L
Liam J. Stephens
Researcher at Monash University, Clayton campus
Publications - 7
Citations - 53
Liam J. Stephens is an academic researcher from Monash University, Clayton campus. The author has contributed to research in topics: Antibacterial activity & Cytotoxic T cell. The author has an hindex of 3, co-authored 7 publications receiving 20 citations. Previous affiliations of Liam J. Stephens include Monash University.
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Journal ArticleDOI
Is Bismuth Really the "Green" Metal? Exploring the Antimicrobial Activity and Cytotoxicity of Organobismuth Thiolate Complexes.
Liam J. Stephens,Sarmishta Munuganti,Tom H. Moran,Rebekah N. Duffin,Melissa V. Werrett,Philip C. Andrews +5 more
TL;DR: It is demonstrated that the environment surrounding the metal center has a clear influence on the safety of bismuth-containing complexes and the first insights into the biological mode of action of these particular bismUTH thiolates were revealed.
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Antimicrobial innovation: a current update and perspective on the antibiotic drug development pipeline.
TL;DR: Using clinical trials data, company website information and the most recent press releases, a current update of the antibiotic drug development pipeline is included and aims to provide an insight into the predicament that the authors face.
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Impact of structural changes in heteroleptic bismuth phosphinates on their antibacterial activity in Bi-nanocellulose composites
Megan E. Herdman,Melissa V. Werrett,Rebekah N. Duffin,Liam J. Stephens,Rajini Brammananth,Ross L. Coppel,Warren Batchelor,Philip C. Andrews +7 more
TL;DR: Four mono-phosphinato bismuth complexes used to produce antibacterial nanocellulose composites displayed an increased level of toxicity towards mammalian cells (COS-7, human and murine fibroblasts), where it was shown the complexes disrupt cellular membranes leading to cytotoxicity.
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Bismuth(III) Flavonolates: The Impact of Structural Diversity on Antibacterial Activity, Mammalian Cell Viability and Cellular Uptake.
TL;DR: Bismuth(III) flavonolates: the impact of structural diversity on antibacterial activity, mammalian cell viability, and cellular uptake is studied.
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Bismuth(III) Thiophosphinates: Understanding How a Small Atomic Change Influences Antibacterial Activity and Mammalian Cell Viability
Dimuthu C. Senevirathna,Rebekah N. Duffin,Liam J. Stephens,Megan E. Herdman,Melissa V. Werrett,Philip C. Andrews +5 more
TL;DR: In this article, diphenylphosphinothioic acid (HSP(=O)Ph2) and HSP( =S)ph2) were used to synthesize four BiIII complexes: 1 [Bi(SP(O)PH2)3], 2 [BiPh(SP[O]Ph2]2], 3 [BiPH[SP[S]Ph 2], 4] using BiPh[OtBu] as bismuth sources.