Theoretical modeling of viscosity monitoring with vibrating resonance energy transfer for point-of-care and environmental monitoring applications

Name: Theoretical modeling of viscosity monitoring with vibrating resonance energy transfer for point-of-care and environmental monitoring applications
Author: Memişoğlu, G., Gülbahar, Burhan, Zubia, J., Villatoro, J.

İsim	Theoretical modeling of viscosity monitoring with vibrating resonance energy transfer for point-of-care and environmental monitoring applications
Yazar	Memişoğlu, G., Gülbahar, Burhan, Zubia, J., Villatoro, J.
Basım Tarihi:	2019-01-01
Basım Yeri	- MDPI
Konu	Forster resonance energy transfer (FRET), Viscosity monitoring, Fluidic characterization, Microfluidics, Point-of-care, Environmental monitoring
Tür	Süreli Yayın
Dil	İngilizce
Dijital	Evet
Yazma	Hayır
Kütüphane:	Özyeğin Üniversitesi
Demirbaş Numarası	2072-666X
Kayıt Numarası	09e820b4-5e03-46a7-8a00-502108bba042
Lokasyon	Electrical & Electronics Engineering
Tarih	2019-01-01
Notlar	European Union (EU) ; Ministerio de Economia y Competitividad (MINECO) ; Eusko Jaurlaritza ; Vestel Electronics Inc.
Örnek Metin	Forster resonance energy transfer (FRET) between two molecules in nanoscale distances is utilized in significant number of applications including biological and chemical applications, monitoring cellular activities, sensors, wireless communications and recently in nanoscale microfluidic radar design denoted by the vibrating FRET (VFRET) exploiting hybrid resonating graphene membrane and FRET design. In this article, a low hardware complexity and novel microfluidic viscosity monitoring system architecture is presented by exploiting VFRET in a novel microfluidic system design. The donor molecules in a microfluidic channel are acoustically vibrated resulting in VFRET in the case of nearby acceptor molecules detected with their periodic optical emission signals. VFRET does not require complicated hardware by directly utilizing molecular interactions detected with the conventional photodetectors. The proposed viscosity measurement system design is theoretically modeled and numerically simulated while the experimental challenges are discussed. It promises point-of-care and environmental monitoring applications including viscosity characterization of blood or polluted water.
DOI	10.3390/mi10010003
Cilt	10

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Theoretical modeling of viscosity monitoring with vibrating resonance energy transfer for point-of-care and environmental monitoring applications

Yazar Memişoğlu, G., Gülbahar, Burhan, Zubia, J., Villatoro, J.

Basım Tarihi 2019-01-01

Basım Yeri - MDPI

Konu Forster resonance energy transfer (FRET), Viscosity monitoring, Fluidic characterization, Microfluidics, Point-of-care, Environmental monitoring

Tür Süreli Yayın

Dil İngilizce

Dijital Evet

Yazma Hayır

Kütüphane Özyeğin Üniversitesi

Demirbaş Numarası 2072-666X

Kayıt Numarası 09e820b4-5e03-46a7-8a00-502108bba042

Lokasyon Electrical & Electronics Engineering

Tarih 2019-01-01

Notlar European Union (EU) ; Ministerio de Economia y Competitividad (MINECO) ; Eusko Jaurlaritza ; Vestel Electronics Inc.

Örnek Metin Forster resonance energy transfer (FRET) between two molecules in nanoscale distances is utilized in significant number of applications including biological and chemical applications, monitoring cellular activities, sensors, wireless communications and recently in nanoscale microfluidic radar design denoted by the vibrating FRET (VFRET) exploiting hybrid resonating graphene membrane and FRET design. In this article, a low hardware complexity and novel microfluidic viscosity monitoring system architecture is presented by exploiting VFRET in a novel microfluidic system design. The donor molecules in a microfluidic channel are acoustically vibrated resulting in VFRET in the case of nearby acceptor molecules detected with their periodic optical emission signals. VFRET does not require complicated hardware by directly utilizing molecular interactions detected with the conventional photodetectors. The proposed viscosity measurement system design is theoretically modeled and numerically simulated while the experimental challenges are discussed. It promises point-of-care and environmental monitoring applications including viscosity characterization of blood or polluted water.

DOI 10.3390/mi10010003

Cilt 10