Anahita Karimi of Potsdam, N.Y. , Graduates from Clarkson University
Anahita Karimi of Potsdam, N.Y. , received a doctor of philosophy degree in chemistry from Clarkson University on May 13. Clarkson University educates the leaders of the global economy. One i...
June, 06 2017 - Verified by Clarkson University
Clarkson University Doctoral Student Anahita Karimi Wins Travel Grant for International Conference on Electrochemistry
Clarkson University chemistry doctoral student Anahita Karimi has won a travel grant from the Electrochemical Society (ECS) to attend the biannual ECS Meeting in October in Phoenix, Ariz. Karimi o...
October, 07 2015 - Verified by Clarkson University
Research Assistant at Clarkson University
-Working on application of Nano-impact electrochemistry for detection and characterization of nanoparticles
*Development of electroanalytical collision technique to characterize the fundamental surface properties, functionalization and redox reactivity of metal and metal oxide nanoparticles
*Assessment of redox active nanoparticles for monitoring biorecognition events at single particle surfaces for applications in sensing
-Development of oxidase-based bioelectrodes operating in oxygen-deficient environment using engineered nanoparticles
*Optimizing the lactate oxidase biosensor based on ceria nanoparticles for the detection of lactate in hypoxic media and miniaturizing the sensor for testing in vivo
*Developing nanoparticle based bioelectrodes to operate in hypoxic condition for the use in biofuel cells
August 2013 - Present
PhD Candidate at Clarkson University
• PhD Candidate in Bioanalytical Chemistry at Clarkson University (Fall 2013-present) (GPA: 4/4) BIOSEM (Biosensors, Bioelectrochemistry, Biomaterials) Research Group
Advisor: Prof. S. Andreescu
o Thesis: Electroanalytical Evaluation of Nanoparticles by Nano-impact Electrochemistry
* Monitoring biorecognition events at single particle surfaces by assessing redox active nanoparticles for applications in sensing
* Development of electroanalytical collision technique to characterize the fundamental surface properties, functionalization and redox reactivity of metal and metal oxide nanoparticles
o Development of oxidase-based bioelectrodes operating in oxygen-deficient environment using engineered nanoparticles
* Optimizing the lactate oxidase biosensor based on ceria nanoparticles for the detection of lactate in hypoxic media and miniaturizing the sensor for testing in vivo
* Developing nanoparticle based bioelectrodes to operate in hypoxic condition for the use in biofuel cells
August 2013 - Present