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Page 86

Volume 7, Issue 6 (Suppl)

J Biotechnol Biomater, an open access journal

ISSN: 2155-952X

World Biotechnology 2017

December 04-05, 2017

2

nd

World Biotechnology Congress

December 04-05, 2017 | Sao Paulo, Brazil

Synthetic biology for detection of contaminants and for diagnose of disease: New biotechnology

R G Cuero

International Park of Creativity, Colombia

D

espite the great advances on diagnostic technologies for disease and for detection of environmental contaminants (i.e. pesticides,

heavy metals, hydrocarbons, and others), there is still a need for a non-endpoint diagnose in addition to better precision

and real-time results. Therefore, herein we are presenting a novel approach based on synthetic biology to diagnose disease and

for detection of environmental contaminants/pollutants. Our technology is based on a construct microbial DNA sensor. Thus, we

developed three types of DNA sensors for early detection of diabetes (US Patent No.: 9,683,266 B2, June 20, 2017) Alzheimer’s disease

(patent pending), respectively. Also, we developed a microbial DNA sensor for detection of heavy metals in soil. Although microbial/

molecular sensors have been used for detecting different biological molecules, chemicals, as well as contaminants, their sensitivity

is limited. Therefore, we present here three types of sensors with higher sensitivity based on assemblage of different genetic parts

which are cloned on benign bake yeast, Saccharomyces cerevisiae. The genetic parts were sequences related to proteins for detections

of molecules such as glucose or beta-amyloid for diagnosing of diabetes or Alzheimer’s disease, respectively. We also assembled a

genetic building block for identification of specific heavy metals in soil. The diagnosis was based on the biofluorescence emitted by

the mixture of the DNA sensor with patient blood plasma when the respective molecule or proteins have been detected. Hence, the

degree of the diagnosed disease is based on the intensity of the fluorescence unit (FSU). Likewise, the microbial DNA metal sensor

was able to identify different heavy metals in soil at very low concentrations, also based on the intensity of the fluorescence of the

DNA sensor. The denoted technology brings great advantages, since it enables us to accurately classify diabetes patients in different

groups (i.e. diabetic, pre-diabetic, normal), thus predicting development of the disease at early stages. In addition to early detection

of the disease, the present technology also allows for earlier clinical intervention. Similarly, the technology enables us to identify

metal contaminations which are undetectable under conventional methods. The above mentioned synthetic biology approach was

effectively supported by a computational modeling. This new biotechnology applied to the medical and environmental fields facilitate

the integration of different molecular techniques with physiological mechanisms at the cellular and molecular level on real time,

based on the integration of biological sciences, engineering, and computational modeling for a more predictable biological process.

This allows biology to become more effective at the industrial level not only for health solutions but also for economic benefit

olimpa@aol.com

J Biotechnol Biomater 2017, 7:6 (Suppl)

DOI: 10.4172/2155-952X-C1-086