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Volume 7

Biosensors Journal

ISSN: 2090-4967

Electrochemistry 2018

June 11-12, 2018

June 11-12, 2018 | Rome, Italy

4

th

International Conference on

Electrochemistry

Electrochemical breast cancer screening technology facilitating earlier clinical diagnosis

Mackenzie Honikel

and

Jeffrey T LaBelle

Arizona State University, USA

Statement of the Problem:

Breast cancer remains the second leading cause of cancer related death among women and accounts

for nearly one in three cancer diagnoses. Advances in mammography have helped improve the early detection rate; however,

noninvasive imaging modalities are unable to accurately identify the molecular subtype of the disease, therefore delaying

treatment until further validation. In addition, technological advancements have increased annual screening costs, segregating

lower income populations from proper preventative care. To facilitate earlier diagnosis and treatment, a point-of-care (POC)

electrochemical biosensor is currently being pursued to provide immediate, sensitive and specific diagnostic information.

Methodology & Theoretical Orientation:

Using electrochemical impedance spectroscopy (EIS) and a novel imaginary

impedance algorithm a panel of biomarkers can be detected, simultaneously. Through the identification of a biomarker’s

respective optimal binding frequency rapid signal acquisition is achievable, permitting signal deconvolution and robust

characteristics.

Findings:

Currently we have validated detection of a previously FDA approved biomarker on a benchtop electrode platform

revealing low limits of quantification. Upon the characterization of other breast cancer indicative biomarkers, a multiplexed

POC sensor will be developed and validated in complex media and clinical samples. Additionally, a screen-printed electrode

platform and novel immobilization protocol will be adopted for increased feasibility in clinical use.

Conclusion & Significance:

We propose that the developed technology in conjunction with electrochemical detection

methodologies has profound applications in other medical conditions where a rapid diagnostic test could be useful in

supplementing clinical diagnosis.

Figure 1:

Left: Imaginary impedance overlay across a range of antigen concentrations. Right: Determination of optimal binding frequency

Recent Publications:

1.

Malkoc A, Lin C, Probst D, Honikel M and La Belle J (2017) Toward the future development of an electrochemical

continuous biosensor for enhanced glycemic management. Journal of Diabetes Science and Technology 11(5):1053-1054.

2.

Lin C, Pratt B, Honikel M, Jenish A, Ramesh B, Alkhan A and La Belle J (2017) Toward the development of a glucose

dehydrogenase-based saliva glucose sensor without the need for sample preparation. Journal of Diabetes Science and

Technology 12(1):83-89.

3.

Lin C, Honikel M and La Belle J (2017) Amulti-marker approach for improved glycemic management in diabetes mellitus.

Journal of Diabetes, Metabolic Disorders and Control. 4(5): 00124

Biography

Mackenzie Honikel is a current PhD student in the School of Biological and Health Systems Engineering at Arizona State University, mentored by Dr. Jeffrey

LaBelle. She graduated from Binghamton University in May 2016 with a Bachelor’s degree in Biomedical Engineering, with a concentration in biomedical devices.

Her research background is in point-of-care diagnostics and she aims to continue this work during her doctoral training. Her current research focuses on the

development of a continuous, implantable sensor platform for continuous monitoring throughout the episode of care for breast cancer patients

mhonikel@asu.edu

Mackenzie Honikel et al., Biosens J 2018, Volume 7

DOI: 10.4172/2090-4967-C1-002