Photoacoustic probe

The invention claimed is: 1. A photoacoustic tomography (PAT) bracket comprising an ultrasound transducer; a holder, which holds and translates the ultrasound transducer; force sensors, which are coupled to the holder and provide information about a force applied by the ultrasound transducer on the skin of a subject of interest; and two rotating fiber arms coupled to the holder, wherein both rotating fiber arms are juxtaposed with respect to the holder at a pivoting point, and wherein each of the two rotating fiber arms to holds a fiber optic bundle and rotates the fiber optic bundle and laser light projections thereof such that the laser projections intersect at a selective focal depth of the subject of interest below the bracket. 2. The PAT bracket according to claim 1 , wherein the holder holds and translates the ultrasound transducer to tune the pivoting point at which the two rotating fiber arms are juxtaposed with respect to the holder and at which each rotating fiber arm holds and rotates its fiber optic bundle and laser light projections thereof. 3. The PAT bracket according to claim 1 , wherein the rotating fiber arms rotate the fiber optic bundles at an angle to converge the laser light projections at various depths of the subject of interest to optimize an optical contrast in the subject of interest. 4. The PAT bracket according to claim 1 , wherein the holder translates the ultrasound transducer up and down with respect to the subject of interest. 5. The PAT bracket according to claim 1 , wherein each of the two rotating fiber arms can articulate about the holder by angular motion, linear motion, or angular and linear motions. 6. The PAT bracket according to claim 1 , further comprising a photoacoustic filter that is configured to redirect laser light reflected from the skin of the subject of interest back toward the skin while allowing ultrasound waves to pass through. 7. The PAT bracket according to claim 1 , wherein the bracket further comprises an ultrasound gel incorporating photo reflectors to reflect light back onto the skin of the subject of interest. 8. The PAT bracket according to claim 1 , wherein the fiber optic bundles transmit light at a fixed wavelength. 9. A method to generate optimum photoacoustic signals to a subject of interest, comprising: a. providing a photoacoustic tomography (PAT) bracket comprising an ultrasound transducer; a holder, which holds and translates the ultrasound transducer; and two rotating fiber arms coupled to the holder, wherein both rotating fiber arms are juxtaposed with respect to the holder at a pivoting point, and wherein each of the two rotating fiber arms holds a fiber optic bundle and rotates the fiber optic bundle and laser light projections thereof; b. applying a fixed wavelength of light through the fiber optic bundles while rotating the fiber arms and translating the holder to fine tune the pivoting point; c. acquiring photoacoustic images at different focal lengths in the subject of interest to obtain images with increased photon density at various depths; and d. applying digital image processing algorithms to concatenate all images obtained in (c) to construct a photoacoustic image with improved photon density throughout the photoacoustic image. 10. The method of claim 9 , wherein the fixed wavelength is selected from the group consisting of 1100 nm, 1210 nm 1250 nm and 1400 nm. 11. The method of claim 9 , which further comprises providing a light reflecting material over the ultrasound transducer to remove any reflection artifact that is potentially obscuring an image of the subject of interest, wherein the artifact is induced due to a photoacoustic effect at a face of the ultrasound transducer. 12. The method of claim 11 , wherein the light reflecting material is a photoacoustic filter. 13. The method of claim 9 , wherein the subject of interest is a lipid tissue, a cancerous tissue, a body fluid, a peripheral nerve tissue, or a polyethylene-50 (PE-50) tube. 14. The method of claim 9 , wherein the focal lengths include 2 mm, 3 mm, 5 mm 6.5 mm or 10 mm for maximum photon density within the subject of interest.