Deep Neural Network Assisted Microfluidic pH Sensor

Henry E. Ventura-Grandez; Jonathan Quevedo; Itamar Salazar-Reque; Maria Armas-Alvarado; Luz Adanaque-Infante; Ruth Rubio-Noriega

doi:10.1109/JSEN.2025.3548912

Deep Neural Network Assisted Microfluidic pH Sensor

Henry E. Ventura-Grandez, Jonathan Quevedo, Itamar Salazar-Reque, Maria Armas-Alvarado, Luz Adanaque-Infante, Ruth Rubio-Noriega

Sección de Bioingeniería

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

Resumen

Water pH measurement is vital as it provides fundamental information about its quality and suitability for agriculture, aquatic ecosystems, industry, and human consumption. Each of these applications may require numerical readings of acidity or alkalinity, preferably using tools that are already ubiquitous, such as cellphones. This work presents a microfluidic lab-on-a-chip system to measure the pH of liquid samples. We used purple cabbage as the colorimetric reagent to produce a 2640-image dataset with pH levels in the range of [2-12] on a Polydimethylsiloxane microfluidic recipient. We fed our dataset to our parametrized Deep Neural Network to classify our samples and found an accuracy of 99.7%. Additionally, we developed a mobile application with an easy-to-use graphic user interface that recognizes the microfluidic device shape, classifies the image’s color, and returns the pH level. (Figure presented).

Idioma original	Inglés
Publicación	IEEE Sensors Journal
DOI	https://doi.org/10.1109/JSEN.2025.3548912
Estado	Aceptada/en prensa - 2025

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title = "Deep Neural Network Assisted Microfluidic pH Sensor",

abstract = "Water pH measurement is vital as it provides fundamental information about its quality and suitability for agriculture, aquatic ecosystems, industry, and human consumption. Each of these applications may require numerical readings of acidity or alkalinity, preferably using tools that are already ubiquitous, such as cellphones. This work presents a microfluidic lab-on-a-chip system to measure the pH of liquid samples. We used purple cabbage as the colorimetric reagent to produce a 2640-image dataset with pH levels in the range of [2-12] on a Polydimethylsiloxane microfluidic recipient. We fed our dataset to our parametrized Deep Neural Network to classify our samples and found an accuracy of 99.7\%. Additionally, we developed a mobile application with an easy-to-use graphic user interface that recognizes the microfluidic device shape, classifies the image{\textquoteright}s color, and returns the pH level. (Figure presented).",

keywords = "Colorimetry, machine learning, microfluidics, pH level",

author = "Ventura-Grandez, \{Henry E.\} and Jonathan Quevedo and Itamar Salazar-Reque and Maria Armas-Alvarado and Luz Adanaque-Infante and Ruth Rubio-Noriega",

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AU - Ventura-Grandez, Henry E.

AU - Quevedo, Jonathan

AU - Salazar-Reque, Itamar

AU - Armas-Alvarado, Maria

AU - Adanaque-Infante, Luz

AU - Rubio-Noriega, Ruth

PY - 2025

Y1 - 2025

N2 - Water pH measurement is vital as it provides fundamental information about its quality and suitability for agriculture, aquatic ecosystems, industry, and human consumption. Each of these applications may require numerical readings of acidity or alkalinity, preferably using tools that are already ubiquitous, such as cellphones. This work presents a microfluidic lab-on-a-chip system to measure the pH of liquid samples. We used purple cabbage as the colorimetric reagent to produce a 2640-image dataset with pH levels in the range of [2-12] on a Polydimethylsiloxane microfluidic recipient. We fed our dataset to our parametrized Deep Neural Network to classify our samples and found an accuracy of 99.7%. Additionally, we developed a mobile application with an easy-to-use graphic user interface that recognizes the microfluidic device shape, classifies the image’s color, and returns the pH level. (Figure presented).

AB - Water pH measurement is vital as it provides fundamental information about its quality and suitability for agriculture, aquatic ecosystems, industry, and human consumption. Each of these applications may require numerical readings of acidity or alkalinity, preferably using tools that are already ubiquitous, such as cellphones. This work presents a microfluidic lab-on-a-chip system to measure the pH of liquid samples. We used purple cabbage as the colorimetric reagent to produce a 2640-image dataset with pH levels in the range of [2-12] on a Polydimethylsiloxane microfluidic recipient. We fed our dataset to our parametrized Deep Neural Network to classify our samples and found an accuracy of 99.7%. Additionally, we developed a mobile application with an easy-to-use graphic user interface that recognizes the microfluidic device shape, classifies the image’s color, and returns the pH level. (Figure presented).

KW - Colorimetry

KW - machine learning

KW - microfluidics

KW - pH level

UR - https://www.scopus.com/pages/publications/105000364699

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JF - IEEE Sensors Journal

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Deep Neural Network Assisted Microfluidic pH Sensor

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