William T. Self

University of Central Florida

H-index: 47

North America-United States

About William T. Self

William T. Self, With an exceptional h-index of 47 and a recent h-index of 32 (since 2020), a distinguished researcher at University of Central Florida, specializes in the field of Metal and metalloid metabolism, metalloenzymes, selenoproteins, cerium oxide nanomaterials, redox-active nanomaterials.

His recent articles reflect a diverse array of research interests and contributions to the field:

Inhibition of selenoprotein synthesis is not the mechanism by which auranofin inhibits growth of Clostridioides difficile

Evaluation of Derivatives of (+)-Puupehenone against Clostridioides difficile and Other Gram-Positive Bacteria

d-Proline Reductase Underlies Proline-Dependent Growth of Clostridioides difficile

Exploring the selenium-over-sulfur substrate specificity and kinetics of a bacterial selenocysteine lyase

Implant and coating to reduce osteolysis

William T. Self Information

University	University of Central Florida
Position	Professor Burnett School of Biomedical Science
Citations(all)	12582
Citations(since 2020)	5999
Cited By	9330
hIndex(all)	47
hIndex(since 2020)	32
i10Index(all)	63
i10Index(since 2020)	51
Email	Access Email
University Profile Page	University of Central Florida
Google Scholar	View Google Scholar Profile

William T. Self Skills & Research Interests

Metal and metalloid metabolism

metalloenzymes

selenoproteins

cerium oxide nanomaterials

redox-active nanomaterials

Top articles of William T. Self

Title	Journal	Author(s)	Publication Date
Inhibition of selenoprotein synthesis is not the mechanism by which auranofin inhibits growth of Clostridioides difficile	Scientific Reports	Michael A Johnstone Matthew A Holman William T Self	2023/9/7
Evaluation of Derivatives of (+)-Puupehenone against Clostridioides difficile and Other Gram-Positive Bacteria	ACS omega	Michael A Johnstone Alexander D Landgraf Anshupriya Si Steven J Sucheck William T Self	2022/9/9
d-Proline Reductase Underlies Proline-Dependent Growth of Clostridioides difficile	Journal of Bacteriology	Michael A Johnstone William T Self	2022/8/16
Exploring the selenium-over-sulfur substrate specificity and kinetics of a bacterial selenocysteine lyase	Biochimie	Michael A Johnstone Samantha J Nelson Christine O’Leary William T Self	2021/3/1
Implant and coating to reduce osteolysis			2021/9/23