December 6, 2016

Low-cost paper-based skin patch monitors dehydration by changing color from sweat

Ziaie dehydration Purdue University researchers show off a newly developed skin patch that changes color to indicate different levels of hydration, representing a potential new medical technology. As sweat secretion increases, the strips are activated sequentially, changing from blue to red and providing easily identifiable levels of moisture loss. Here, the patch is shown recording hydration at specific time intervals. (Purdue University photo/ Vaibhav Jain, Manuel Ochoa) Download image

WEST LAFAYETTE, Ind. — Researchers have developed a low-cost skin patch that changes color to indicate different levels of hydration, representing a potential new medical technology.

Such an innovation might be used by marathon runners, military personnel and others to help prevent dehydration.

“Hydration in humans is a delicate parameter,” said Babak Ziaie, a professor of biomedical engineering and electrical and computer engineering at Purdue University. “Even small deviations such as 2 percent from normal levels can affect a person’s cognitive and physical performance by more than 30 percent.”

The palm-size patch consists of filter paper that is laser-machined to create a radial array of strips, which are laminated with a water-impermeable film to form microchannels. The channels are loaded with a water-activated dye at one end. As sweat secretion increases, the strips are activated sequentially, changing from blue to red and providing easily identifiable levels of moisture loss.

Findings were detailed in a research paper presented during the MicroTAS 2016 Conference in October.

“We have talked to many experts including marathon directors, the Ironman World Championship, Olympic triathlon athletes and many collegiate and professional coaches, athletes, race directors and EMTs to validate the need for this kind of product,” said graduate student Vaibhav Jain. “Also, two industrial companies have shown interest in our technology, and we are in talks with them.”

Conventional methods for monitoring hydration are either invasive, require non-portable equipment or do not yield results immediately. 

“In comparison, our approach is a fast, user-friendly dermal patch for collecting and measuring sweat secretion," Ziaie said. “And our fabrication process could be scaled up to large-volume manufacturing.”

The patch was tested at a sweating rate of 90 microliters per hour over a square centimeter of skin, which corresponds to normal human sweat rates.

The researchers have filed a patent application for the concept through the Office of Technology Commercialization of the Purdue Research Foundation.

Funding for this work was provided in part by the National Science Foundation. The research is based at the Birck Nanotechnology Center in Purdue’s Discovery Park.

During the MicroTAS conference, Jain was awarded a Ninth Annual Art in Science Award, sponsored by National Institute of Standards and Technology and Lab on a Chip magazine. The paper was co-authored by Jain; postdoctoral research associate Manuel Ochoa; and Ziaie. 

Writer: Emil Venere, 765-494-4709, venere@purdue.edu

Source: Babak Ziaie, 765-494-0725, bziaie@purdue.edu

Note to Journalists:  An electronic copy of the research paper is available by contacting Emil Venere, 765-494-4709, venere@purdue.edu 


ABSTRACT

A Low-Cost, Paper-Based Visual Indicator Patch for Monitoring Dehydration Rate Due to Sweating

V. Jain, M. Ochoa, and B. Ziaie

Purdue University

We have developed a colorimetric dermal patch for collecting and measuring sweat secretion in discrete volumes over a small area of skin to aid in hydration monitoring. The patch consists of filter paper, laser-machined to create a radial array of strips. When laminated by a medical film, the strips form microchannels; their tips are loaded with a water-responsive dye, thus allowing discrete colorimetric representations of collected sweat. The palm-sized patch is usable from 15 to 90 minutes at sweating rates of  90 µL/h/cm2 which lies in a physiologically relevant range (0-240 µL/h/cm2).



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