Mikkel Winther Pedersen
Overview
Explore the profile of Mikkel Winther Pedersen including associated specialties, affiliations and a list of published articles.
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Articles
22
Citations
535
Followers
0
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Recent Articles
1.
Holman L, Zampirolo G, Gyllencreutz R, Scourse J, Froslev T, Caroe C, et al.
Mol Ecol Resour
. 2025 Feb;
:e14086.
PMID: 39980208
The condition of ancient marine ecosystems provides context for contemporary biodiversity changes in human-impacted oceans. Sequencing sedimentary ancient DNA (sedaDNA) is an emerging method for generating high-resolution biodiversity time-series data,...
2.
Eriksen A, Rodriguez J, Seersholm F, Hollund H, Gotfredsen A, Collins M, et al.
Commun Biol
. 2025 Feb;
8(1):210.
PMID: 39930064
Understanding the environmental and microbial processes involved in DNA degradation from archaeological remains is a fundamental part of managing bone specimens. We investigated the state of DNA preservation in 33...
3.
Vogel N, Rubin J, Pedersen A, Sackett P, Pedersen M, Renaud G
Mol Biol Evol
. 2024 Oct;
41(10).
PMID: 39361595
Ancient environmental DNA (aeDNA) is becoming a powerful tool to gain insights about past ecosystems, overcoming the limitations of conventional fossil records. However, several methodological challenges remain, particularly for classifying...
4.
Zampirolo G, Holman L, Sawafuji R, Ptakova M, Kovacikova L, Sida P, et al.
Curr Biol
. 2024 Sep;
34(20):4650-4661.e4.
PMID: 39305897
Central European forests have been shaped by complex human interactions throughout the Holocene, with significant changes following the introduction of domesticated animals in the Neolithic (∼7.5-6.0 ka before present [BP])....
5.
Laine J, Mak S, Martins N, Chen X, Gilbert M, Jones F, et al.
Curr Biol
. 2024 Feb;
34(5):1142-1147.e6.
PMID: 38350445
Directly observing the chronology and tempo of adaptation in response to ecological change is rarely possible in natural ecosystems. Sedimentary ancient DNA (sedaDNA) has been shown to be a tractable...
6.
Kjaer K, Pedersen M, De Sanctis B, De Cahsan B, Korneliussen T, Michelsen C, et al.
Nature
. 2022 Dec;
612(7939):283-291.
PMID: 36477129
Late Pliocene and Early Pleistocene epochs 3.6 to 0.8 million years ago had climates resembling those forecasted under future warming. Palaeoclimatic records show strong polar amplification with mean annual temperatures...
7.
Wang Y, Prohaska A, Dong H, Alberti A, Alsos I, Beilman D, et al.
Nature
. 2022 Nov;
612(7938):E4-E6.
PMID: 36450908
No abstract available.
8.
Scorrano G, Nielsen S, Vetro D, Sawafuji R, Mackie M, Margaryan A, et al.
Commun Biol
. 2022 Nov;
5(1):1262.
PMID: 36400919
Recent improvements in the analysis of ancient biomolecules from human remains and associated dental calculus have provided new insights into the prehistoric diet and genetic diversity of our species. Here...
9.
Wang Y, Pedersen M, Alsos I, De Sanctis B, Racimo F, Prohaska A, et al.
Nature
. 2022 Sep;
610(7931):E5.
PMID: 36163291
No abstract available.
10.
Wang Y, Pedersen M, Alsos I, De Sanctis B, Racimo F, Prohaska A, et al.
Nature
. 2022 Mar;
603(7903):E31.
PMID: 35296866
No abstract available.