, and an exopolysaccharide, EPS, on calcium carbonate crystallization. We have found that all the three biopolymers induce the formation of complex CaCO3 structures. The crystals formed in the presence of the EPS are very diverse in morphology and they are either calcite or vaterite in structure. However, more uniformly sized calcite crystals are formed in the presence of the proteins; these crystals are composed of single crystalline domains that assemble together into spherulites (in the presence of TapA) or dumbbell-like shapes (in the presence of TasA). Our results suggest the EPS affects the nucleation of calcium carbonate when it induces the formation of vaterite crystals and that unlike EPS, the proteins stabilize preformed calcite nuclei and induce their aggregation into complex calcite structures. Biomineralization processes induced by bacterial ECM macromolecules make biofilms more robust and difficult to remove when they form, for example, on pipes and filters in water desalination systems or on ship hulls. Understanding the formation conditions and mechanism of formation of calcium carbonate in the presence of bacterial biopolymers may lead to the design of suitable mineralization inhibitors.
Counter polyelectrolytes (PEs) having a degradable polyamide backbone and controlled thiolation are prepared. Their nanosized polyelectrolyte complexes (PECs) spontaneously crosslink under ambient conditions via bioreducible disulfide bonds. These PECs are regenerable after centrifugation, and resist degradation by proteases. They are stable to variations of pH and electrolyte concentration, similar to those encountered in biological milieu. However, they are unraveled in reductive conditions. These PECs act as efficient vectors for delivering entrapped cargo. They entrap with high efficiency, and controllably release, fluorescein isothiocyanate (FITC)-insulin (a model peptide) in vitro. Potent cellular internalization of FITC-insulin within human lung cancer cells with high cell viability is demonstrated.
We report the design of a structurally concise alanine derivative (Ala-hyd) that has a rotationally flexible aromatic N-protecting group for alanine and a hydrazide functionality at its carboxylic end. Ala-hyd requires mechanical agitation (physically stirring, vortexing or sonicating) to form supramolecular hydrogels at medium concentrations (0.4-0.8 wt%). At higher concentrations (>0.8 wt%), it spontaneously gelates water on undisturbed cooling of the hot solution, while at lower concentrations (<0.4 wt%), only turbid suspensions were formed upon agitation. In the <0.8 wt% regime, hydrogelation by Ala-hyd is modulated by its concentration as well as by the extent of applied mechanical agitation. Turbidimetry and fluorescence spectroscopy indicate enhanced self-assembly of Ala-hyd upon agitation, and FTIR studies point towards stronger hydrogen bonds in the resulting assemblies. Since Ala-hyd requires mechanical agitation to undergo self-assembly, its aqueous sols exhibited mild shear-thickening behaviour in buffered as well as salt-free conditions. During shearing, the formation of an entangled mesh of long, helical nanofibers coincided with the maximum in the bulk shear viscosity. pH-dependent rheological investigations indicate that protonation of the amine unit (pKa = 8.9) of hydrazide diminishes the self-assembly propensity of this compound. The self-assembly of Ala-hyd can thus be modulated through mechanical as well as chemical cues.
A new frontier in the design and applications of useful micro- and nanomaterials was unlocked by the combination of fluid mechanics with modern engineered technologies. Fluidic methods allow for the exact and active spatiotemporal manipulation of matter, which has enormous potential for the fabrication of advanced nanoplatforms with flexible material characteristics. Fluidic technologies bestow some advantages over conventional experimental methods, such as quick sample processing and precise fluid control during assays. When combined with different two-dimensional (2D) materials, these fluidic techniques opened up a new era in the area of material science and engineering. MXenes, the youngest family of layered 2D materials, have attracted great scientific attention as a result of their peculiar properties and are used for a multitude of applications. This review discusses the magnificent relationship between MXenes and fluid manipulation technique nanofluidics in the domain of energy research. This article proclaims a concise review of the synthesis, energy applications, challenges, and future outlook of MXenes in fluidic research. An emphasis is given to the applications of MXene-based fluidic techniques in the field of energy harvesting and storage. This analysis will provide anew insight into MXenes in the field of fluid manipulation techniques that followed custom approaches in the past and researchers to move toward a new direction in the future. This examinative article will fill a major gap in fluidic research in the world of materials. And to the best part of our perception, this is the first review that offers an overview of the combination of fluidics and MXenes for application, particularly in energy harvesting and storage devices.
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