Systems for optical imaging of biological tissues

1 . Apparatus for optical coherence tomography comprising: a reference arm; a sample arm, a light splitter connected to direct a first portion of light from a light source into the reference arm by way of a first non-polarization-maintaining optical fiber path and a second portion of light from the light source into the sample arm by way of a second non-polarization-maintaining optical fiber path, a light combiner connected to receive light from the reference arm by way of a third non-polarization-maintaining optical fiber path and to receive light from the sample arm by way of a fourth non-polarization-maintaining optical fiber path, the light combiner configured to allow interference of the light received from the sample and reference arms, the light combiner having first and second outputs respectively connected to first and second polarizing beam splitters by first and second polarization maintaining optical fiber paths, the first and second polarizing beam splitters each having first and second outputs, the first outputs of the first and second polarizing beam splitters connected by optical fibers to deliver light having a first state of polarization to a first light detector, the second outputs of the first and second polarizing beam splitters connected by optical fibers to deliver light having a second state of polarization distinct from the first state of polarization to a second light detector. 2 . Apparatus according to claim 1 wherein the light combiner comprises first and second input ports configured to receive single mode optical fibers and first and second output ports configured to receive polarization maintaining optical fibers. 3 . Apparatus according to claim 2 wherein the light combiner comprises first and second dual fiber collimators arranged to provide collimated beams that intersect at a non-polarizing beamsplitter, wherein first sides of the first and second dual fiber collimators are respectively connected to the first and second input ports and second sides of the first and second dual fiber collimators are respectively connected to the first and second output ports. 4 . Apparatus according to claim 3 wherein the non-polarizing beamsplitter is a 50/50 beamsplitter. 5 . Apparatus according to claim 2 wherein the first and second output ports are each configured to non-rotationally engage the polarization maintaining optical fiber. 6 . Apparatus according to claim 1 wherein the light combiner comprises a 50/50 light combiner. 7 . Apparatus according to claim 1 comprising a first light circulator connected to the first and third non-polarization-maintaining optical fiber paths, the first light circulator configured to direct light from the first non-polarization-maintaining optical fiber paths into a non-polarization-maintaining optical fiber path of the reference arm and to direct light from the non-polarization-maintaining optical fiber path of the reference arm into the third non-polarization-maintaining optical fiber path. 8 . Apparatus according to claim 7 comprising a second light circulator connected to the second and fourth non-polarization-maintaining optical fiber paths, the second light circulator configured to direct light from the second non-polarization-maintaining optical fiber paths into a non-polarization-maintaining optical fiber path of the sample arm and to direct light from the non-polarization-maintaining optical fiber path of the sample arm into the fourth non-polarization-maintaining optical fiber path. 9 . Apparatus according to claim 1 wherein the light splitter is configured so that the second portion of light directed into the sample arm is significantly greater in power than the first portion of light directed into the reference arm. 10 . Apparatus according to claim 1 comprising a processor connected to process signals from the first and second light detectors to determine a retardation of the sample. 11 . Apparatus according to claim 10 wherein determining the tangent of the retardation comprises dividing amplitudes of the signals detected at the first and second light detectors. 12 . Apparatus according to claim 10 wherein the processor is further configured to determine polarization independent structural information and the processing comprises computing a sum of squares of amplitudes of the signals detected at the first and second light detectors. 13 . Apparatus according to claim 10 wherein the processing comprises determining a root mean square of amplitudes of the signals detected at the first and second light detectors. 14 . Apparatus according to claim 1 wherein the sample arm comprises a fiber optic rotary joint, probe assembly comprising an optical fiber having a probe tip at a distal end thereof and a drive system coupled to rotate the optical fiber. 15 . Apparatus according to claim 14 wherein the fiber optic rotary joint comprises an input port, a first lens arranged to collimate light entering the input port, a second lens arranged to couple light collimated by the first lens into the optical fiber of the probe assembly and a dichroic mirror between the first and second lenses, the dichroic mirror constructed to pass light having wavelengths emitted by the light source and to reflect light of other wavelengths. 16 . Apparatus according to claim 15 comprising a second light source operable to emit fluorescence excitation light, the second light source arranged to direct the fluorescence excitation light onto the dichroic mirror. 17 . Apparatus according to claim 14 wherein the probe tip comprises a focusing element arranged to direct light onto a light deflector and a section of clad fiber between the focusing element and the optical fiber of the probe. 18 . Apparatus according to claim 17 wherein the section of clad fiber comprises a section of step-index multimode fiber. 19 . Apparatus according to claim 18 wherein the optical fiber of the probe comprises a dual clad fiber. 20 . Apparatus according to claim 19 wherein the focusing element comprises a graded index optical fiber having a core diameter D GRIN and a length of the section of clad fiber satisfies: L MMF × 2  λ OCT π   w OCT  n OCT < D GRIN , where w OCT , and n OCT are the half of the mode field diameter of the core of the dual clad fiber and refractive index of a core of the clad fiber at the wavelength λ OCT of the light source. 21 . Apparatus according to claim 20 wherein a diameter D MMF of the core of the multimode fi