Asmaa A. Sadoon Data-verified
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Director: Rick Wise
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Biography and Research Information
OverviewAI-generated summary
Asmaa A. Sadoon's research focuses on understanding fundamental biological processes at the molecular level. Her work investigates the diffusion of proteins within bacteria, examining the applicability of established physical laws like the Stokes-Einstein equation. Sadoon also explores novel methods for detecting and monitoring antibiotic resistance genes in environmental samples, integrating basic separation techniques with advanced quantification strategies. A significant portion of her research utilizes molecular dynamics simulations to elucidate the mechanisms behind DNA-based amplifying sensors, contributing to the development of new biosensing technologies. Sadoon's scholarship metrics include an h-index of 5, with 10 total publications and 141 citations. She has collaborated with researchers including W. F. Oliver, Jiali Li, Katherine M. Bullard, and Deborah Okyere, all at the University of Arkansas at Fayetteville.
Metrics
- h-index: 5
- Publications: 10
- Citations: 142
Selected Publications
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A Practical Framework for Integrating Basic Separation Techniques with Molecular Quantification to Extract and Monitor Antibiotic Resistance Genes in Water Samples (2025)
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Understanding the Mechanism of Bent DNA Amplifying Sensors Using All-Atom Molecular Dynamics Simulations (2025)
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Revisiting the Temperature Dependence of Protein Diffusion inside Bacteria: Validity of the Stokes-Einstein Equation (2022)
Collaboration Network
Top Collaborators
- Revisiting the Temperature Dependence of Protein Diffusion inside Bacteria: Validity of the Stokes-Einstein Equation
- Understanding the Mechanism of Bent DNA Amplifying Sensors Using All-Atom Molecular Dynamics Simulations
- A Practical Framework for Integrating Basic Separation Techniques with Molecular Quantification to Extract and Monitor Antibiotic Resistance Genes in Water Samples
- Revisiting the Temperature Dependence of Protein Diffusion inside Bacteria: Validity of the Stokes-Einstein Equation
- Understanding the Mechanism of Bent DNA Amplifying Sensors Using All-Atom Molecular Dynamics Simulations
- Understanding the Mechanism of Bent DNA Amplifying Sensors Using All-Atom Molecular Dynamics Simulations
- Understanding the Mechanism of Bent DNA Amplifying Sensors Using All-Atom Molecular Dynamics Simulations
- Understanding the Mechanism of Bent DNA Amplifying Sensors Using All-Atom Molecular Dynamics Simulations
- Understanding the Mechanism of Bent DNA Amplifying Sensors Using All-Atom Molecular Dynamics Simulations
- A Practical Framework for Integrating Basic Separation Techniques with Molecular Quantification to Extract and Monitor Antibiotic Resistance Genes in Water Samples
- A Practical Framework for Integrating Basic Separation Techniques with Molecular Quantification to Extract and Monitor Antibiotic Resistance Genes in Water Samples
- A Practical Framework for Integrating Basic Separation Techniques with Molecular Quantification to Extract and Monitor Antibiotic Resistance Genes in Water Samples
- A Practical Framework for Integrating Basic Separation Techniques with Molecular Quantification to Extract and Monitor Antibiotic Resistance Genes in Water Samples
- A Practical Framework for Integrating Basic Separation Techniques with Molecular Quantification to Extract and Monitor Antibiotic Resistance Genes in Water Samples
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