Optical fiber scanner for performing multimodal optical imaging

US 7,616,986 B2
Filed: 06/28/2004
Issued: 11/10/2009
Est. Priority Date: 05/07/2001
Status: Active Grant

First Claim

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1. A method for using an optical fiber scanner for carrying out rapid scanning during imaging of a subject to carry out either optical coherence tomography, confocal imaging, or multiphoton excitation imaging of the subject, comprising the steps of:

(a) advancing the optical fiber scanner to a position adjacent to the subject, the optical fiber scanner including an actuator cantilevered from a fixed mounting base, and an optical fiber, a portion of the optical fiber being cantilevered from the actuator to form a cantilevered optical fiber, the actuator including a plurality of pairs of drivers disposed in a predefined pattern to drive the cantilevered optical fiber in regard to a plurality of axes of the actuator;

(b) actuating the cantilevered optical fiber such that it rapidly moves generally in a two-dimensional area scanning path comprising a desired scanning pattern and such that it is driven to vibrate at one of a resonant frequency, and a near-resonant frequency of the cantilevered optical fiber, a combination of the actuator that is cantilevered and the cantilevered optical fiber resulting in a large displacement of the cantilevered optical fiber as it moves in the two-dimensional scanning path at a rapid rate, the step of actuating comprising the step of applying a signal that actuates the plurality of pairs of drivers to drive the cantilevered optical fiber in the desired scanning pattern;

(c) conveying light through the cantilevered optical fiber and emitting the light from a distal portion of the cantilevered optical fiber, to illuminate the subject as the light emitted from the distal portion of the cantilevered optical fiber scans the subject in the desired scanning pattern at a desired depth within the subject;

(d) moving a focal point of the optical fiber scanner generally along an axis that is substantially orthogonal to the plane of the desired scanning pattern, to scan at a different desired depth within the subject; and

(e) repeating step (b) at the different desired depth.

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Abstract

An optical fiber scanner is used for multiphoton excitation imaging, optical coherence tomography, or for confocal imaging in which transverse scans are carried out at a plurality of successively different depths within tissue. The optical fiber scanner is implemented as a scanning endoscope using a cantilevered optical fiber that is driven into resonance or near resonance by an actuator. The actuator is energized with drive signals that cause the optical fiber to scan in a desired pattern at successively different depths as the depth of the focal point is changed. Various techniques can be employed for depth focus tracking at a rate that is much slower than the transverse scanning carried out by the vibrating optical fiber. The optical fiber scanner can be used for confocal imaging, multiphoton fluorescence imaging, nonlinear harmonic generation imaging, or in an OCT system that includes a phase or frequency modulator and delay line.

196 Citations

30 Claims

1. A method for using an optical fiber scanner for carrying out rapid scanning during imaging of a subject to carry out either optical coherence tomography, confocal imaging, or multiphoton excitation imaging of the subject, comprising the steps of:
- (a) advancing the optical fiber scanner to a position adjacent to the subject, the optical fiber scanner including an actuator cantilevered from a fixed mounting base, and an optical fiber, a portion of the optical fiber being cantilevered from the actuator to form a cantilevered optical fiber, the actuator including a plurality of pairs of drivers disposed in a predefined pattern to drive the cantilevered optical fiber in regard to a plurality of axes of the actuator;
  
  (b) actuating the cantilevered optical fiber such that it rapidly moves generally in a two-dimensional area scanning path comprising a desired scanning pattern and such that it is driven to vibrate at one of a resonant frequency, and a near-resonant frequency of the cantilevered optical fiber, a combination of the actuator that is cantilevered and the cantilevered optical fiber resulting in a large displacement of the cantilevered optical fiber as it moves in the two-dimensional scanning path at a rapid rate, the step of actuating comprising the step of applying a signal that actuates the plurality of pairs of drivers to drive the cantilevered optical fiber in the desired scanning pattern;
  
  (c) conveying light through the cantilevered optical fiber and emitting the light from a distal portion of the cantilevered optical fiber, to illuminate the subject as the light emitted from the distal portion of the cantilevered optical fiber scans the subject in the desired scanning pattern at a desired depth within the subject;
  
  (d) moving a focal point of the optical fiber scanner generally along an axis that is substantially orthogonal to the plane of the desired scanning pattern, to scan at a different desired depth within the subject; and
  
  (e) repeating step (b) at the different desired depth.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13)
- - 2. The method of claim 1, wherein the step of actuating causes the cantilevered optical fiber to move back and forth generally laterally relative to a longitudinal axis of the optical fiber scanner.
  - 3. The method of claim 1, wherein the step of actuating further comprises the step of driving the cantilevered optical fiber to move in two generally orthogonal directions, both of which are generally orthogonal to a longitudinal axis of the optical fiber scanner.
  - 4. The method of claim 1, wherein the focal point of the optical fiber scanner is moved to a different depth at a substantially slower rate than the cantilevered optical fiber is actuated to move it generally in the plane, for scanning the subject in the desired pattern.
  - 5. The method of claim 1, wherein the focal point of the optical fiber scanner is moved longitudinally in a stepwise manner, repeating steps (b) and (c) for each different depth desired, so that the cantilevered optical fiber scans, generally transversely, at a plurality of different depths.
  - 6. The method of claim 1, further comprising the step of employing one of an electro-optic phase modulator and an acousto-optic modulator in one of a sample arm and a reference arm, when carrying out optical coherence tomography.
  - 7. The method of claim 1, wherein while carrying out multiphoton excitation imaging with a light source that comprises a laser, further comprising the step of pre-chirping the laser pulses to pre-compensate for a pulse broadening of the light from the laser before the light reaches the focal point within the subject.
  - 8. The method of claim 1, further comprising the step of focusing light passing through the distal portion of the cantilevered optical fiber using a lens optically linked thereto.
  - 9. The method of claim 8, wherein the lens optically linked to the distal portion of the cantilevered optical fiber comprises at least one of a refractive type lens, a graded index (GRIN) type lens, and a miniature compound achromatic lens having a plurality of lens elements.
  - 10. The method of claim 1, further comprising the step of focusing and collecting light passing through the distal portion of the cantilevered optical fiber using a lens that is longitudinally movable relative to the distal portion of the cantilevered optical fiber, to adjust the focal point of the optical fiber scanner.
  - 11. The method of claim 1, wherein the step of moving the focal point of the optical fiber scanner includes at least one of the steps of:
    - (a) actuating an elastomeric polymer that changes length in response to an electric potential, shifting the focal point longitudinally;
      
      (b) changing a focus of a variable focus fluid lens that shifts the focal point longitudinally, in response to an electric potential;
      
      (c) driving a motor to rotate a shaft that shifts the focal point longitudinally;
      
      (d) applying one of a hydraulic and pneumatic pressure to overcome a spring tension, causing the focal point to move;
      
      (e) controlling a pressure applied to vary a separation between tissue at the subject and the distal portion of the cantilevered optical fiber, shifting the focal point longitudinally; and
      
      (f) changing a focus of a deformable membrane mirror that shifts the focal point to vary the depth in the subject, in response to an electric potential.
  - 12. The method of claim 1, further comprising the step of substantially reducing back reflections by carrying out at least one of the steps of creating an angled bevel on a distal end of the cantilevered optical fiber through which light is conveyed in the optical fiber scanner, and applying an anti-reflection coating to one or more possibly reflective surfaces.
  - 13. The method of claim 1, wherein the step of advancing the optical fiber scanner comprises the step of delivering the optical fiber scanner to a site with or without an endoscope.

14. A compact optical fiber scanner adapted for use in carrying out a rapid transverse scan while imaging a subject during either optical coherence tomography, confocal imaging, or multiphoton excitation imaging of the subject, comprising:
- (a) a light source that produces light;
  
  (b) an optical fiber having a proximal end and a distal end, the light source being optically coupled to the proximal end of said optical fiber, said distal end of the optical fiber being adapted to be positioned adjacent to a subject;
  
  (c) a scanning actuator disposed adjacent to the distal end of a longitudinal axis of the optical fiber, a portion of the optical fiber being cantilevered from the scanning actuator, said scanning actuator driving the cantilevered portion of the optical fiber that is disposed at the distal end of the optical fiber to vibrate in two generally orthogonal directions, both of which are generally orthogonal to a longitudinal axis of the optical fiber, causing light produced by the light source that is conveyed through the optical fiber and is emitted from a distal end of the cantilevered portion, to scan a region of interest in a desired scanning pattern, wherein said scanning actuator drives the cantilevered portion of the optical fiber to vibrate at one of a resonant frequency, and a near-resonant frequency, the scanning actuator comprising a tubular piezoelectric driver that is configured to be axially symmetric about the portion of the optical fiber that is cantilevered from the scanning actuator, and concentric about the longitudinal axis of the optical fiber, to thereby achieve a compact configuration;
  
  (d) a focusing lens disposed proximate to and distal of the distal end of the cantilevered portion of the optical fiber, said focusing lens being longitudinally spaced apart from the scanning actuator;
  
  (e) a focal point displacer that moves a focal point of the focusing lens to change a disposition of a focal point of the optical fiber scanner, to scan at a different depth in a subject after the scanning actuator and cantilevered portion of the optical fiber have completed scanning at a previous depth; and
  
  (f) a light detector that responds to light that was reflected from a subject and collected by the optical fiber scanner, producing a signal.
- View Dependent Claims (15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27)
- - 15. The optical fiber scanner of claim 14, wherein the scanning actuator drives the cantilevered portion of the optical fiber to vibrate back and forth generally laterally relative to a longitudinal axis of the optical fiber scanner.
  - 16. The optical fiber scanner of claim 14, wherein the scanning actuator drives the cantilevered portion of the optical fiber to vibrate in a two-dimensional, area scanning path comprising the desired scanning pattern.
  - 17. The optical fiber scanner of claim 14, further comprising a reference arm coupled to a splitter in an optical path of the light produced by the source, so that light from the source is split between a measuring arm that includes the distal end of the optical fiber and the reference arm, the reference arm including one of an electro-optic phase modulator and an acousto-optic frequency modulator for use in carrying out optical coherence tomography.
  - 18. The optical fiber scanner of claim 14, wherein the focal point displacer changes the focal point of the focusing lens at a substantially slower rate than the distal end of the cantilevered portion of the optical fiber is caused to vibrate in the desired pattern by the scanning actuator.
  - 19. The optical fiber scanner of claim 14, wherein the focal point displacer changes the disposition of the focal point of the focusing lens in one of a stepwise and a continuous manner, to focus at each different depth desired.
  - 20. The optical fiber scanner of claim 14, wherein the focal point displacer changes a separation between the distal end of the cantilevered portion of the optical fiber and the focusing lens to change the disposition of the focal point in order to scan at each different depth desired.
  - 21. The optical fiber scanner of claim 14, wherein the focal point displacer comprises at least one of:
    - (a) an elastomeric polymer coupling a lens to the optical fiber scanner, the elastomeric polymer changing length in response to an electric potential applied to the elastomeric polymer, causing the disposition of the focal point to shift longitudinally;
      
      (b) a variable focus lens that shifts the disposition of the focal point of the optical fiber scanner in response to an electric potential applied to the variable focus lens, causing the disposition of the focal point to shift longitudinally;
      
      (c) a motor that is drivingly coupled to a shaft for shifting the disposition of the focal point of the optical fiber scanner as the shaft is rotated by the motor, causing the disposition of the focal point to shift longitudinally;
      
      (d) a source of one of a hydraulic and pneumatic pressure applied to a volume to overcome a spring bias, causing the disposition of the focal point to shift longitudinally;
      
      (e) a vacuum source coupled to an enclosed space disposed between tissue at a subject being scanned and a distal end of the cantilevered portion of the optical fiber, variation in a level of vacuum applied to the enclosed space causing the disposition of the focal point to shift longitudinally; and
      
      (f) a beamsplitter that directs a portion of the light from the light source transversely relative to a longitudinal axis of the optical fiber scanner, and a deformable membrane mirror that shifts the disposition of the focal point of the optical fiber scanner in response to an electric potential applied to the deformable membrane mirror, causing the disposition of the focal point to change in the direction in which the portion of the light is penetrating into the subject.
  - 22. The optical fiber scanner of claim 14, wherein the distal end of the cantilevered portion of the optical fiber includes at least one of an angled bevel and an anti-reflection coating for the wavelengths of interest.
  - 23. The optical fiber scanner of claim 14, wherein the scanning actuator comprises a piezoelectric actuator.
  - 24. The optical fiber scanner of claim 14, further comprising one of an analog and a digital demodulator for demodulating the signal produced by the light detector, for use in optical coherence tomography.
  - 25. The optical fiber scanner of claim 14, further comprising a tubular housing disposed about a distal end of the cantilevered portion of the optical fiber.
  - 26. The optical fiber scanner of claim 14, further comprising a lens optically linked to the distal end of the cantilevered portion of the optical fiber.
  - 27. The optical fiber scanner of claim 26, wherein the lens optically linked to the distal end of the cantilevered portion of the optical fiber comprises one of a refractive type lens, a graded index (GRIN) type lens, and a miniature compound achromatic lens.

28. An optical fiber scanner adapted for use in carrying out a rapid transverse scan while imaging a subject during either optical coherence tomography, confocal imaging, or multiphoton excitation imaging of the subject, comprising:
- (a) a light source that produces light;
  
  (b) an optical fiber having a proximal end and a distal end, the light source being optically coupled to the proximal end of said optical fiber, said distal end of the optical fiber being adapted to be positioned adjacent to a subject;
  
  (c) a piezoelectric actuator having a proximal end and a distal end, the proximal end of the piezoelectric actuator being supported by a fixed mounting base and being cantilevered therefrom, the distal end of the optical fiber including a cantilevered portion that extends distally from the distal end of the piezoelectric actuator, said piezoelectric actuator including a plurality of pairs of drivers disposed in a predefined pattern in regard to a plurality of axes of the actuator, thereby configuring the actuator to drive the cantilevered portion of the optical fiber that is disposed at the distal end of the optical fiber to vibrate in two generally orthogonal directions, both of which are generally orthogonal to a longitudinal axis of the optical fiber, causing light produced by the light source that is conveyed through the optical fiber and is emitted from a distal end of the cantilevered portion, to scan a region of interest in a desired scanning pattern;
  
  (d) a focusing lens disposed proximate to the distal end of the cantilevered portion of the optical fiber;
  
  (e) a focal point displacer that causes a relative movement between the distal end of that cantilevered portion of the optical fiber and the focusing lens, to change a disposition of a focal point of the optical fiber scanner, enabling the optical fiber scanner to scan at a different depth in a subject after the scanning actuator and cantilevered portion of the optical fiber have completed scanning at a previous depth; and
  
  (f) a light detector that responds to light reflected from a subject and collected by the optical fiber, producing a signal useful for imaging the subject.

29. A method for using an optical fiber scanner for carrying out rapid scanning during imaging of a subject to carry out one of optical coherence tomography, confocal imaging, and multiphoton excitation imaging of the subject, comprising the steps of:
- (a) advancing the optical fiber scanner to a position adjacent to the subject, the optical fiber scanner including an optical fiber having a proximal end and a distal end, said optical fiber scanner further having an actuator disposed symmetrically about a longitudinal axis of the optical fiber and disposed adjacent to the distal end such that the distal end of the optical fiber is cantilevered from the actuator to form a cantilevered optical fiber that is configured to be actuated to vibrate so that the cantilevered optical fiber moves in a desired scanning pattern to scan the subject, the cantilevered optical fiber emitting light from a distal end of the cantilevered optical fiber that is focused using a lens that is disposed at or distally beyond the distal end of the optical fiber and longitudinally spaced apart from the actuator, to illuminate the subject as the light emitted from the distal portion of the cantilevered optical fiber scans the subject in the desired scanning pattern at a depth determined by a focal point of the optical fiber scanner;
  
  (b) actuating the cantilevered optical fiber symmetrically about the longitudinal axis using a tubular actuator that is concentrically disposed about the cantilevered optical fiber, thereby achieving a compact configuration that causes the cantilevered optical fiber to vibrate such that the cantilevered optical fiber rapidly moves generally in a two-dimensional area scanning path comprising the desired scanning pattern, at a frequency greater than 1.0 kilohertz;
  
  (c) moving the focal point of the optical fiber scanner generally along an axis that is substantially orthogonal to a plane of the desired scanning pattern, to scan at a different depth within the subject, the focal point moving at a substantially slower rate than that at which the cantilevered optical fiber scans in the desired scanning pattern; and
  
  (d) repeating step (b) to scan at the different depth.

30. A method for using an optical fiber scanner for carrying out rapid scanning, to carry out any of optical coherence tomography imaging, confocal imaging, or multiphoton excitation imaging of a subject, comprising the steps of:
- (a) advancing the optical fiber scanner to a position adjacent to the subject, the optical fiber scanner including an actuator cantilevered from a fixed mounting base, and an optical fiber, a portion of the optical fiber being cantilevered from the actuator to form a cantilevered optical fiber, the actuator including a plurality of pairs of drivers disposed in a predefined pattern to drive the cantilevered optical fiber in regard to a plurality of axes of the actuator, thereby enabling the actuator to drive the cantilevered optical fiber to vibrate so that the cantilevered optical fiber moves in a desired scanning pattern to scan the subject at a depth determined by a focal point of the optical fiber scanner, the cantilevered optical fiber conveying light that is emitted from a distal portion of the cantilevered optical fiber, to illuminate the subject as the light emitted from the distal portion of the cantilevered optical fiber scans the subject in the desired scanning pattern, wherein the desired scanning pattern is either a spiral scan or a helical scan;
  
  (b) actuating the cantilevered optical fiber such that it rapidly moves generally in a two-dimensional area scanning path comprising the desired scanning pattern and such that it is driven to vibrate at either a resonant frequency, or a near-resonant frequency of the cantilevered optical fiber, a combination of the actuator that is cantilevered and the cantilevered optical fiber resulting in a large displacement of the cantilevered optical fiber as it moves in the two-dimensional scanning path at a rapid rate;
  
  (c) moving the focal point of the optical fiber scanner generally along an axis that is substantially orthogonal to the plane of the desired scanning pattern, to scan at a different depth within the subject; and
  
  (d) repeating step (b) at the different depth.

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Current Assignee
University of Washington, Washington University In St Louis
Original Assignee
University of Washington
Inventors
Liu, Xiumei, Seibel, Eric, Li, Xingde
Primary Examiner(s)
Le; Long V
Assistant Examiner(s)
Lauritzen; Amanda L.

Application Number

US10/880,008
Publication Number

US 20040254474A1
Time in Patent Office

1,961 Days
Field of Search

600476-478, 600/129, 600/130, 600/163, 600/173, 600/160, 356/479, 356/497, 356/477, 356/450, 250/234, 250/227.26
US Class Current

600/476
CPC Class Codes

A61B 3/102   for optical coherence tomog...

A61B 5/0062   Arrangements for scanning

A61B 5/0066   Optical coherence imaging

A61B 5/0068   Confocal scanning

A61B 5/6852   Catheters

B31B 2105/001   made from laminated webs, e...

G02B 21/0028   specially adapted for speci...

G02B 21/0036   Scanning details, e.g. scan...

G02B 21/006   focusing arrangements; sele...

G02B 21/0076   arrangements using fluoresc...

G02B 23/2423   of the distal end

G02B 26/10   Scanning systems

G02B 26/103   having movable or deformabl...

G02B 6/262   Optical details of coupling...

G02B 6/32   having lens focusing means ...

G02B 6/3502   involving direct waveguide ...

G02B 7/08   adapted to co-operate with ...

Optical fiber scanner for performing multimodal optical imaging

First Claim

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Abstract

196 Citations

30 Claims

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Optical fiber scanner for performing multimodal optical imaging

First Claim

3 Assignments

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0 Petitions

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Accused Products

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Abstract

196 Citations

30 Claims

Specification

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Solutions

Use Cases

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