Albertinka J Murk
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Explore the profile of Albertinka J Murk including associated specialties, affiliations and a list of published articles.
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Articles
103
Citations
1282
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Recent Articles
1.
Knoester E, Sanders R, Durden D, Masiga B, Murk A, Osinga R
PLoS One
. 2025 Jan;
19(12):e0315475.
PMID: 39774452
Restoration and artificial reefs can assist the recovery of degraded reefs but are limited in scalability and climate resilience. The Mineral Accretion Technique (MAT) subjects metal artificial reefs to a...
2.
Breve N, van Dieren D, Weeber M, Mosselman E, Nagelkerke L, Murk A, et al.
Aquat Conserv
. 2024 Nov;
34(11):e70016.
PMID: 39605956
Information about reproductive habitat and migration pathways is of paramount importance to restore migratory fish species. This study assesses the availability of spawning and nursery habitats for the European sturgeon...
3.
van den Heuvel-Greve M, Jonker M, Klaassen M, Puts I, Verbeeke G, Hoekema L, et al.
Environ Toxicol Chem
. 2024 Jun;
43(7):1627-1637.
PMID: 38837458
Shipping activities are increasing with sea ice receding in the Arctic, leading to higher risks of accidents and oil spills. Because Arctic toxicity data are limited, oil spill risk assessments...
4.
Hermans A, Winter H, Gill A, Murk A
Environ Pollut
. 2024 Feb;
346:123570.
PMID: 38360387
Subsea power cables cause electromagnetic fields (EMFs) into the marine environment. Elasmobranchs (rays, skates, sharks) are particularly sensitive to EMFs as they use electromagnetic-receptive sensory systems for orientation, navigation, and...
5.
Karengera A, Bao C, Bovee T, Dinkla I, Murk A
Environ Toxicol Chem
. 2022 Oct;
42(1):130-142.
PMID: 36282018
Gene expression profiling in Caenorhabditis elegans has been demonstrated to be a potential bioanalytical tool to detect the toxic potency of environmental contaminants. The RNA transcripts of genes responding to...
6.
Foekema E, Keur M, van der Vlies L, van der Weide B, Bittner O, Murk A
Environ Pollut
. 2022 Oct;
315:120429.
PMID: 36244502
For two months, communities in 5.8 m outdoor marine mesocosms were exposed to 700 μm sphere-shaped polystyrene (PS) beads in dosages between 0.08 and 80 g/m. Barnacle (Semibalanus balanoides) densities...
7.
Karengera A, Verburg I, Sterken M, Riksen J, Murk A, Dinkla I
Arch Environ Contam Toxicol
. 2022 Oct;
83(3):284-294.
PMID: 36190544
With chemical analysis, it is impossible to qualify and quantify the toxic potency of especially hydrophilic bioactive contaminants. In this study, we applied the nematode C. elegans as a model...
8.
Breve N, Leuven R, Buijse A, Murk A, Venema J, Nagelkerke L
Sci Total Environ
. 2022 Jul;
848:157641.
PMID: 35908701
Sturgeons rank among the most endangered vertebrates in the world. Yet, the dwindling of wild sturgeon populations stands in stark contrast to their thriving status in aquaculture. Moreover, through the...
9.
Karengera A, Sterken M, Kammenga J, Riksen J, Dinkla I, Murk A
Ecotoxicol Environ Saf
. 2022 Feb;
233:113344.
PMID: 35219257
Caenorhabditis elegans is a well-established model organism for toxicity testing of chemical substances. We recently demonstrated its potential for bioanalysis of the toxic potency of chemical contaminants in water. While...
10.
Karengera A, Bao C, Riksen J, van Veelen H, Sterken M, Kammenga J, et al.
Ecotoxicol Environ Saf
. 2021 Oct;
227:112923.
PMID: 34700171
Low concentrations of environmental contaminants can be difficult to detect with current analytical tools, yet they may pose a risk to human and environmental health. The development of bioanalytical tools...