Acoustic-assisted iterative wave form optimization for deep tissue focusing

What is claimed is: 1. A method for irradiating a target within a scattering medium, comprising: (a) controllably defining a target within a scattering medium with an acoustic field transmitted from an acoustic wave source; (b) transmitting input electromagnetic (EM) radiation from pixels of a wavefront modifying device to the scattering medium, including the target, wherein: the input EM radiation irradiating the target has an input wavefront and a frequency, and at least some of the input EM radiation that passes through the acoustic field at the target is shifted in frequency by the acoustic field and outputs from the scattering medium as output EM radiation comprising frequency shifted EM radiation; (c) detecting an amount of the frequency shifted EM radiation; and (d) modulating the pixels, wherein: the modulating of the pixels iteratively modifies a phase, or amplitude, or the phase and the amplitude of the input wavefront, using feedback comprising the amount of the frequency shifted EM radiation that is detected and so as to increase the amount of the frequency shifted EM radiation that is detected. 2. The method of claim 1 , further comprising modulating the pixels until a maximum amount of the frequency shifted EM radiation is detected. 3. The method of claim 1 , wherein the acoustic field is focused to produce a first focus of the acoustic field at the target, and the modulating of the pixels forms a modified wavefront converging to form a second focus of the input EM radiation at the target. 4. The method of claim 3 , further comprising using the input EM radiation comprising the modified wavefront to perform Raman spectroscopy of the target. 5. The method of claim 3 , wherein: the scattering medium comprises at least one biological medium comprising biological cells, or biological tissue, or biological cells and biological tissue, and the input EM radiation does not damage the biological medium that is not at the target, and further comprising using the input EM radiation, comprising the modified wavefront, to cut the biological medium at, and defined by, the target, wherein the target is at a depth of no less than 1 mm from a surface of the biological medium. 6. The method of claim 2 , wherein: the scattering medium comprises at least one biological medium comprising biological cells, or biological tissue, or biological cells and biological tissue, the acoustic field comprises ultrasound that is focused to an ultrasound focal spot at the target, the ultrasound focal spot has a diameter of 100 micrometers or less at a depth of no less than 5 mm within the biological medium, and the input EM radiation having the modified wavefront is focused to at most a same size as the ultrasound focal spot. 7. The method of claim 3 , further comprising: performing photodynamic therapy on the scattering medium comprising at least one biological medium comprising biological cells, or biological tissue, or biological cells and biological tissue, wherein: the input EM radiation having the modified wavefront excites a photosensitive agent at the target to activate the target and trigger the photodynamic therapy of the biological medium at the target, and the target is at a depth of no less than 1 mm from a surface of the biological medium. 8. The method of claim 3 , wherein the modified wavefront is a phase conjugate of the input wavefront. 9. The method of claim 1 , wherein the acoustic field comprises ultrasound. 10. The method of claim 1 , wherein the irradiating of the scattering medium includes selecting the frequency of the input EM radiation that enables multi-photon excitation of the target. 11. The method of claim 1 , further comprising performing steps (a)-(d) within 1.5 seconds. 12. The method of claim 11 , wherein: the scattering medium comprises at least one biological medium comprising biological tissue, or biological cells, or biological tissue and biological cells. 13. The method of claim 1 , wherein the pixels are modulated by (1) raster scanning, (2) frequency modulation, or (3) according to a matrix, a combination of (2) and (3), or a combination of (1) and (2). 14. An apparatus implementing the method of claim 1 , comprising: a laser for irradiating the scattering medium with the input Electromagnetic (EM) radiation; a detection system for detecting an amount of the frequency shifted EM radiation; and the wavefront modifying device chosen from a deformable mirror device and a spatial light modulator. 15. An apparatus for irradiating a target within a scattering medium, comprising: a detector detecting modulated electromagnetic (EM) radiation from a target in a scattering medium after input EM radiation from an EM radiation source is incident on the target, the input EM radiation comprising a wavefront; a spatial light modulator iteratively modifying a phase, or amplitude, or phase and amplitude of the wavefront incident on the target; and one or more processors for controlling the modifying using feedback comprising an amount of the modulated EM radiation that is detected and so as to increase the amount of the modulated EM radiation that is detected. 16. The apparatus of claim 15 , wherein the one or more processors select the wavefront comprising a modified wavefront that maximizes the amount of the modulated EM radiation as compared to the amount of the modulated EM radiation obtained using the wavefront prior to the modifying. 17. The apparatus of claim 15 , further comprising an acoustic wave source and control system focusing an acoustic field at the target, wherein the acoustic field modulates the input EM radiation into the modulated EM radiation and the wavefront converges to form a focus of the input EM radiation at the target. 18. The apparatus of claim 17 , wherein the acoustic wave source comprises an ultrasound transducer, the acoustic field comprises ultrasound, the EM radiation source comprises a laser, and the detector comprises a camera and interferometer. 19. The apparatus of claim 17 , further comprising a scattering medium holder for the scattering medium that comprises at least one biological medium comprising biological cells, or biological tissue, or biological cells and biological tissue, wherein the scattering medium holder is: adjustably positioned relative to the EM radiation source; adjustably positioned relative to the acoustic wave source; and coupled to the detector. 20. The apparatus of claim 19 , wherein: the scattering medium holder is adjustably positioned relative to the acoustic wave source and the EM radiation source, to cut the biological medium at the target, and the target is at a depth of no less than 1 mm from a surface of the tissue. 21. The apparatus of claim 19 , wherein: the acoustic wave source comprises an ultrasound transducer that generates the acoustic field comprising ultrasound that is focused to an ultrasound focal spot at the target; the ultrasound focal spot has a diameter of 100 micrometers or less at a depth of no less than 5 mm within the biological medium; and the input EM radiation is focused to at most a same size as the ultrasound focal spot. 22. The apparatus of claim 19 , wherein: the input EM radiation having the wavefront comprising a modified wavefront modified by the spatial light modulator excites a photosensitive agent at the target, thereby activating the target. 23. The apparatus of claim 15 , wherein the apparatus is o