Publications en collaboration avec des chercheurs de Queen Mary University of London (70)

2024

  1. Additional file 3 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  2. Additional file 3 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  3. Additional file 4 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  4. Additional file 4 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  5. Additional file 5 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  6. Additional file 5 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  7. Additional file 6 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  8. Additional file 6 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  9. Additional file 7 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  10. Additional file 7 of An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    figshare

  11. Assessing the role of Chemokine (C–C motif) ligand 14 in AKI: a European consensus meeting

    Renal Failure, Vol. 46, Núm. 1

  12. Current Status of Indole-Derived Marine Natural Products: Synthetic Approaches and Therapeutic Applications

    Marine Drugs, Vol. 22, Núm. 3

  13. Influence of bismuth and cobalt doping on structural, dielectric, and magnetic properties of M-type calcium hexagonal ferrites

    Journal of Alloys and Compounds, Vol. 994

  14. LANDMARK comparison of early outcomes of newer-generation Myval transcatheter heart valve series with contemporary valves (Sapien and Evolut) in real-world individuals with severe symptomatic native aortic stenosis: a randomised non-inferiority trial

    The Lancet, Vol. 403, Núm. 10445, pp. 2695-2708

  15. Transition-Metal-Catalyzed Transformations for the Synthesis of Marine Drugs

    Marine Drugs, Vol. 22, Núm. 6

2023

  1. A second update on mapping the human genetic architecture of COVID-19

    Nature

  2. An external quality assessment feasibility study; cross laboratory comparison of haemagglutination inhibition assay and microneutralization assay performance for seasonal influenza serology testing: A FLUCOP study

    Frontiers in Immunology, Vol. 14

  3. An observational human study investigating the effect of anabolic androgenic steroid use on the transcriptome of skeletal muscle and whole blood using RNA-Seq

    BMC Medical Genomics, Vol. 16, Núm. 1

  4. Erratum to: Mapping the human genetic architecture of COVID-19 (Nature, (2021), 600, 7889, (472-477), 10.1038/s41586-021-03767-x)

    Nature

  5. Maresin 1 activates brown adipose tissue and promotes browning of white adipose tissue in mice

    Molecular Metabolism, Vol. 74