Celeste Dunn Data-verified
Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.
Researcher
unknown
Research Areas
Biography and Research Information
OverviewAI-generated summary
Celeste Dunn's research investigates the physiological and molecular responses to various stimuli, including traumatic brain injury and dietary components. Her work has explored the breakdown of the blood-brain barrier and astrocyte reactivity following repeated traumatic brain injury, with a focus on the cortical transcriptome and proteome. This research has identified neurogenesis, inflammation, and cell death as key processes affected by such injuries. Dunn has also examined the safety and nutritional aspects of novel food ingredients, such as Fy Protein™, for human consumption. Her scholarship metrics include an h-index of 4, with 8 total publications and 88 citations. She has collaborated with researchers at the University of Arkansas at Fayetteville, including Kartik Balachandran, Jeffrey C. Wolchok, and Sara M. Venier, as well as Syed F. Ali from the National Center for Toxicological Research, with whom she shares multiple publications.
Metrics
- h-index: 4
- Publications: 8
- Citations: 90
Selected Publications
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Functional Analysis of the Cortical Transcriptome and Proteome Reveal Neurogenesis, Inflammation, and Cell Death after Repeated Traumatic Brain Injury <i>In vivo</i> (2022)
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Blood–Brain Barrier Breakdown and Astrocyte Reactivity Evident in the Absence of Behavioral Changes after Repeated Traumatic Brain Injury (2021)
Collaboration Network
Top Collaborators
- Blood–Brain Barrier Breakdown and Astrocyte Reactivity Evident in the Absence of Behavioral Changes after Repeated Traumatic Brain Injury
- Functional Analysis of the Cortical Transcriptome and Proteome Reveal Neurogenesis, Inflammation, and Cell Death after Repeated Traumatic Brain Injury <i>In vivo</i>
- Blood–Brain Barrier Breakdown and Astrocyte Reactivity Evident in the Absence of Behavioral Changes after Repeated Traumatic Brain Injury
- Functional Analysis of the Cortical Transcriptome and Proteome Reveal Neurogenesis, Inflammation, and Cell Death after Repeated Traumatic Brain Injury <i>In vivo</i>
- Blood–Brain Barrier Breakdown and Astrocyte Reactivity Evident in the Absence of Behavioral Changes after Repeated Traumatic Brain Injury
- Functional Analysis of the Cortical Transcriptome and Proteome Reveal Neurogenesis, Inflammation, and Cell Death after Repeated Traumatic Brain Injury <i>In vivo</i>
- Blood–Brain Barrier Breakdown and Astrocyte Reactivity Evident in the Absence of Behavioral Changes after Repeated Traumatic Brain Injury
- Blood–Brain Barrier Breakdown and Astrocyte Reactivity Evident in the Absence of Behavioral Changes after Repeated Traumatic Brain Injury
- Safety evaluation of Fy Protein™ (Nutritional Fungi Protein), a macroingredient for human consumption
- Safety evaluation of Fy Protein™ (Nutritional Fungi Protein), a macroingredient for human consumption
- Safety evaluation of Fy Protein™ (Nutritional Fungi Protein), a macroingredient for human consumption
- Safety evaluation of Fy Protein™ (Nutritional Fungi Protein), a macroingredient for human consumption
- Safety evaluation of Fy Protein™ (Nutritional Fungi Protein), a macroingredient for human consumption
- Functional Analysis of the Cortical Transcriptome and Proteome Reveal Neurogenesis, Inflammation, and Cell Death after Repeated Traumatic Brain Injury <i>In vivo</i>
- Functional Analysis of the Cortical Transcriptome and Proteome Reveal Neurogenesis, Inflammation, and Cell Death after Repeated Traumatic Brain Injury <i>In vivo</i>
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