Large-scale preparative high-performance size-exclusion chromatography (HPSEC) was performed to separate different molecular size fractions in milligram quantities from strongly colored dissolved organic matter (DOM) of a freshwater using a very mild conjugate acid-base pair (10 mM acetic acid-sodium acetate solution at pH 7.0 with an ionic strength of 6 x 10(-5)) as the mobile phase. The homogeneity-uniformity of different molecular size fractions in relation to their combined original mixture was verified by an analytical HPSEC system. In addition to molecular size distribution and basic spectroscopic characteristics, Fourier transform infrared spectroscopy was applied to specify structural features for different size fractions. The results demonstrate clearly that only a very small amount of conjugate organic acid-base pair is required to generate a powerful resolution for a DOM mixture, and very strong treatments with organic acids are not necessarily needed to reach a better SEC resolution. Most essential is the combined outcome of different HPSEC experiments and determined structural functionalities which indicate that almost all original DOM solutes are aggregated mixtures consisting of different associations possessing various molecular size ranges, which can be separated from their integrated whole as nearly homogeneous and uniform species. In summary, the present study strongly speaks for the need to direct the research of natural dissolved and colloidal organic carbon more strongly toward a nanoscale study of supramolecular assemblies. More precise knowledge about the primary, secondary, and tertiary structure of dissolved DOM constituents has its essential function, e.g., for environmental protection and utilization of surface waters.
The kinetics of simulated low-energy daylight (UVA-vis) and powerful combined ultraviolet B and A (UVB-UVA) induced direct and indirect phototransformations of four pharmaceuticals, i.e., ibuprofen, metoprolol, carbamazepine, and warfarin, which were investigated in dilute solutions of pure laboratory and natural humic waters. The results strengthen the essential function of natural chromophores in dissolved organic material (CDOM) as principal photosensitizer toward indirect phototransformations of pharmaceuticals in natural conditions under available low-energy UVA-vis and slight UVB radiations. The results confirmed that organic micropollutants are able to undergo a direct photolysis if their absorbance spectra overlap the spectral range of the available radiation but only if the radiation is strong enough, e.g., ibuprofen is able to undergo only indirect photolysis via different pathways in all realistic conditions. The action of nitrate anions as photosensitizers in the applied conditions proved to be of little importance. High-performance size-exclusion chromatographic experiments verified that the rate constants obtained under the low-energy UVA-vis and powerful UVB-UVA irradiations for the decreased amounts of the two largest molecular size fractions of CDOM were quite close to the rate constants detected for the increased amounts of the next five molecular size fractions with smaller molecular sizes. The decreased contents of the two largest molecular size fractions correlated quite well with the decreased contents of the studied pharmaceuticals under the low-energy UVA-vis irradiation process but somewhat less under the powerful UVB-UVA irradiation. The photochemically induced decomposition of the CDOM aggregates appears to increase the amounts of smaller molecular size fractions and simultaneously produce via CDOM-stimulated radical reactions indirect structural transformations of pharmaceuticals. Apparent quantum yields were estimated for the transformation-degradation of the two largest molecular-size CDOM aggregates under low-energy UVA-vis and powerful UVB-UVA irradiations.
The structural similarity−dissimilarity of several humic-type derivatives, separated from a strongly colored freshwater
sample by different sorbing solid techniques, tangential-flow ultrafiltration (UF), and large-scale preparative high-performance size-exclusion chromatography (HPSEC), were
in detail studied with one-dimensional liquid 1H and solid-state 13C nuclear magnetic resonance (NMR) spectroscopy,
especially in light of the native humic-type dissolved organic
matter (DOM-HM). The results support the applicability
of functional cross-linked poly(vinylpyrrolidone) (PVP) or
diethylaminoethyl-cellulose (DEAE) sorbents in concentrating
representative integrated wholes of aquatic humic-type
material along with a conventional nonionic XAD-8/DAX-8
(polymethyl methacrylates) technique. Apart from the
fact that the acidification of the original humic water before
a separation procedure seems not to be so destructive
to the original structural composition of the DOM-HM as
expected, the refinement of aquatic humic solutes,
independent of the selected sorbing solid technique, will
cause structural changes in the separated humic complexes
in comparison with the situation predominating in the
original starting material. Tangential-flow ultrafiltration (UF)
proved an overpowering reliability to concentrate the
aquatic DOM-HM. Most fundamental is the combined
outcome of different HPSEC experiments and determined
structural functionalities which indicate that almost all original
DOM-HM solutes are aggregated mixtures consisting of
structurally similar associations possessing various molecular
size ranges, which can be separated from their integrated
whole as nearly homogeneous and uniform species.
This finding permits a reasonable starting point to go on
working with more advanced multidimensional NMR
techniques in resolving the uncertainty about supramolecular
assembly of dissolved humic material. The tested
conformity between the obtained molecular NMR descriptors
and the corresponding previously collected FT-IR
parameters was acceptable thus speaking for the fact
that the less sensitive FT-IR spectroscopy can also provide
valuable information on the structural and functional
properties of heterogeneous humic-type mixtures.
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