Pyridine-containing block copolymers are a special type of macromolecules, and they can self-assemble into highly-ordered nano-objects for a wide range of applications due to their multiple properties including the hydrogen...
Polymer-based nanomaterials have exhibited promising alternative avenues to combat the globe challenge of multidrug-resistant bacterial infection. However, most of the reported polymeric nanomaterials have facially linear amphiphilic structures with positive net charges, which may lead to nonspecific binding, high hemolysis, and uncontrollable self-organization, limiting their practical applications. In this contribution, we report a one-dimensional glyconanorod (GNR) through self-assembly of well-defined β-cyclodextrin-based glycoconjugates (RMan) featuring hydrophobic carbon-based chains and amide rhodamines with an adenosine triphosphate (ATP)-recognition site and targeted and hydrophilic mannoses and positively net-charged ethylene amine groups. The GNRs show superior targeting sensing and killing for Gram-negative Escherichia coli (E. coli) dominantly through the multivalent recognition between mannoses on the nanorod and the lectin on the surface of E. coli. Moreover, red fluorescence was light on due to the hydrogen bonding between amide rhodamine and ATP. Benefiting from the designs, the GNRs are capable of possessing a higher therapeutic index and of encapsulating other antibiotics. They exhibit an enhanced effect against E. coli strains. Intriguingly, the GNRs displayed a more reduced hemolysis effect and lower cytotoxicity compared to that of ethylene glyco-modified nanorods. These results reveal that the glyconanomaterials not only feature superior and targeted bacterial sensing and antibacterial activity, but also better biocompatibility compared with the widely used PEG-covered nanomaterials. Furthermore, the in vivo studies demonstrate that the targeted and ATP-responsive GNRs complexed with antibiotics showed better treatment using a mouse model of abdominal sepsis following intraperitoneal E. coli infection. The present work describes a targeted and effective sensing and antibacterial platform based on glycoconjugates that have potential applications for the treatment of infections caused by pathogenic microorganisms.
Recycling precious metals from the increasing amount of electronic waste (e-waste) is of great significance for the sustainability of strategic metal resources. However, there are rarely reports of technologies that can efficiently and highly selectively recover precious metals from strong acid e-waste leachates. Herein, we demonstrated a simply synthesized thiolated β-cyclodextrin (T-CD) that can recover gold with high selectivity from strong acidic medium. The material has an exceptional adsorption capacity, approaching 1890.98 mg gold/g of adsorbent, and a superior selectivity coefficient of about 5×104 for gold from multi-metal coexistence solutions at pH 2. Sulfhydryl groups, as the adsorption sites, are capable of selectively enriching gold to T-CD surfaces. Simultaneously, the acetal of T-CD can be hydrolyzed into hemiacetal by the initiation of H+ in acidic solution with a more energetically favorable reaction barrier (TS = -3.38 eV) than that in neutral solution (TS = 5.36 eV). Further, the serial transformation process of carbon structure and gold valence state (Au3+ to Au) induced by redox reaction of acetal carbon were confirmed by XPS and DFT. In addition, T-CD shows a remarkable ability to extract gold directly from actual complex waste printed circuit board leachate, which facilitates the recycling of the acidic solution up to five times. The concept of H+-assisted enhancement of adsorbent performance provides a new guidance for the direct recovery of rare and precious metals from strongly acidic actual wastewater.
Transgenic
RNA interference (RNAi) represents a burgeoning and
promising alternative avenue to manage plant diseases and insect pests
in plants. Nonviral nanostructured dsRNA carriers have been demonstrated
to possess great potential to facilitate the application of RNAi.
However, it remains a critical challenge to achieve the targeted and
effective release of dsRNA into the pest cells, limiting the efficiency
of the biological control of pests and diseases in practical applications.
In this study, we designed and constructed a new type of core–shell
polymeric nanostructure (CSPN) with controllable structure, eco-friendliness,
and good biocompatibility, on which dsRNA can be efficiently loaded.
Once loaded into CSPNs, the dsRNA can be effectively prevented from
nonsense degradation by enzymes before entering cells, and it shows
targeted and image-guided release triggered by intracellular ATP,
which significantly increases the efficiency of gene transfection.
Significantly, the in vivo study of the typical lepidoptera
silkworm after oral feeding demonstrates the potential of dsCHT10 in CSPNs for a much better knockdown efficiency than
that of naked dsCHT10. This innovation enables the
nanotechnology developed for the disease microenvironment-triggered
release of therapeutic genes for application in sustainable crop protection.
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