Matthew Prideaux
Biochemistry, Genetics and Molecular Biology · Indiana University
Publications
86
Citations
2,981
Est. group size
~5
Recurring co-author estimate
Active years
21
Publishing since 2006
Matthew Prideaux studies the biology of bone, with a focus on osteocytes cells embedded within bone tissue that sense mechanical forces and help regulate bone formation and breakdown. His work examines how these cells use energy (metabolism), respond to signals and aging, and communicate with the rest of the body, using tools such as single-cell gene sequencing and 3D tissue culture platforms. The research connects to conditions like osteoporosis, bone infection, and aging-related bone loss.
Publication activity has been steady with year-to-year fluctuation, averaging about 5-6 papers per year over the last five years.
Generated by claude-opus-4-8 from public bibliographic data · Jul 11, 2026
- Osteocyte biology
Elsevier eBooks · 2026
- List of contributors
Elsevier eBooks · 2026
- High-resolution profiling of osteocyte transcriptomes via single-nucleus RNA sequencing
JBMR Plus · 2026
- Osteocyte differentiation requires glucose metabolism, but mature osteocytes display metabolic flexibility
Bone · 2025
- Osteocyte Differentiation Requires Glycolysis, but Mature Osteocytes Display Metabolic Flexibility
bioRxiv (Cold Spring Harbor Laboratory) · 2025
- The ‘bIUreactor’: An Open-Source 3D Tissue Research Platform
Annals of Biomedical Engineering · 2024
- Regulation of the Osteocyte Secretome with Aging and Disease
Calcified Tissue International · 2023
- Targeting osteocytes vs osteoblasts
Bone · 2023
- Response to Letter to Editor regarding “Morphology and cell biology - two sides of the same coin: Importance of morphology in choosing Cre experimental models for targeting osteoblasts vs osteocytes”
Bone · 2023
- <scp>L‐BAIBA</scp> Synergizes with Sub‐Optimal Mechanical Loading to Promote New Bone Formation
JBMR Plus · 2023
- Fatty Acid Excess Increases Lipid Droplet Size and Modifies Gene Expression in Osteocytes
Proceedings of IMPRS · 2023
- Author response for "<scp>L‐BAIBA</scp> Synergizes with Sub‐Optimal Mechanical Loading to Promote New Bone Formation"
2023
- Osteocytes directly regulate osteolysis via MYD88 signaling in bacterial bone infection
Nature Communications · 2022
- THE ROLE OF PPARδ-DRIVEN β-OXIDATION IN BONE HEALTH DURING AGING
Innovation in Aging · 2022
- Sclerostin Directly Stimulates Osteocyte Synthesis of Fibroblast Growth Factor-23
Calcified Tissue International · 2021
- Bone×6
- Journal of Bone and Mineral Research×4
- JBMR Plus×4
- bioRxiv (Cold Spring Harbor Laboratory)×4
- eLife×3
This profile was generated automatically from public scholarly data (OpenAlex). Group size and activity levels are estimates derived from co-authorship patterns.
Last updated Jul 11, 2026.
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