Liver-specific contrast agents (CAs)
can improve the Magnetic resonance
imaging (MRI) detection of focal and diffuse liver lesions by increasing
the lesion-to-liver contrast. A novel Mn(II) complex, Mn-BnO-TyrEDTA,
with a lipophilic group-modified ethylenediaminetetraacetic acid (EDTA)
structure as a ligand to regulate its behavior in vivo, is superior
to Gd-EOB-DTPA in terms of a liver-specific MRI contrast agent. An
MRI study on mice demonstrated that Mn-BnO-TyrEDTA can be rapidly
taken up by hepatocytes with a combination of hepatobiliary and renal
clearance pathways. Bromosulfophthalein (BSP) inhibition imaging,
biodistribution, and cellular uptake studies confirmed that the mechanism
of hepatic targeting of Mn-BnO-TyrEDTA is the hepatic uptake of the
amphiphilic anion contrast agent mediated by organic anion transporting
polypeptides (OATPs) expressed by functional hepatocytes.
As the most abundant biomass in nature, cellulose is considered to be an excellent feedstock to produce renewable fuels and fine chemicals. Due to its hydrogen-bonded supramolecular structure, cellulose is hardly soluble in water and most conventional organic solvents, limiting its further applications. The emergence of ionic liquids (ILs) provides an environmentally friendly, biodegradable solvent system to dissolve cellulose. This review summarizes recent advances concerning imidazolium-based ILs for cellulose pretreatment. The structure of cations and anions which has an influence on the solubility is emphasized. Methods to assist cellulose pretreatment with ILs are discussed. The state of art of the recovery, regeneration, and reuse aspects of ILs is also presented in this work. The current challenges and development directions of cellulose dissolution in ILs are put forward. Although further studies are still much required, commercialization of IL-based processes has made great progress in recent years.
Exoelectrogens acclimated from the environment are the key to energy recovery from waste in bioelectrochemical systems. However, it is still unknown how these bacteria are selectively enriched on the electrode. Here we confirmed for the first time that the electric field (EF) intensity selects exoelectrogens from wastewater using an integrated electrovisual system with a gradient EF. Under the operating conditions ( I = 3 × 10A), the EF intensity on the working electrode ranged from 6.00 V/cm at the center to 1.08 V/cm at the edge. A thick biofilm (88.9 μm) with spherical pink aggregates was observed at the center, while the color became gray at the edge (33.8 μm). The coverage of the biofilm also increased linearly with EF intensity from 0.42 at the edge (12 mm to the center) to 0.78 at the center. The biofilm at the center contained 76% Geobacter, which was 25% higher than that at the edge (60%). Geobacter anodireducens was the main species induced by the EF (50% at the center vs 24% at the edge). These results improve our fundamental knowledge of exoelectrogen acclimation and mixed electroactive biofilm formation, which has broader implications for energy recovery from waste and general understanding of microbial ecology.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.