David Cameron‐Smith
About
David Cameron‐Smith is a scholar working on Physiology, Molecular Biology and Cell Biology.
According to data from OpenAlex, David Cameron‐Smith has authored 318 papers receiving a total of 12.3k indexed citations (citations by other indexed papers that have themselves been cited), including 150 papers in Physiology, 111 papers in Molecular Biology and 103 papers in Cell Biology. Recurrent topics in David Cameron‐Smith's work include Muscle metabolism and nutrition (102 papers), Adipose Tissue and Metabolism (80 papers) and Muscle Physiology and Disorders (54 papers). David Cameron‐Smith is often cited by papers focused on Muscle metabolism and nutrition (102 papers), Adipose Tissue and Metabolism (80 papers) and Muscle Physiology and Disorders (54 papers). David Cameron‐Smith collaborates with scholars based in Australia, New Zealand and Singapore. David Cameron‐Smith's co-authors include James F. Markworth, Andrew J. Sinclair, Mark Hargreaves, Sally D. Poppitt, Cameron J. Mitchell, Robin A. McGregor, Jonathan M. Peake, Kate A. Carey, Rebecca J. Tunstall and Gunveen Kaur and has published in prestigious journals such as Proceedings of the National Academy of Sciences, SHILAP Revista de lepidopterología and PLoS ONE.
In The Last Decade
David Cameron‐Smith
312 papers receiving 12.0k citations
Author Peers
Peers are selected by citation overlap in the author's most active subfields. citations · hero ref
| Author | Last Decade | Papers | Cites | |||||
|---|---|---|---|---|---|---|---|---|
| David Cameron‐Smith | 5.2k | 4.2k | 3.1k | 1.9k | 1.7k | 318 | 12.3k | |
| Kevin E. Yarasheski | 6.7k 1.3× | 4.7k 1.1× | 3.6k 1.2× | 1.1k 0.6× | 485 0.3× | 189 | 16.8k | |
| Elena Volpi | 10.3k 2.0× | 5.5k 1.3× | 8.6k 2.8× | 1.9k 1.0× | 1.1k 0.7× | 184 | 17.0k | |
| Scott K. Powers | 5.0k 1.0× | 5.5k 1.3× | 2.9k 1.0× | 4.5k 2.4× | 783 0.5× | 278 | 18.3k | |
| P. Darrell Neufer | 6.2k 1.2× | 5.3k 1.3× | 2.9k 0.9× | 1.9k 1.0× | 334 0.2× | 142 | 11.2k | |
| Joseph A. Houmard | 9.6k 1.9× | 4.5k 1.1× | 3.5k 1.1× | 1.8k 0.9× | 634 0.4× | 235 | 16.6k | |
| Blake B. Rasmussen | 6.6k 1.3× | 5.5k 1.3× | 7.2k 2.3× | 2.1k 1.1× | 541 0.3× | 165 | 13.7k | |
| Malcolm J. Jackson | 4.6k 0.9× | 6.0k 1.4× | 2.7k 0.9× | 5.7k 3.0× | 2.3k 1.4× | 328 | 15.2k | |
| W. W. Campbell | 7.5k 1.4× | 1.2k 0.3× | 3.2k 1.0× | 1.0k 0.5× | 1.2k 0.7× | 270 | 13.3k | |
| Zsolt Radák | 4.8k 0.9× | 3.8k 0.9× | 1.4k 0.5× | 2.9k 1.5× | 698 0.4× | 218 | 11.7k | |
| Gerrit van Hall | 4.6k 0.9× | 2.3k 0.5× | 2.4k 0.8× | 2.2k 1.2× | 286 0.2× | 205 | 10.1k |
Countries citing papers authored by David Cameron‐Smith
Since
Specialization
Citations
This map shows the geographic impact of David Cameron‐Smith's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by David Cameron‐Smith with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites David Cameron‐Smith more than expected).
Fields of papers citing papers by David Cameron‐Smith
Since
Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences
This network shows the impact of papers produced by David Cameron‐Smith. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by David Cameron‐Smith. The network helps show where David Cameron‐Smith may publish in the future.
Co-authorship network of co-authors of David Cameron‐Smith
This figure shows the co-authorship network connecting the top 25 collaborators of David Cameron‐Smith. A scholar is included among the top collaborators of David Cameron‐Smith based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with David Cameron‐Smith. David Cameron‐Smith is excluded from the visualization to improve readability, since they are connected to all nodes in the network.
All Works
1.
McKenna, Michael J., Aaron C. Petersen, Simon Sostaric, et al.. (2024). Digoxin and exercise effects on skeletal muscle Na+,K+‐ATPase isoform gene expression in healthy humans. Experimental Physiology. 109(11). 1909–1921.
2.
Silvestre, Marta P., et al.. (2024). Low serum glycine strengthens the association between branched-chain amino acids and impaired insulin sensitivity assessed before and after weight loss in a population with pre-diabetes: The PREVIEW_NZ cohort. Clinical Nutrition. 43(12). 17–25.
3.
Huang, Jian, Ai Peng Tan, Evelyn Law, et al.. (2023). Maternal preconception circulating blood biomarker mixtures, child behavioural symptom scores and the potential mediating role of neonatal brain microstructure: the S-PRESTO cohort. Translational Psychiatry. 13(1). 38–38.
4.
Tan, Karen, Mya Thway Tint, Kothandaraman Narasimhan, et al.. (2022). The Kynurenine Pathway Metabolites in Cord Blood Positively Correlate With Early Childhood Adiposity. The Journal of Clinical Endocrinology & Metabolism. 107(6). e2464–e2473.
5.
Tan, Karen, Mya Thway Tint, Kothandaraman Narasimhan, et al.. (2022). Association of plasma kynurenine pathway metabolite concentrations with metabolic health risk in prepubertal Asian children. International Journal of Obesity. 46(6). 1128–1137.
6.
Sostaric, Simon, Aaron C. Petersen, Craig A. Goodman, et al.. (2022). Oral digoxin effects on exercise performance, K+ regulation and skeletal muscle Na+,K+‐ATPase in healthy humans. The Journal of Physiology. 600(16). 3749–3774.
7.
Braakhuis, Andrea, Nicola Gillies, Scott O. Knowles, et al.. (2021). A Modern Flexitarian Dietary Intervention Incorporating Web-Based Nutrition Education in Healthy Young Adults: Protocol for a Randomized Controlled Trial. JMIR Research Protocols. 10(12). e30909–e30909.
8.
Zeng, Nina, Randall F. D’Souza, Vandré C. Figueiredo, et al.. (2021). Daily protein supplementation attenuates immobilization-induced blunting of postabsorptive muscle mTORC1 activation in middle-aged men. American Journal of Physiology-Cell Physiology. 320(4). C591–C601.
9.
Jones, Beatrix, Clare Wall, Eric B. Thorstensen, et al.. (2021). Plasma B Vitamers: Population Epidemiology and Parent-Child Concordance in Children and Adults. Nutrients. 13(3). 821–821.
10.
Woodhead, Jonathan S. T., Randall F. D’Souza, Christopher P. Hedges, et al.. (2020). High-intensity interval exercise increases humanin, a mitochondrial encoded peptide, in the plasma and muscle of men. Journal of Applied Physiology. 128(5). 1346–1354.
11.
Mitchell, Sarah M., Cameron J. Mitchell, Amber M. Milan, et al.. (2020). A period of 10 weeks of increased protein consumption does not alter faecal microbiota or volatile metabolites in healthy older men: a randomised controlled trial. Journal of Nutritional Science. 9. e25–e25.
12.
Rettedal, Elizabeth A., Paula Skidmore, David Cameron‐Smith, et al.. (2020). Short‐term high‐intensity interval training exercise does not affect gut bacterial community diversity or composition of lean and overweight men. Experimental Physiology. 105(8). 1268–1279.
13.
Figueiredo, Vandré C., Randall F. D’Souza, Douglas W. Van Pelt, et al.. (2020). Ribosome biogenesis and degradation regulate translational capacity during muscle disuse and reloading. Journal of Cachexia Sarcopenia and Muscle. 12(1). 130–143.
14.
Milan, Amber M., et al.. (2019). Comparison of the impact of bovine milk β-casein variants on digestive comfort in females self-reporting dairy intolerance: a randomized controlled trial. American Journal of Clinical Nutrition. 111(1). 149–160.
15.
Mitchell, Sarah M., Amber M. Milan, Cameron J. Mitchell, et al.. (2019). Protein Intake at Twice the RDA in Older Men Increases Circulatory Concentrations of the Microbiome Metabolite Trimethylamine-N-Oxide (TMAO). Nutrients. 11(9). 2207–2207.
16.
D’Souza, Randall F., Jonathan S. T. Woodhead, Nina Zeng, et al.. (2018). Circulatory exosomal miRNA following intense exercise is unrelated to muscle and plasma miRNA abundances. American Journal of Physiology-Endocrinology and Metabolism. 315(4). E723–E733.
17.
Mitchell, Cameron J., Randall F. D’Souza, William Schierding, et al.. (2018). Identification of human skeletal muscle miRNA related to strength by high-throughput sequencing. Physiological Genomics. 50(6). 416–424.
18.
Hedges, Christopher P., Jonathan S. T. Woodhead, Cameron J. Mitchell, et al.. (2018). Peripheral blood mononuclear cells do not reflect skeletal muscle mitochondrial function or adaptation to high-intensity interval training in healthy young men. Journal of Applied Physiology. 126(2). 454–461.
19.
Neubauer, Oliver, Surendran Sabapathy, Kevin J. Ashton, et al.. (2014). Time course-dependent changes in the transcriptome of human skeletal muscle during recovery from endurance exercise: from inflammation to adaptive remodeling. Griffith Research Online (Griffith University, Queensland, Australia).
20.
Koopman, René, et al.. (2006). Increase in S6K1 phosphorylation in human skeletal muscle following resistance exercise occurs mainly in type II muscle fibers. American Journal of Physiology-Endocrinology and Metabolism. 290(6). E1245–E1252.
Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.
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