MIT-designed cooler preserves tuberculosis drugs, records doses
A simple cooler could help patients battle antibiotic-resistant tuberculosis
Tuberculosis, now largely controlled in the industrialized world, remains a stubbornly persistent killer in most of Africa, as well as parts of Asia and South America. The spread of multidrug-resistant strains of TB has slowed progress against the devastating disease, which is estimated to strike more than 10 million people annually. Now a modified soft-drink cooler, developed by researchers at MIT’s D-Lab, could make a dent in the disease’s impact.
There are two big issues that physicians confront in trying to
tackle drug-resistant TB strains in developing countries. First,
the drugs used to treat the disease, which require several doses
per day over a course of 18 months, must be kept at a controlled
low temperature — in places where the availability of
electricity is sparse and unreliable. And second, the drugs must
be taken regularly, requiring continuous monitoring by health
care workers.
Both issues could potentially be
addressed by the cooler developed by researchers in the Little
Devices Lab, a team of researchers within D-Lab who work to
develop low-cost solutions to pressing medical needs.
D-Lab is a program of classes, workshops and labs at
MIT, launched a decade ago by senior lecturer Amy Smith. The
program now includes 13 classes on topics in health, mobility
and energy, and is devoted to developing appropriate solutions
to problems facing low-income people and communities around the
world.
José Gómez-Márquez, the
D-Lab instructor who runs the
Little Devices group, says the team’s breadbox-sized cooler was adapted from
one designed to keep soft drinks cool. Dubbed
“CoolComply,” it can run on either plug-in power or
solar cells, and contains circuitry to monitor the temperature
inside and transmit an alarm if it rises too high. (Higher
temperatures cause a gas to be released inside the medicine
packets, which can make patients violently ill.)
In
addition, to track compliance, each cooler records the exact
date and time when the box is opened, which allows a single dose
packet to be dispensed. A built-in cellphone transmitter sends
information on temperature and cooler activity to a central
health facility where the data can be stored and monitored.
The
CoolComply team won a $100,000 award last fall as a Vodaphone
Americas Foundation Wireless Innovation Project, as well as a
$50,000 grant from the Harvard Catalyst. The awards will see the
project through initial development and testing.
The
idea originated with Kristian Olson and Aya Caldwell, physicians
at Massachusetts General Hospital in Boston, who told
Gómez-Márquez about the pressing need to keep TB
medicines cool and to verify patient compliance with the dosage
regime.
At present, since many of the patients
entering treatment lack access to refrigerators, they are
instead provided with coolers requiring daily deliveries of ice;
their compliance with the dosage regime is checked regularly by
visiting health workers. Those constraints severely limit the
number of patients who can be treated,
Gómez-Márquez says. The daily ice deliveries cost
$600 a year — about double the cost of the CoolComply
system — and “ice doesn’t send you a
message” to show that medicine has been taken, he says.
Since
last September, three prototype devices have undergone field
testing in Addis Ababa, Ethiopia; this summer the D-Lab team
hopes to deploy at least 10 more there for further testing.
Ultimately, the team hopes the devices can be produced locally
and distributed by a small for-profit company set up for this
purpose, fostering both better health and the creation of local
jobs.
The wireless reporting system in the CoolComply
device “solves the problem of having to visit the patient
every day,” Gómez-Márquez says. But getting
to that point wasn’t easy: The first prototypes built last
summer by the team — which also includes D-Lab instructors
Anna Young and Amit Ghandi — worked perfectly in the
United States, but as soon as they arrived in Addis Ababa for
field testing, “none of it worked,”
Gómez-Márquez says, because of unreliable signals
from the local cellphone system. “We had to go back to the
drawing board,” he says. “We were in despair.”
One problem, Ghandi says, was the design of the
cooler’s antenna. “You couldn’t tell what was
wrong by looking at it,” he says, “but it
wouldn’t work in certain parts of Ethiopia.”
Finally, after switching to a different type of antenna and
devising some tricks to make up for unexpected gaps in the
system (such as the lack of a built-in timestamp on Ethiopian
text messages), they were able to get a reliable device up and
running.
That’s par for the course for such
projects, Gómez-Márquez says. “You want,
during the first trip, for a lot of things to go wrong,”
he says. “That’s why you go over there.” The
key thing for this project was enlisting local users to try out
a new system under real-world conditions. “We found
amazing engineers” at the Addis Ababa Institute of
Technology, he says, who “did an enormous amount of
work” to help get the system working.
These
local engineers, in fact, were delighted to have the chance to
work on such a project, which they could see was something that
could be built and maintained within the country. Young says one
of them told her, looking at an expensive MRI machine in the
local hospital, “Nobody I know will ever use this.”
By contrast, he said of the new cooler, “This is something
I can actually see being used by people I know.”
MIT News Office
http://web.mit.edu/newsoffice/
http://web.mit.edu/newsoffice/2012/fighting-tuberculosis-0530.html
