Ferrate
(K2FeO4) is a powerful oxidant and
up to 3 mol of electrons could be captured by 1 mol of ferrate in
the theoretical conversion of Fe(VI)–Fe(V)–Fe(IV)–Fe(III).
However, it is reported that the utilization efficiency of the ferrate
oxidation capacity is quite low because of the rapid autodecomposition
of intermediate iron species, which negatively influences the potential
of ferrate on organic pollutants control. We accidentally found that
for the ferrate oxidation of carbamazepine (CBZ), bisphenol S (BPS),
diclofenac (DCF), and ciprofloxacin (CIP), the determined reaction
rate constants were 1.7–2.4 times lower in phosphate buffer
than those in borate buffer at pH 8.0. For the reaction of ferrate
with 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulfonate) (ABTS)
at pH 7.0, the determined reaction stoichiometries were 1:1.04 in
100 mM phosphate buffer, 1:1.18 in 10 mM phosphate buffer, and 1:1.93
in 10 mM borate buffer, respectively. The oxidation ability of ferrate
seems depressed in phosphate buffer. A kinetic model involving the
oxidation of ABTS by Fe(VI), Fe(V) and Fe(IV) species was developed
and fitted the ABTS•+ formation kinetics well under
different buffer conditions. The results showed that phosphate exhibited
little influence on the oxidation ability of Fe(VI) and Fe(IV) species,
but decreased the specific rate constants of ABTS with Fe(V) species
by 1–2 orders of magnitude, resulting in the outcompeting of
Fe(V) autodecomposition pathway. The complexation between phosphate
anions and Fe(V) species may account for the inhibition effect of
phosphate buffer. Considering that many studies regarding ferrate
oxidation were carried out in phosphate buffer, the actual oxidation
ability of ferrate may be underestimated.
Artemia has attracted much attention for its ability to produce encysted embryos wrapped in a protective shell when subject to extremely harsh environmental conditions. However, what the cyst shell is synthesized from and how the formative process is performed remains, as yet, largely unknown. Over 20 oviparous specifically expressed genes were identified through screening the subtracted cDNA library enriched between oviparous and ovoviviparous Artemia ovisacs. Among them, a shell gland-specifically expressed gene (SGEG) has been found to be involved in the cyst shell formation. Lacking SGEG protein (by RNA interference) caused the cyst shell to become translucent and the chorion layer of the shell to become less compact and pultaceous and to show a marked decrease of iron composition within the shell. The RNA interference induced defective diapause cysts with a totally compromised resistibility to UV irradiation, extremely large temperature differences, osmotic pressure, dryness, and organic solvent stresses. In contrast, the natural cyst would provide adequate protection from all such factors. SGEG contains a 345-bp open reading frame, and its consequentially translated peptide consists of a 33-amino acid residue putative signal peptide and an 81-amino acid residue mature peptide. The results of Northern blotting and in situ hybridization indicate that the gene is specifically expressed in the cells of shell glands during the period of diapause cyst formation of oviparous Artemia. This investigation adds strong insight into the mechanism of cyst shell formation of Artemia and may be applicable to other areas of research in extremophile biology.
Many investigations focused on the capacity of ferrate for the oxidation of organic pollutant or adsorption of hazardous species, while little attention has been paid on the effect of ferrate resultant nanoparticles for the removal of organics. Removing organics could improve microbiological stability of treated water and control the formation of disinfection byproducts in following treatment procedures. Herein, we studied ferrate oxidation of p-arsanilic acid (p-ASA), an extensively used organoarsenic feed additive. p-ASA was oxidized into As(V), p-aminophenol (p-AP), and nitarsone in the reaction process. The released As(V) could be eliminated by in situ formed ferric (oxyhydr) oxides through surface adsorption, while p-AP can be further oxidized into 4,4′-(diazene-1,2-diyl) diphenol, p-nitrophenol, and NO 3 − . Nitarsone is resistant to ferrate oxidation, but mostly adsorbed (>85%) by ferrate resultant ferric (oxyhydr) oxides. Ferrate oxidation (ferrate/p-ASA = 20:1) eliminated 18% of total organic carbon (TOC), while ferrate resultant particles removed 40% of TOC in the system. TOC removal efficiency is 1.6 to 38 times higher in ferrate treatment group than those in O 3 , HClO, and permanganate treatment groups. Besides ferrate oxidation, adsorption of organic pollutants with ferrate resultant nanoparticles could also be an effective method for water treatment and environmental remediation.
BackgroundMany species of the brine shrimp Artemia are found in various severe environments in many parts of the world where extreme salinity, high UV radiation levels, high pH, anoxia, large temperature fluctuations, and intermittent dry conditions are often recorded. To withstand adverse environments, Artemia undergoes an oviparous developmental pathway to release cysts whereas, under favorable conditions, swimming nauplius larvae are formed directly via an ovoviviparous pathway. In the former case these cysts have an extraordinary ability to keep the embryos protected from the harsh environment for long periods. This is achieved through the protection by a complex out-wrapping cyst shell. However, the formation and function of the cyst shell is complex; the details remain largely unclear.Principal FindingA shell gland-specific gene (SGEG2) was cloned and identified from a suppression subtractive hybridization library. Western blot analysis showed that SGEG2 presumably requires post-translational proteolysis in order to be processed into two mature peptides (SGEG2a and 2b). The three matrix peptides (SGEG1 reported previously, 2a, and 2b) were found to distribute throughout the cyst shell. The results of gene knockdown by RNAi and subsequent resistance to environmental stresses assays indicated that these matrix peptides are required for cyst shell formation and are involved in protecting the encysted embryos from environmental stress.Conclusions/SignificanceThis study revealed that extracellular matrix peptides participate in protecting embryos from extreme salinity, UV radiation, large temperature fluctuations and dry environments, thereby facilitating their survival. The cyst shell provides an excellent opportunity to link the ecological setting of an organism to the underlying physiological and biochemical processes enabling its survival. The cyst shell material has also a high potential to become an excellent new biomaterial with a high number of prospective uses due, specifically, to such biological characteristics.
Sulfamethoxazole
(SMX) is a broad-spectrum antibiotic and was largely
used in breeding industry. The reaction rate of SMX with KMnO4 is slow, and the adsorption efficiency of biochar for SMX
was inferior (less than 11% in 30 min). By adding biochar powder into
SMX solution with the addition of permanganate, the oxidation ratio
of SMX surged to 97% in 30 min, and over 58% of the total organic
carbon (TOC) was simultaneously removed. KMnO4 interacted
with biochar and resulted in the formation of highly oxidative intermediate
manganese species, which transformed SMX into hydrolysis products,
oxygen-transfer products, and self-coupling products. Brunauer–Emmett–Teller
(BET) analysis showed that surface area, total pore volume, and micropore
volume of biochar increased by 32.1%, 36.4%, and 80.6%, respectively,
after reaction process. This in situ activation of biochar with KMnO4 enhanced its adsorption capacity and led to great improvement
of TOC removal. Besides KMnO4 oxidation, biochar also enhanced
TOC removal in Mn(III) oxidation (KMnO4+ bisulfite) and
ozonization of SMX. Considering that KMnO4 could react
with biochar and result in the formation of intermediate manganese
species, while biochar can be simultaneously activated and exhibit
high capacity for organic adsorption, the combination of biochar with
the chemical/advanced oxidation could be a promising process for the
removal of environmental pollutants.
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