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- Baden, Susanne P., 1952, et al.
(author)
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Accumulation and elimination kinetics of manganese from different tissues of the Norway lobster Nephrops norvegicus (L.)
- 1999
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In: Aquatic Toxicology. - 0166-445X. ; 46:2, s. 127-137
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Journal article (peer-reviewed)abstract
- The exposure of marine benthic animals to dissolved manganese (Mn) occurs from metalliferous outlets or the enhanced flux of dissolved manganese from sediments during hypoxia. A prerequisite to valid interpretation of manganese concentrations measured in animals in situ is a thorough understanding of accumulation and elimination rates of this metal by relevant target tissues in organisms exposed to environmentally realistic manganese concentrations. Norway lobster, Nephrops norvegicus, accumulated manganese when exposed to solutions of < 0.06 (background), 5 and 10 mg Mn l(-1) for 20 days and was allowed to eliminate any accumulated manganese in undosed sea water for a further 20 days. During this period individual N. norvegicus were dissected into a number of components (brain, ventral ganglion, haemolymph, midgut gland, gills and exoskeleton) and the manganese concentration of each was analysed. Manganese accumulation reached a plateau after 1.25 days in all tissues except for midgut gland, which continued to accumulate manganese during the entire exposure period. In general, the manganese elimination was significantly slower than accumulation and reached a plateau after 1.25-2.5 days (except the gills) following exposure to clean sea water. The accumulation factor (AF), when compared to maximum concentrations in control and exposed animals, was highest in the haemolymph (x 88) followed by nerve tissue (x 22) at the 10 mg Mn l(-1) exposure. The concentration factor (CF), when comparing manganese accumulation in tissues (wet weight) with exposure concentration, was 1.2-3.5 and for most tissues was similar for both exposure concentrations or slightly higher in the 5 mg Mn l(-1) exposure-indicating net accumulation of manganese in all tissues with a saturation effect with increasing exposure concentrations. Thus, from these experiments it may be concluded that measured manganese concentrations in N. norvegicus give an indication of recent exposure to manganese concentrations in the bottom waters of their habitats. (C) 1999 Elsevier Science B.V. All rights reserved.
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| 3. |
- Eriksson, Susanne P., 1964, et al.
(author)
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Behaviour and tolerance to hypoxia in juvenile Norway lobster (Nephrops norvegicus) of different ages
- 1997
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In: Marine Biology. - 0025-3162. ; 128:1, s. 49-54
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Journal article (peer-reviewed)abstract
- The annual occurrence of hypoxia (<25% oxygen saturation) in the bottom waters along the Swedish west coast coincides with the postlarval settlement of Norway lobster, Nephrops norvegicus (L.). This study investigates behaviour and the experimental effects of low oxygen concentrations in juvenile N. norvegicus of different ages. All experimental individuals were reared to the juvenile (postlarval) stage in the laboratory and then given sediment as a substratum. Behavioural responses to low oxygen concentrations were tested in early and late Postlarvae 1 exposed to normoxia (>80% oxygen saturation, pO(2) > 16.7 kPa), moderate hypoxia (30% oxygen saturation, pO(2) = 6.3 kPa) and hypoxia (25% oxygen saturation, pO(2) = 5.2 kPa). The experiments were run for a maximum period of 24 h or until individuals died. Behaviour was studied using sequential video recordings of four behavioural activities: digging, walking, inactivity or flight (escape swimming up into the water column). Behaviour and mortality changed with lowered oxygen concentrations; energetically costly activities (such as walking) were reduced, and activity in general declined. In normoxia, juveniles initially walked and then burrowed, but when exposed to hypoxia they were mainly inactive with occasional outbursts of escape swimming. To increase oxygen availability the juveniles were observed to raise their bodies on stilted legs (similar to adults in hypoxic conditions), but oxygen saturations of 25% were lethal within 24 h. The results suggest that the main gas exchanges of early postlarval stages occur over the general body surface. Burrowing behaviour was tested in Postlarvae 1 and 2 of different ages held in >80% oxygen saturation for 1 wk. The difference in time taken to complete a V-shaped depression or a U-shaped burrow was measured. The results showed a strong negative relationship between postlarval age and burrowing time, but all individuals made a burrow. Juveniles were more sensitive to hypoxia than adults. Thus, the possible consequences of episodic hypoxia for the recruitment of Nephrops norvegicus and for the recolonization of severely affected areas are discussed.
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| 4. |
- Eriksson, Susanne P., 1964, et al.
(author)
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Manganese in the haemolymph and tissues of the Norway lobster, Nephrops norvegicus (L.), along the Swedish west coast, 1993-1995
- 1998
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In: Hydrobiologia. - 0018-8158. ; 376, s. 255-264
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Journal article (peer-reviewed)abstract
- Spatial and temporal differences in manganese levels in Norway lobsters, Nephrops norvegicus, were compared with the concentrations of manganese in their environment. Animals were collected twice yearly (spring and autumn) from seven stations along the Swedish west coast and from one site in the Faroe Islands, during 1993-94, and analysed for manganese tissue concentration and content. Animals were also collected from the Swedish stations in the autumn of 1995 and compared with animals from a stressful environment, frequently exposed to hypoxia. There were large spatial differences and the animals collected in the Faroe Islands contained (in most tissues) one order of magnitude less manganese than the animals collected along the Swedish west coast. The manganese level of the haemolymph correlated most closely with the manganese concentration the animal was exposed to in the field. The manganese concentration of the female gonad tissue did however not differ with space nor time and remained stable around 5.1 mu g Mn g(-1) dw tissue throughout the investigation. Animals taken from an area with known repeated hypoxia in the bottom water, had high levels of manganese in especially the gills. Their mean manganese concentration was over 20 times higher (1560 mu g Mn g(-1) dw tissue) than the manganese concentration in animals from the other Swedish stations. They also had more than threefold the amount of manganese in the brain, giving a mean concentration of 193 mu g Mn g(-1) dw tissue.
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| 6. |
- Bignert, Anders, et al.
(author)
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Temporal trends of organochlorines in Northern Europe, 1967–1995. Relation to global fractionation, leakage from sediments and international measures
- 1998
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In: Environmental Pollution. - 0269-7491 .- 1873-6424. ; 99:2, s. 177-198
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Journal article (peer-reviewed)abstract
- The time trend monitoring of organochlorine pollution was carried out in Sweden since the late 1960s. This report presents data on concentrations of DDT, PCB, HCHs and HCB in biota samples collected and analysed annually. All the matrices and compounds studied show a significant decrease over time. The data cover severely polluted Swedish marine and fresh water in southern Sweden as well as locally unpolluted waters in remote northern Arctic regions of Sweden. A total of 13 time series representing different locations and species are presented for the different pollutants. The period studied covers the time when pollution was serious as well as the time of recovery. All monitoring activities were carried out at the same laboratories over the entire study period, which means that comparability over time is good in the sets of data presented. The various time trends show a convincing agreement with trends and annual change over time, although the concentrations differ between the species and locations investigated, the highest concentrations being in the south. Since the annual changes are normally similar regardless of locations and species, spatial variations in concentrations remain over time, although concentrations are lower today. The onset of changes in concentrations over time can be related to international measures or other circumstances that lowered releases into the environment. Similarities in the annual changes, as well as the time when changes began, are discussed with respect to suggested hypotheses on the fate of the investigated organochlorines. It was not possible to verify that the oxygenation of anoxic sediments mobilised old pollution in Baltic sediments. Neither was it possible to conclude that eutrophication has caused a measurable effect on the rate and timing of the decreases. Finally, long-range transport to Arctic regions seems to be due more to a one step transport than to the ‘Grass-hopper’ effect. The comprehensive database used, clearly shows how important it is to have datasets big enough to describe between-year variation before attempting to evaluate the time trend. In addition, if between-year variation is not known, it is then also difficult to evaluate spatial variation on the basis of single year observations.
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