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Dahms, Hans‐,Uwe,Tseng, Li‐,Chun,Hsiao, Shih‐,Hui,Chen, Qing‐,Chao,Hwang, Jiang‐,Shiou Springer Japan 2013 Ecological research Vol.28 No.2
<P><B>Abstract</B></P><P>The mesozooplankton of a river tributary in Oceania is evaluated and is correlated against environmental, abiotic, and biological attributes of this lotic system. Abundance, distribution, and the diversity of mesozooplankton was studied at nine stations including one estuarine station during ten sampling campaigns from June 2004 to December 2005 along the Lanyang River, the largest river and estuarine ecosystem in northeastern Taiwan. Mesozooplankton was dominated by copepods, cladocerans, and fish larvae. Among all samples, the highest abundances of mesozooplankton (5,049.36 individuals m<SUP>−3</SUP>) occurred in the estuary station in August 2004, which also corresponds to the highest salinities (37.0), indicating the marine role in shaping the estuarine planktonic assemblages. The abundance of mesozooplankton and number of mesozooplankton taxa were significantly higher in samples of the estuarine station than in the riverine stations (<I>p</I> < 0.05, one‐way ANOVA). The number of mesozooplankton taxa number was affected by water temperature (<I>r</I> = 0.697; <I>p</I> = 0.025, Pearson's correlation) that was primarily influenced by the weather that was in turn affected by seasonal monsoons.</P>
Dahms, H. U.,Lee, S. H.,Huang, D. J.,Chen, W. Y.,Hwang, J. S. Springer Science + Business Media 2017 Hydrobiologia Vol.784 No.1
<P>We used the marine model copepod taxon T. japonicus Mori, 1938 for a first short sublethal life cycle assay of the endocrine-disrupting chemical bisphenol A (BphA) where we studied life cycle and reproductive success. Individual copepodid-I-stages were reared in 96-well microplates to adulthood in as short as 6 days in only 200 mu l of 0.1 mg bisphenol (BphA/L) or seawater solution as a control (CON). Males and females were then mated in one well and checked daily for the following endpoints: postmating days to female brood sac extrusion, days from brood sac extrusion to naupliar hatching, first clutch brood size, hatching success, and reproductive success. Mean naupliar hatching times ranged from 1.3 days for CON-reared mating pairs to 2.7 days for BphA-reared mating pairs; mean brood size was significantly lower for CON females mated with BphA males than for all other mating combinations; reproductive success of CON females mated with BphA males and BphA females mated with BphA males showed significant differences between females and males. In conclusion, T. japonicus complete life cycle exposures to BphA at an environmentally realistic concentration resulted generally in reproductive depression with effect values depending on the exposure history of the different gender.</P>
Hans-Uwe Dahms,주형민,이재형,윤미선,안소현,이상헌 한국해양과학기술원 2015 Ocean science journal Vol.50 No.4
Demersally drifting organisms were collected at Ny Ålesund (Svalbård – Arctic Ocean) to study the taxon composition and relative abundances in the Arctic summer. Catch potentials of two collection devices for demersal drift were compared. A lowvolume submersible drift-pump and a drift-net unit were employed for the collection of demersally drifting biota, particularly for shallow aquatic habitats. With the exception of Appendicularia, Chaetognatha, Coelenterata, and Ctenophora, which were damaged at times, the pump catches were in good condition and sufficient for identification and quantification of less mobile fauna. A comparison of the two devices revealed that the drift-pump collected more specimens than the drift-net. However, the drift-net may have caused an underestimation of the abundances of invertebrates. No differences in identified taxon number and indices of richness, evenness and diversity were found. However, the proportion of invertebrate animals in the two devices was different for the three groups: zooplankton, macrofauna and meiofauna. At Svalbård, zooplankton, larvae of macrofauna, and meiofauna were successfully collected by the two collecting devices. However, the catchibility of the two devices in collecting various invertebrate taxa was different and, therefore, a sound ‘Device Effect’ was revealed.
Microalgae - A promising tool for heavy metal remediation
Suresh Kumar, K.,Dahms, H.U.,Won, E.J.,Lee, J.S.,Shin, K.H. Academic Press 2015 Ecotoxicology and environmental safety Vol.113 No.-
Biotechnology of microalgae has gained popularity due to the growing need for novel environmental technologies and the development of innovative mass-production. Inexpensive growth requirements (solar light and CO<SUB>2</SUB>), and, the advantage of being utilized simultaneously for multiple technologies (e.g. carbon mitigation, biofuel production, and bioremediation) make microalgae suitable candidates for several ecofriendly technologies. Microalgae have developed an extensive spectrum of mechanisms (extracellular and intracellular) to cope with heavy metal toxicity. Their wide-spread occurrence along with their ability to grow and concentrate heavy metals, ascertains their suitability in practical applications of waste-water bioremediation. Heavy metal uptake by microalgae is affirmed to be superior to the prevalent physicochemical processes employed in the removal of toxic heavy metals. In order to evaluate their potential and to fill in the loopholes, it is essential to carry out a critical assessment of the existing microalgal technologies, and realize the need for development of commercially viable technologies involving strategic multidisciplinary approaches. This review summarizes several areas of heavy metal remediation from a microalgal perspective and provides an overview of various practical avenues of this technology. It particularly details heavy metals and microalgae which have been extensively studied, and provides a schematic representation of the mechanisms of heavy metal remediation in microalgae.