Fabrication and Packaging of a Dual Sensing Electrochemical Biotransducer for Glucose and Lactate Useful in Intramuscular Physiologic Status Monitoring

Rahman, Abdur; Justin, Gusphyl; Guiseppi-Wilson, Adilah; Guiseppi‐Elie, Anthony

doi:10.1109/jsen.2009.2031347

“…Nowadays, there is an increasing interest in the field of glucose biosensors, looking for Glucose Continous Monitoring (GCM). In the last years several works have been published in the field like Patel et al, (2007), where it's presented an electro-enzymatic glucose sensor, (Xi Huang et al, 2009), where it is introduced a capacitive based MEMS affinity sensor for continuous glucose monitoring applications, (Teymoori, Mir Majid et al, 2009) introducing a MEMS for glucose and other generical sensors in medical applications and (Rodrigues et al, 2007) where it's developed a new cell-based biochip dedicated to the real-time monitoring of transient effluxes of glucose and oxygen, using arrays of amperometric microsensors integrated in the inlet and the outlet of a PDMS cell chamber, and complete designs like (Rahman et al, 2009) where is presented the design, microfabrication, packaging, surface functionalization and in vitro testing of a complete electrochemical cell-on-a-chip (ECC) for the continuous amperometric monitoring of glucose, performing cyclic voltammetry, electrical impedance spectroscopy (EIS), and microscopic examination. Special interest has the development of nanosensors applied in this field.…”

Section: Some Examplesmentioning

confidence: 99%

Portable Bio-Devices: Design of electrochemical instruments from miniaturized to implantable devices

Colomer‐Farrarons¹,

Miribel-Català²,

Rodríguez-Villarreal³

et al. 2011

New Perspectives in Biosensors Technology and Applications

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“…Other interesting studies are provided by Rodrigues et al [45], who developed a new cell-based biochip dedicated to the real-time monitoring of transient effluxes of glucose and oxygen, using arrays of amperometric microsensors integrated in the inlet and the outlet of a PDMS cell chamber. A complete design is provided by Rahman et al [46], who present the design, microfabrication, packaging, surface functionalization and in vitro testing of a complete electrochemical cell-on-a-chip (ECC) for the continuous amperometric monitoring of glucose, performing cyclic voltammetry, electrical impedance spectroscopy (EIS) and microscopic examination.…”

Section: The Choice Of the Nanobiosensormentioning

confidence: 99%

Challenges facing academic research in commercializing event-detector implantable devices for an in-vivo biomedical subcutaneous device for biomedical analysis

Juanola-Feliu¹,

Colomer‐Farrarons²,

Miribel-Català³

et al. 2011

VLSI Circuits and Systems V

0

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It is widely recognized that the welfare of the most advanced economies is at risk, and that the only way to tackle this situation is by controlling the knowledge economies and dealing with. To achieve this ambitious goal, we need to improve the performance of each dimension in the "knowledge triangle": education, research and innovation. Indeed, recent findings point to the importance of strategies of adding-value and marketing during R+D processes so as to bridge the gap between the laboratory and the market and so ensure the successful commercialization of new technology-based products. Moreover, in a global economy in which conventional manufacturing is dominated by developing economies, the future of industry in the most advanced economies must rely on its ability to innovate in those high-tech activities that can offer a differential added-value, rather than on improving existing technologies and products. It seems quite clear, therefore, that the combination of health (medicine) and nanotechnology in a new biomedical device is very capable of meeting these requisites.This work propose a generic CMOS Front-End Self-Powered In-Vivo Implantable Biomedical Device, based on a threeelectrode amperometric biosensor approach, capable of detecting threshold values for targeted concentrations of pathogens, ions, oxygen concentration, etc.Given the speed with which diabetes can spread, as diabetes is the fastest growing disease in the world, the nano-enabled implantable device for in-vivo biomedical analysis needs to be introduced into the global diabetes care devices market. In the case of glucose monitoring, the detection of a threshold decrease in the glucose level it is mandatory to avoid critic situations like the hypoglycemia. Although the case study reported in this paper is complex because it involves multiple organizations and sources of data, it contributes to extend experience to the best practices and models on nanotechnology applications and commercialization.Nanotechnology provides breakthroughs that support endless sources of innovation and creativity at the intersection between medicine, biotechnology, engineering, the physical sciences and information technology, and the discipline is opening up new directions in R+D, knowledge management and technology transfer. A number of nanotech products are VLSI Circuits and Systems V, edited by Teresa Riesgo, Eduardo de la Torre-Arnanz,

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“…Nowadays, there is an increasing interest in the field of glucose biosensors, looking for Glucose Continous Monitoring (GCM). In the last years several works have been published in the field like Patel et al, (2007), where it's presented an electro-enzymatic glucose sensor, (Xi Huang et al, 2009), where it is introduced a capacitive based MEMS affinity sensor for continuous glucose monitoring applications, (Teymoori, Mir Majid et al, 2009) introducing a MEMS for glucose and other generical sensors in medical applications and (Rodrigues et al, 2007) where it's developed a new cell-based biochip dedicated to the real-time monitoring of transient effluxes of glucose and oxygen, using arrays of amperometric microsensors integrated in the inlet and the outlet of a PDMS cell chamber, and complete designs like (Rahman et al, 2009) where is presented the design, microfabrication, packaging, surface functionalization and in vitro testing of a complete electrochemical cell-on-a-chip (ECC) for the continuous amperometric monitoring of glucose, performing cyclic voltammetry, electrical impedance spectroscopy (EIS), and microscopic examination. Special interest has the development of nanosensors applied in this field.…”

Section: Some Examplesmentioning

confidence: 99%

New Perspectives in Biosensors Technology and Applications

Serra¹

2011

11

0

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Fabrication and Packaging of a Dual Sensing Electrochemical Biotransducer for Glucose and Lactate Useful in Intramuscular Physiologic Status Monitoring

Cited by 15 publications

References 17 publications

Portable Bio-Devices: Design of electrochemical instruments from miniaturized to implantable devices

Portable Bio-Devices: Design of electrochemical instruments from miniaturized to implantable devices

Challenges facing academic research in commercializing event-detector implantable devices for an in-vivo biomedical subcutaneous device for biomedical analysis

New Perspectives in Biosensors Technology and Applications

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