Remote Microscopy

A modular microscope attachment for cell phones could improve the quality of telemedi

Mobile microscopy: A cell phone incorporating a microscope (top) developed at the University of California, Berkeley, can capture and transmit pictures such as this 23x-magnification image of the freshwater crustacean Cyclops (bottom). Researchers hope that the device will allow patients in remote areas to send images of red blood cells and other diagnostic information to medical specialists. Credit: David Breslauer

Researchers at the University of California, Berkeley, have developed a modular, high-magnification microscope attachment for cell phones. The device will enable health workers in remote, rural areas to take high-resolution images of a patient's blood cells using a cell-phone camera, and then transmit the photos to experts at medical centers.

The researchers hope that the innovation will help patients with blood disorders who live far from medical specialists get more accurately diagnosed and treated. "I wanted to make optical design relevant to today," says Daniel Fletcher, a professor of bioengineering at Berkeley. Fletcher's students found it relatively easy to integrate a simple arrangement of lenses with the cell-phone camera and transmit magnified images to a laptop using a Bluetooth attachment to the phone. The work prompted Fletcher to file a patent through the university and try to make a practical microscope. The researchers say that the cameras in late-model phones are capable of capturing all the details that a doctor would need to identify malaria parasites and cancer cells.

"The challenge was to make a low-cost, durable device with a long battery life," says David Breslauer, a graduate student in Fletcher's lab. "As engineers, we initially wanted to make a whiz-bang gadget to take pictures of both skin and blood. But people in the field told us, 'Once it gets too complicated, no one is going to want to use it. Make something simple that just does the task.'"

The total cost of the first prototype, built from off-the-shelf components, was $75. The current version provides its own sample illumination from cheap, low-power LEDs. The device comes in two versions: with a magnification of about 5 times, for taking images of moles and rashes, and with a magnification of about 60 times, for capturing the details of blood cells and parasites. The higher-magnification model--the larger of the two--is roughly the size and shape of a roll of quarters. Both scopes attach to the phone with a modified belt clip.

"Microscopy is still considered the gold standard" for malaria diagnosis, says Katherine Herz, a medical doctor and a fellow in health policy at Stanford University. "If microscopy could be done with portable equipment ... [it] might be adopted far more widely and prove extremely useful."

Fletcher plans to test the microscope cell phone in Uganda this summer. Initially, his lab will make prototypes, but eventually, it plans to hand off the design to a manufacturer. The Blum Center for Developing Economies at Berkeley, which provided initial funding, will help test the device in Kampala. The scheme is to train local personnel and provide them with the necessary equipment to take pictures of patients' blood on special slides, and then phone in the images to specialists who can identify and count malaria parasites.

The researchers also hope to collaborate with a telemedicine program at the University of California, Davis, that serves rural California. Leukemia patients in remote areas could use the microscope cell phone to transmit images for white blood cell counts.

Wireless ways for high-speed file swaps

New wireless personal networks promise ultra-fast data exchange over short distances

Illustration: NICTA



Gigabit wireless: The Gi-Fi integrated wireless transceiver chip developed at the National ICT Research Centre, Australia. —

Move over Wi-Fi, Gi-Fi is here! They are not putting it quite that way, but recent developments hold out the hope that very large video and other files, can be swapped within seconds, by wireless devices operating over a few metres, in largely unused and unlicensed higher frequency bands. First tangible evidence

The first tangible evidence that Gi-Fi (the ‘Gi’ is for gigabit data rates) might be more than just a neat new acronym, came from Australia last week. Researchers at the Victoria Research Laboratory of National Information and Communication Technology Australia Ltd (NICTA), announced that they had developed the world’s first transmitter-receiver integrated on a single chip, operating at 60 GHz and fabricated using the complementary metal oxide semiconductor (CMOS) process. (http://nicta.com.au/news/current )

The chip, just 5 mm per side, has a tiny 1 mm antenna and uses the 60 GHz ‘millimetre-wave’ spectrum — an unlicensed band of 7 GHz between 57 GHZ and 64GHz. NICTA’s CEO David Skellern says the technology will allow the wireless transfer of audio and video files at rates up to 5 gigabits per second… almost ten times faster than what is currently possible. And the fabrication which uses a 130 nanometre CMOS process, may lead eventually to chips priced as low as $10.

There are a number of firsts here: One, developing high frequency radio components in a standard CMOS process rather than in silicon seems to be a major achievement. If the process can be scaled up, it holds out the possibility of low cost, low power chips which are also very high broadband.

To get a feel for the scale of achievement, consider the best we can achieve with today’s incumbent wireless technologies, Wi-Fi ,Wi-MAX or Bluetooth.

WiFi (WLAN, 802.11) operates in the 2.4 GHz band, has transfer rates of between 11 MBPS and 55 MBPS. WiMAX ( 802.16WiMAX) operates in the 2-11 GHz band and achieves data rates of up to 70 MBPS. Bluetooth (802.15Bluetooth) whose operational ranges are comparable to what can be achieved by the Australian Gi-Fi chip, is typically capable of 20 KBPS to 200 KBPS and in its fastest version, peaks at 55 MBPS. Second, this is one of the first practical applications in the band of what is being known as mw-WPAN, that is, millimeter wave Wireless Personal Area Network… or 802.15.3 to give it the correct designation. An IEEE Task Group no. 3C was formed in 2005 to develop this new WPAN alternative which promises to harness a relatively uncrowded, unlicensed band while offering the hope of data rates of at least 1 GBPS and typically 2 GBPS or better. (see entries for Task Group 3C at http://www.ieee802.org/15/ for technical details and future roadmap).

The potential of mw-WPAN for ultra fast data exchange has prompted companies like Intel, LG, Matsushita (Panasonic), NEC, Samsung, SiBEAM, Sony and Toshiba to form WirelessHD, an industry-led effort to define a specification for the next generation wireless digital network interface for consumer electronics products. Specifically, WirelessHD has a stated goal of enabling wireless connectivity for streaming high-definition content between source devices and high-definition displays. ( see http://www.wirelesshd.org ).

In fact the NICTA effort, says its Gigabit Wireless Project leader Prof Stan Skafidas, has been supported by key industry players like IBM, Synopsys, Cadence, Anritsu, Aglent, Microsoft and SUSS MicroTec, so clearly there is industry interest in exploiting any technology that might boost data rates and drop product costs, ten fold… an enticing possibility.

Usable prototypes

In an indoor environment, the NICTA Gi-Fi device ( usable prototypes may be less than a year away) is expected to work over a distance of up to 10 metres… which puts it somewhere between Bluetooth and WiFi, range-wise. What will it do for you and me? Consumers could typically download a high definition movie from a kiosk in a matter of seconds to a music player or smart phone and having got home, could play it on a home theatre system or store it on a home server for future viewing, again within a few seconds.

Maybe, it’s not that premature to say, “WiFi, it’s time to move over, the competition is here!”

Silent, microchip-sized 'fan' has no moving parts, yet produces enough wind to cool a laptop

Dan Schlitz of Thorrn Micro Technologies is one of the developers of a new, solid-state micro-fan. Credit: Dan Schlitz and Vishal Singhal, Thorrn Micro Technologies

Engineers harnessing the same physical property that drives silent household air purifiers have created a miniaturized device that is now ready for testing as a silent, ultra-thin, low-power and low maintenance cooling system for laptop computers and other electronic devices.

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The compact, solid-state fan, developed with support from NSF's Small Business Innovation Research program, is the most powerful and energy efficient fan of its size. It produces three times the flow rate of a typical small mechanical fan and is one-fourth the size.

Dan Schlitz and Vishal Singhal of Thorrn Micro Technologies, Inc., of Marietta, Ga. will present their RSD5 solid-state fan at the 24th Annual Semiconductor Thermal Measurement, Modeling and Management Symposium (Semi-Therm) in San Jose, Calif., on March 17, 2008. The device is the culmination of six years of research that began while the researchers were NSF-supported graduate students at Purdue University.

"The RSD5 is one of the most significant advancements in electronics cooling since heat pipes. It could change the cooling paradigm for mobile electronics," said Singhal.

The RSD5 incorporates a series of live wires that generate a micro-scale plasma (an ion-rich gas that has free electrons that conduct electricity). The wires lie within un-charged conducting plates that are contoured into half-cylindrical shape to partially envelop the wires.

Within the intense electric field that results, ions push neutral air molecules from the wire to the plate, generating a wind. The phenomenon is called corona wind.

"The technology is a breakthrough in the design and development of semiconductors as it brings an elegant and cost effective solution to the heating problems that have plagued the industry," said Juan Figueroa, the NSF SBIR program officer who oversaw the research.

With the breakthrough of the contoured surface, the researchers were able to control the micro-scale discharge to produce maximum airflow without risk of sparks or electrical arcing. As a result, the new device yields a breeze as swift as 2.4 meters per second, as compared to airflows of 0.7 to 1.7 meters per second from larger, mechanical fans.

The contoured platform is a part of the device heat sink, a trick that enabled Schlitz and Singhal to both eliminate some of the device's bulk and increase the effectiveness of the airflow.

"The technology has the power to cool a 25-watt chip with a device smaller than 1 cubic-cm and can someday be integrated into silicon to make self-cooling chips," said Schlitz.

This device is also more dust-tolerant than predecessors. While dust attraction is ideal for living-room-scale fans that that provide both air flow and filtration, debris can be a devastating obstacle when the goal is to cool an electrical component.