• Photograph (left) and schematic diagram (right) of the field-portable lensfree tomographic microscope. This device will enable the 3D imaging of microscopic particles, a never-before-available capability (Complimentary Photograph adapted from Isikman, et al.).

    Army funded research may enhance battlefield medicine

    Photograph (left) and schematic diagram (right) of the field-portable lensfree tomographic microscope. This device will enable the 3D imaging of microscopic particles, a never-before-available capability (Complimentary Photograph adapted from Isikman...

  • Holographic microscopy enables real-time, wide field-of-view and depth-of-field imaging. The researchers demonstrated wide-field imaging of a whole blood smear sample using holographic imaging. The subcellular features of a white blood cell could be resolved (inset), even with this relatively low-resolution, early version of the microscope (Complimentary Photograph adapted from Bishara, et al.).

    Army funded research may enhance battlefield medicine

    Holographic microscopy enables real-time, wide field-of-view and depth-of-field imaging. The researchers demonstrated wide-field imaging of a whole blood smear sample using holographic imaging. The subcellular features of a white blood cell could be...

  • Schematic diagram of the lensfree holographic imaging method. The Army funded researchers have developed a method for lensfree on-chip microscopic imaging in which the entire active area of the sensor-array becomes the imaging field of view (Complimentary Photograph from Greenbaum and Ozcan).

    Army funded research may enhance battlefield medicine

    Schematic diagram of the lensfree holographic imaging method. The Army funded researchers have developed a method for lensfree on-chip microscopic imaging in which the entire active area of the sensor-array becomes the imaging field of view...

ADELPHI, Md. (May 7, 2013) -- Extramural basic research at the University of California, Los Angeles, funded by the U.S. Army Research Laboratory's Army Research Office, the Office of Naval Research and the Defense Advanced Research Projects Agency, has led to the discovery of a fundamental new way to image microorganisms using visible or ultraviolet light without the requirement of any lenses, lasers or bulky optical elements.

This new method, called holographic microscopy, may provide a cost-effective, handheld, lightweight and rapid diagnostic system to enhance battlefield medicine capabilities.

Holographic microscopy can overcome many limitations of conventional optical microscopy.
Current optical microscopes are expensive, cumbersome to transport and require frequent technical maintenance.

For example, accidently jarring a microscope will typically require time-intensive realignment by a specialist.

In contrast, holographic microscopy simply requires a sensor, software, computing power and a display, and is enabling imaging devices that are inexpensive, compact and virtually maintenance-free.

This technology should allow imaging solutions at significantly lower cost (tens of dollars per device vs. thousands for each optical microscope), improved ruggedness (no moving parts or optics), reduced weight (grams rather than kilograms) and smaller size relative to optical microscopes.

Dr. Wallace Buchholz, the ARL program manager for this research project, noted that "holographic microscopy can capture an image in less than a second and is capable of resolving bacteria and other microscopic objects over areas and depths-of-field thousands of times greater than possible with optical microscopes."

These capabilities are required attributes for three-dimensional imaging of microscopic particles, a powerful imaging capability that has never-before been available.

Given its compact, inexpensive and rugged characteristics, this new method may lead to new capabilities relevant to the Army.

Holographic microscopy can revolutionize point-of-care diagnostics.

Tests that are currently restricted to hospitals or clinics could be readily conducted on the battlefield and in the remotest areas of the world.

For instance, blood, urine, fecal and tissue samples could be analyzed for the presence of parasites and pathogens, and whole blood could be analyzed for cell differentials to diagnose a variety of maladies such as discriminating between allergic reactions and infections.

Other potential applications of the technology might include detection of micro-fractures in materiel such as helicopter rotor blades, or detection of microbes on surfaces.

The research team published results in 2013 that demonstrate an adaptation of holography for use on cell phones, thereby providing a lightweight and highly-portable method for imaging fluids such as water, blood and urine to potentially detect and identify infectious diseases.

According to Buchholz, this research has great promise for field use by the warfighter; however, there are several key challenges remaining before practical field use of this technology can be realized.

Research efforts are underway to increase the resolution beyond 0.5 micrometer. Whereas this resolution is adequate for many needs, higher resolution will significantly increase versatility.

Furthermore, current and pending detection methods for pathogen identification must be adapted to the new platform, software that addresses specific Army/DoD needs must be developed, and the technology must transition from the research and development stage to production and commercialization.

To foster nearer-term applications, an Army-Academia-Industry partnership (the U.S. Army Edgewood Chemical Biological Center, UCLA and Luminex Inc.), funded by the Defense Threat Reduction Agency, is determining proof-of-concept of this technology for detecting pathogenic bacteria in a body fluid (urine).

In addition, a project to be funded by the Tank Automotive Research, Development and Engineering Center and conducted at UCLA will develop a field-deployable platform to monitor the safety of drinking water in-theater by the sensitive and specific detection of waterborne protozoan parasites and fecal bacteria.

Though conceptually similar, these two projects will use different technical approaches to achieve similar goals.

Scientists in ARL's Sensors and Electron Devices Directorate are interested in using the technology as a "miniature flow-through cytometer" for research in a size-limited anaerobic chamber, and in integrating this technology into future sensors and detectors.

Furthermore, proposals to a Chemical Biological Defense Small Business Innovation Research topic are currently under review for the potential development of a global disease surveillance network that would be used to monitor and track natural disease outbreaks.

The system could similarly monitor the release and spread of intentionally or accidentally released biological or chemical agents.

It is unusual for basic research to quickly mature into potential Army-relevant applications.
However, with continued investment it is anticipated that in three to five years, a handheld, inexpensive, cell-phone-based prototype may be available to the Army for rapidly detecting microbes in drinking water and bodily fluids--providing critical diagnostics capabilities previously unavailable on the battlefield or in remote locations.

The Army Research Laboratory, Tank Automotive Research, Development and Engineering Center and Edgewood Chemical Biological Center are part of the U.S. Army Research, Development and Engineering Command at Aberdeen Proving Ground, Md. The command has the mission to empower, unburden and protect America's Soldiers through technology and engineering solutions.

Page last updated Tue May 7th, 2013 at 14:30