Handheld optoacoustic probe

1 . A handheld optoacoustic probe having a distal end, the probe comprising: a plurality of optical fibers comprising a first light path, the plurality of optical fibers having a first end formed into at least one fiber bundle providing an input, and having a second end formed into first and second groups of optical fiber, each of the first and second groups of optical fiber consisting of approximately the same number of optical fibers; first and second light bar guides associated with the first and second groups of optical fiber, respectively, each of the first and second light bar guides retaining a distal end of the respective group of optical fibers on the same plane; a first and second optical window associated with, and spaced from, each of the first and second light bar guides, respectively; an RTV silicon rubber acoustic lens having an inner surface and an outer surface, the acoustic lens being doped with Ti0 2 ; an ultrasound transducer array having an active end, the array comprising a plurality of ultrasound transducer elements, the ultrasound transducer array having the inner surface of the acoustic lens at its active end; a reflective metal surrounding the outer surface of acoustic lens; and a handheld probe shell, the shell housing the first and second light bar guides and the ultrasound transducer array, and housing the acoustic lens between the first and second optical windows at the distal end of the probe. 2 . The handheld optoacoustic probe of claim 1 , wherein the plurality of optical fibers comprising at least one of the at least one fiber bundles are fused. 3 . The handheld optoacoustic probe of claim 1 , wherein the reflective metal is selected from the group of: aluminum, copper, gold, silver, brass or noble metal. 4 . The handheld optoacoustic probe of claim 1 , wherein the reflective metal is gold. 5 . The handheld optoacoustic probe of claim 4 , wherein the gold reflective metal surrounding the outer surface of the acoustic lens is overlaid with a protective layer to avoid flaking or cracking of the reflective metal. 6 . The handheld optoacoustic probe of claim 5 , wherein the protective layer is transparent and has a low acoustic absorption. 7 . The handheld optoacoustic probe of claim 4 , wherein the gold reflective metal surrounding the outer surface of the acoustic lens is enveloped in a protective layer to avoid flaking or cracking. 8 . The handheld optoacoustic probe of claim 4 , further comprising: an edge protector to protect at least one edge of the gold metal surrounding the outer surface of the acoustic lens to reduce flaking or cracking of the reflective metal at the at least one edge. 9 . The handheld optoacoustic probe claimed in claim 1 , further comprising: a first beam expander located between the distal end of the first group of optical fibers and the first optical window. 10 . The handheld optoacoustic probe claimed in claim 9 , wherein the first beam expander expands light beams emitted by the first group of optical fibers to fill the first optical window. 11 . The handheld optoacoustic probe claimed in claim 10 , wherein the space between the first optical window and the first light bar guide is defined on its sides by walls, and wherein the walls are made from a material that has high acoustic absorption. 12 . The handheld optoacoustic probe claimed in claim 10 , wherein the space between the first optical window and the first light bar guide is defined on its sides by walls, and wherein the walls are made from a material that has a high light scattering property. 13 . The handheld optoacoustic probe claimed in claim 12 , wherein the walls are made from a white or light colored material. 14 . The handheld optoacoustic probe claimed in claim 12 , wherein the walls are made from a material having low optical absorption and high optical reflection. 15 . The handheld optoacoustic probe claimed in claim 9 , further comprising: a second beam expander located between the distal end of the second group of optical fibers and the second optical window. 16 . The handheld optoacoustic probe claimed in claim 1 , wherein the distal end of the first and second groups of fiber are fused. 17 . The handheld optoacoustic probe claimed in claim 1 , wherein the transducer array is formed on a flex circuit, and a plurality of traces connect the transducer array to cable connectors, the optoacoustic probe further comprising an optically reflective and RF shielding material surrounding at least a substantial portion of the flex circuit and the cable connectors. 18 . The handheld optoacoustic probe claimed in claim 17 wherein the optically reflective material is copper, and the copper is tied to an electrical ground. 19 . A handheld optoacoustic probe having a distal end, the probe comprising: a plurality of optical fibers comprising a first light path, the plurality of optical fibers having a first end formed into at least one fiber bundle providing an input, and having a second end formed from the distal end of at least some of the plurality of optical fibers; a light bar guide retaining the distal end of the at least some of the plurality of optical fibers on the same plane; an optical window associated with, and spaced from the light bar guide; a silicon rubber acoustic lens having an inner surface and an outer surface, the acoustic lens being doped with Ti0 2 ; an ultrasound transducer array having an active end, the array comprising a plurality of ultrasound transducer elements, the ultrasound transducer array having the inner surface of the acoustic lens at its active end; a reflective metal surrounding the outer surface of acoustic lens; and a handheld probe shell, the shell housing the light bar guide and the ultrasound transducer array, and housing the acoustic lens adjacent to the optical window at the distal end of the probe. 20 . The handheld optoacoustic probe claimed in claim 19 wherein the transducer array is formed on a flex circuit, and a plurality of traces connect the transducer array to cable connectors, the optoacoustic probe further comprising copper foil surrounding at least a substantial portion of the flex circuit and the cable connectors. 21 . The handheld optoacoustic probe claimed in claim 20 , further comprising a beam expander located between the distal end of the at least some of the plurality of optical fibers and the optical window. 22 . The optoacoustic probe claimed in claim 21 , where the beam expander comprises a ground glass element. 23 . The handheld optoacoustic probe claimed in claim 21 , where the beam expander comprises at least one optical lens. 24 . The handheld optoacoustic probe of claim 19 , wherein the silicon rubber acoustic lens comprises a room temperature vulcanization silicon rubber acoustic lens. 25 . A handheld optoacoustic probe having a distal end, the probe comprising: a plurality of optical fibers comprising a first light path, the plurality of optical fibers having a first end formed into a fiber bundle providing an input, and having a second end formed from the distal end of at least some of the plurality of optical fibers; a light bar guide retaining the distal end of the at least some of the plurality of optical fibers on the same plane, the distal end of the at least some of the plurality of optical fibers being lapped and polished to provide for a more uniform