Catching Cancer's Spread by Watching Hemoglobin.New Blood-Vessel-Imaging Technique Exploits Natural Properties of Oxygen-Carrying Molecule News from the Conference on Lasers and Electro-Optics/Quantum Electronics Laser Science Conference (CLEO/QELS) BALTIMORE -- In an advance that can potentially assist cancer diagnosis, a new optical technique provides high-resolution, three-dimensional images of blood vessels Blood vessels Tubular channels for blood transport, of which there are three principal types: arteries, capillaries, and veins. Only the larger arteries and veins in the body bear distinct names. by taking advantage of the natural multiple-photon-absorbing properties of hemoglobin, the red-blood-cell molecule that carries oxygen throughout the bloodstream. The research will be presented in Baltimore at CLEO/QELS, May 6 - May 11. The new laser-based method, developed at Duke University, should provide 3-D images of blood vessels in relatively deep tissue (up to 1 mm, much better than conventional microscopes) with a resolution at the micron scale (at the level of blood cells blood cells, n.pl the formed elements of the blood, including red cells (erythrocytes), white cells (leukocytes), and platelets (thrombocytes). blood cells See erythrocyte and leukocyte. Platelets are classed separately. , which is better than MRI 1. (application) MRI - Magnetic Resonance Imaging. 2. MRI - Measurement Requirements and Interface. resolution) and does not require any contrast agents or fluorescent markers (unlike most other high-resolution vessel-imaging techniques). Clinically, the imaging technique can potentially be used to detect the spread of cancer, since angiogenesis--the growth of new blood vessels from existing ones--often signals the proliferation of tumors. This may make the technique convenient and powerful for helping to diagnose diseases such as melanoma, the deadliest form of skin cancer. The technique can image blood vessels up to a millimeter below the surface. Looking at blood vessels just below skin growths would be very useful for distinguishing between malignant and benign skin tumors, and would remove the critical need for skin biopsies, which is especially helpful if there are multiple suspicious areas that need to be investigated. Since hemoglobin is highly concentrated in red blood cells Red blood cells Cells that carry hemoglobin (the molecule that transports oxygen) and help remove wastes from tissues throughout the body. Mentioned in: Bone Marrow Transplantation red blood cells , imaging the locations where this molecule occurs can map out the distribution of red blood cells and reveal the vessels themselves. If the imaging is fast enough, researchers can capture snapshots of blood flow in individual vessels. Moving beyond mere imaging, the technique can detect the difference between oxygen-carrying hemoglobin (oxyhemoglobin oxyhemoglobin /oxy·he·mo·glo·bin/ (-he?mo-glo´bin) hemoglobin that contains bound O2, a compound formed from hemoglobin on exposure to alveolar gas in the lungs. ox·y·he·mo·glo·bin n. ) and oxygen-lacking hemoglobin (deoxyhemoglobin). This is important for monitoring tumors, because the oxygenation oxygenation /ox·y·gen·a·tion/ (ok?si-je-na´shun) 1. the act or process of adding oxygen. 2. the result of having oxygen added. state around cancerous tissue and the size and density of blood vessels around the tumor can provide a lot of information about the progression of a tumor and its response to anti-cancer drugs. In the technique, two lasers at different wavelengths (colors) send ultra-short pulses (lasting only a femtosecond, or a quadrillionth quad·ril·lionth n. 1. The ordinal number matching the number quadrillion in a series. 2. One of a quadrillion equal parts. quad·ril of a second) on a blood vessel blood vessel n. An elastic tubular channel, such as an artery, a vein, a sinus, or a capillary, through which the blood circulates. blood vessel(s), n the network of muscular tubes that carry blood. . The hemoglobin absorbs light from both of these lasers at the same time, in a process known as "two-photon absorption Two photon absorption (TPA) is the simultaneous absorption of two photons of identical or different frequencies in order to excite a molecule from its ground state to an excited state. ," and then gives off signals that can be detected to build up an image. One "pump" laser boosts (excites) hemoglobin molecules to a higher energy state. The other "probe" laser monitors the hemoglobin after the excitation. Sometimes the pump laser is off and there is no two-photon absorption. By subtracting the signal from the "off" state from the "on" state (when two-photon absorption occurs), the researchers remove unwanted scattered light from the data and can get high-quality signals from hemoglobin molecules. To map out the hemoglobin distribution, the researchers scan laser beams across the sample, a process that then reveals the outlines and contours of blood vessels. By taking images at different depths and stacking these images layer by layer, the researchers can reconstruct 3-D images of blood vessels. A major advantage of the technique is that it is "label-free," meaning it does not require the addition of fluorescing molecules but rather relies on the inherent light-absorbing properties of hemoglobin. While the technique has been demonstrated in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. (by excising tissue samples and imaging the vessels on a glass dish), imaging in the living body is possible either for vessels up to a millimeter below the surface or through the use of minimally invasive probes, being developed in various labs, that can be inserted in the body. Meeting Paper: CTuF1, "Two-Photon Absorption Imaging of Hemoglobin," to be presented on Tuesday, May 8, 8 a.m. - 8:30 a.m. About CLEO/QELS With a distinguished history as one of the industry's leading events on laser science, the Conference on Lasers and Electro-Optics and the Quantum Electronics and Laser Science Conference (CLEO/QELS) is where laser technology was first introduced. CLEO/QELS combines the strength of peer-reviewed scientific programming with an applications-focused exhibition to showcase the present and future of this technology. Sponsored by the American Physical Society's (APS) Laser Science Division, the Institute of Electronic Engineers/Laser and Electro-Optics Society (IEEE/LEOS) and the Optical Society of America The Optical Society of America (OSA) is a scientific society dedicated to advancing the study of light—optics and photonics—in theory and application, by means of worldwide research, scientific publishing, conferences and exhibitions, partnership with industry, and the (OSA 1. OSA - Open Scripting Architecture. 2. OSA - Open System Architecture. ), CLEO/QELS provides an educational forum, complete with a dynamic Plenary, short courses, tutorials, workshops and more, on topics as diverse as its attendee base whose broad spectrum of interests range from biomedicine biomedicine /bio·med·i·cine/ (bi?o-med´i-sin) clinical medicine based on the principles of the natural sciences (biology, biochemistry, etc.).biomed´ical bi·o·med·i·cine n. 1. to defense to optical communications and beyond. For more information, visit the conference's Web site at www.cleoconference.org. |
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