TW202123870A - Imaging fiber scanning probe and endoscopy - Google Patents

Abstract

An imaging fiber scanning probe includes a rotating component and at least one optical fiber. The rotating component includes a torque rope and the torque rope is rotatable with its axis as the rotating center, and the optical fiber is disposed on the rotating component eccentrically. The axis of the optical fiber and the axis of the torque rope are substantially parallel. When the rotating component rotates with the axis of the torque rope, the rotating component drives the free end of the optical fiber to scan along an arc path.

Description

Fiber optic scanning probe and endoscope

This idea is about a fiber optic scanning probe and an endoscope containing the fiber optic scanning probe.

Optical Coherence Tomography (Optical Coherence Tomography, OCT) is a rapidly developing intravascular imaging technology in recent years. It uses scanning beams to reconstruct the 2D or 3D structure of biological tissues. It has a non-free energy field source, high resolution, high-speed scanning and Imaging and other advantages. At present, the most common application is to configure a fiber optic probe at the front end of an endoscope or a cardiac catheter, and use the fiber optic probe to perform optical coherence tomography to examine the condition of the tissues in the body. Optical coherence tomography is the technology that can provide the clearest images of internal tissues in clinical practice. It can effectively evaluate the nature of the internal tissues and select more appropriate and accurate treatment strategies. It can ultimately improve the overall medical quality and postoperative results.

The existing optical coherent tomography imaging system needs to be equipped with a scanning mechanism in the sample arm in order to successfully obtain a two-dimensional tomographic image of the tissue. At present, the most common optical fiber scanning probe uses piezoelectric force or electromagnetic force to drive the optical fiber to shake to achieve the scanning function. However, the optical fiber scanning probe needs to be equipped with a power supply device to drive the movement of the optical fiber, which has the risk of electric shock or electromagnetic interference to human tissues, which leads to increased medical risks during endoscopy or cardiac catheterization. In addition, part of the way to drive the movement of the fiber is to drive the bottom of the fiber, so the light exit end of the fiber actually has an inclination angle change, which will need to be matched with an optical lens group for optical path correction and adjustment, so the structure is complicated, and it is not conducive to fiber scanning. Miniaturization of the probe.

This idea discloses an optical fiber scanning probe, which helps to solve the problems of increased medical risks caused by the power supply device configured in the probe and the difficulty of miniaturization caused by the need to match an optical lens set. The inventive embodiment also discloses an endoscope including the optical fiber scanning probe.

The optical fiber scanning probe disclosed in the present invention includes a rotating element and at least one optical fiber. The rotating element includes a torque rope, and the torque rope can rotate with its own axis as the center of rotation. The optical fiber is eccentrically arranged on the rotating element, and the axis of the optical fiber is substantially parallel to the axis of the torque rope. When the rotating element rotates with the axis of the torque rope as the rotation center, the rotating element drives a free end of the optical fiber to scan along an arc path.

An endoscope disclosed by the present invention includes a housing, a photosensitive element, and the aforementioned optical fiber scanning probe. The photosensitive element and the optical fiber scanning probe are arranged in the housing, and the axial extension direction of the optical fiber scanning probe is substantially parallel to the axial extension direction of the photosensitive element.

According to the optical fiber scanning probe disclosed in the present invention, when the rotating element rotates around the axis of the torque rope, since the torque rope and the optical fiber are eccentrically arranged, the rotating element will drive the free end of the optical fiber to scan along an arc path. When the optical fiber is scanned, the end face of the free end of the optical fiber maintains the same direction, which helps to ensure that no additional optical lens is required to correct the optical path when scanning the tissue of the specimen, thereby contributing to the miniaturization of the optical fiber scanning probe. In addition, the torque cord in the rotating element has the characteristic of not generating torsional strain during rotation, so the free end of the optical fiber can be prevented from moving in the radial direction of the rotating element, which helps to obtain stable quality scanned images.

The above description of the creative content and the description of the following implementation manners are used to demonstrate and explain the spirit and principle of the present invention, and provide a further explanation of the scope of the patent application of the present invention.

Hereinafter, the embodiments of the present invention are described in detail in the embodiments, which are sufficient for anyone familiar with the relevant art to understand the technical content of the present invention and implement them accordingly. The following examples further illustrate the viewpoints of the present invention in detail, but do not limit the scope of the present invention by any viewpoint.

Hereinafter, the "A element and the B element are eccentrically arranged" and "The A element is eccentrically arranged on the B element" means that the centers of the A element and the B element are deviated from each other. In some cases, it specifically means that the respective axes of the A element and the B element deviate from each other, that is, the A element and the B element are not concentric.

According to an embodiment of the present invention, the optical fiber scanning probe includes a rotating element and at least one optical fiber. Please refer to FIGS. 1 and 2. FIG. 1 is a three-dimensional schematic diagram of the optical fiber scanning probe according to the first embodiment of the invention, and FIG. 2 is an internal schematic diagram of the optical fiber scanning probe of FIG. In this embodiment, the optical fiber scanning probe 1 a includes a probe sleeve 10, a rotating element 20, an optical fiber 30 and a driving source 40, and the rotating element 20 and the front end of the optical fiber 30 are arranged in the probe sleeve 10.

The rotating element 20 includes a torque rope (or Torque Rope) 210, a base 220 and a sleeve 230. The torque rope 210 can rotate with its own axis A1 as the center of rotation. The front end portion of the torque cord 210, the sleeve 230 and the base 220 are arranged in the probe sleeve 10. In detail, the base 220 is, for example, but not limited to, a bump, the torque cord 210 is sleeved in the sleeve 230, and the base 220 is disposed on the outer surface of the sleeve 230. Therefore, when the torque cord 210 is opposite to the probe sleeve 10 When rotating, it will drive the base 220 to rotate together.

Further refer to FIGS. 3 and 4, wherein FIG. 3 is a schematic internal side view of the optical fiber scanning probe of FIG. 2. Fig. 4 is a schematic diagram of the internal front view of the optical fiber scanning probe of Fig. 1. The optical fiber 30 is eccentrically arranged on the rotating element 20. The so-called eccentric arrangement here means that the axis A2 of the optical fiber 30 is separated from the axis A1 of the torque cord 210 by a distance. In detail, the optical fiber 30 is disposed on the base 220 of the rotating element 20. The axis A2 of the optical fiber 30 and the axis A1 of the torque cord 210 deviate from each other and are substantially parallel to each other.

The driving source 40 is arranged outside the probe casing 10, and the torque cord 210 of the rotating element 20 is connected to the driving source 40. By outputting power through the driving source 40, the torque cord 210 can be rotated relative to the probe casing 10. The driving source 40 is, for example, but not limited to, a servo motor.

When the torque rope 210 of the rotating element 20 rotates around the axis A1, since the optical fiber 30 is eccentrically arranged, the rotating element 20 will drive the free end 310 of the optical fiber 30 to scan along an arc path R. The various parts of the torque rope 210 do not generate torsional strain when rotating, and the optical fiber 30 is disposed on the base 220 of the rotating element 20, so that the free end 310 of the optical fiber 30 can be prevented from moving in the radial direction of the torque rope 210 . The aforementioned torque cord 210 does not generate torsional strain, and includes the case where no torsional strain is generated at all, and the case where the torsional strain is generated but is so small that it cannot affect the movement path of the optical fiber 30.

When the rotating element 20 rotates, the torque cord 210 does not generate torsional strain when it rotates, and the normal direction of the end surface 311 of the free end 310 of the optical fiber 30 can be maintained substantially parallel to the axis A1 of the torque cord 210. Maintaining the end face 311 of the optical fiber 30 facing the same direction helps to eliminate the need for additional optical lenses to correct the optical path when scanning the tissue of the specimen, thereby contributing to the miniaturization of the optical fiber scanning probe 1a. In addition, the drive source 40 in this embodiment is arranged outside the probe sleeve 10, so the probe sleeve 10 does not need to provide space for accommodating the drive source 40, which helps to reduce the size of the probe sleeve 10 and promotes optical fiber Miniaturization of the scanning probe 1a.

In this embodiment, the rotating element 20 is eccentrically arranged in the probe sleeve 10, that is, the axis A1 of the torque cord 210 and the axis A0 of the probe sleeve 10 are offset from each other. Thereby, the probe sleeve 10 can provide a larger internal space for the movement of the optical fiber 30, which can increase the length of the arc path R (the effective stroke of scanning), and the optical fiber 30 can scan a larger area of the specimen tissue.

The rotating element of the first embodiment includes a torque cord, but the present invention is not limited to this. Please refer to FIG. 5, which is a three-dimensional diagram of the interior according to the second embodiment of the present invention. The second embodiment is similar to the first embodiment, but it should be noted that in this embodiment, the optical fiber scanning probe 1b includes a rotating element 20b. The rotating element 20 b is disposed in the probe casing 10, and the rotating element 20 b includes a torque cord 210 and a rotating body 225. In detail, in the rotating element 20 of the first embodiment, the base 220 and the sleeve 230 may be integrally formed, which is the rotating body 225 in this embodiment. That is, the torque rope 210 and the optical fiber 30 are both arranged on the rotating body 225, and the axis A2 of the optical fiber 30 and the rotation axis A1 of the rotating element 20b (ie, the axis A1 of the torque rope 210) are separated by a distance (off-center arrangement). The rotating body 225 is a disc body with any shape, which can be made of high-carbon steel, stainless steel, or polyamide with high rigidity, and can fix the distance between the axis A2 of the optical fiber 30 and the axis A1 of the torque rope 210. Therefore, no torsional strain can be generated during rotation.

Please refer to FIG. 6, which is a schematic diagram of the internal front view of the optical fiber scanning probe according to the third embodiment of the present invention. The third embodiment is similar to the first embodiment, but it should be noted that in this embodiment, the optical fiber scanning probe 1c includes a probe sleeve 10c, a rotating element 20c, and an optical fiber 30. The rotating element 20c includes a torque cord 210, a base 220, and a sleeve 230 disposed in the probe sleeve 10c. The base 220 is disposed on the outer surface of the sleeve 230 through an elastic member 240. The optical fiber scanning probe 1c further includes a base 220c, and the base 220c is disposed on the outer surface of the sleeve 230. The base 220c has a pivoting member 241, and the pivoting member 241 is rotatably disposed on the base 220c. The base 220 has a rack 221 which can be normally engaged with the pivoting member 241.

The pivoting member 241 interacts with the probe sleeve 10c to separate or engage the rack 221 and the pivoting member 241, thereby adjusting the distance between the axis of the optical fiber 30 and the axis of the torque cord 210. In detail, the combination of the pivoting member 241 and the rack 221 can adjust the distance between the axis of the optical fiber 30 and the axis of the torque rope 210 while the optical fiber 30 is scanning. Please refer to FIGS. 7 and 8 together, which are schematic diagrams of adjusting the distance between the optical fiber and the torque rope in FIG. 6. As shown in FIG. 7, the torque cord 210 rotates to drive the optical fiber 30 to move in the first direction D1 for scanning, and the rotation of the torque cord 210 causes the pivot 241 to touch the inner wall surface of the probe sleeve 10c. The pivot 241 receives the reaction force of the probe sleeve 10c and rotates away from the rack 221. At this time, since the pivoting member 241 does not interfere with the rack 221, the elastic force of the elastic member 240 allows the base 220 to move relative to the sleeve 230, thereby adjusting and changing the axis of the optical fiber 30 and the axis of the torque rope 210. distance.

As shown in FIG. 8, the torque rope 210 rotates to drive the optical fiber 30 to move in a second direction D2 opposite to the first direction D1 for scanning, and the reverse rotation of the torque rope 210 causes the pivot 241 and the probe sleeve 10c to move The inner wall surface is separated. At this time, the pivoting member 241 can be reset to engage with the rack 221 on the base 220. For example, after the pivoting member 241 is separated from the probe sleeve 10c, the torsion spring (not shown separately) connected to the pivoting member 241 can rely on its own elastic force to allow the pivoting member 241 to engage with the rack 221 again. After the pivoting member 241 is engaged with the rack 221 again, the distance between the axis of the optical fiber 30 and the axis of the torque rope 210 can be maintained. In this way, while ensuring that the end face 311 of the optical fiber 30 remains facing in the same direction, the optical fiber 30 can also have a relative displacement in the radial direction of the torque rope 210 to change the axial distance between the optical fiber 30 and the torque rope 210, thereby allowing the optical fiber The scanning probe 1c can perform three-dimensional optical coherent tomography.

Fig. 9 is a schematic diagram of the internal side view of the optical fiber scanning probe according to the fourth embodiment of the present invention. Fig. 10 is an internal front view schematic diagram of the optical fiber scanning probe of Fig. 9. The fourth embodiment is similar to the first embodiment, but it should be noted that in this embodiment, the optical fiber scanning probe 1d includes a probe sleeve 10, a rotating element 20, and a plurality of optical fibers 30. The optical fibers 30 are disposed on the base 220 of the rotating element 20, and the distance between the respective axis A2 of the optical fibers 30 and the axis A1 of the torque cord 210 of the rotating element 20 may be the same or may not be completely the same. In one embodiment, the distance between the respective axis A2 of the optical fibers 30 and the axis A1 of the torque cord 210 of the rotating element 20 is different in the radial direction. The optical fiber 30 closer to the torque cord 210 and the optical fiber 30 farther from the torque cord 210 can respectively scan different positions of the tissue of the specimen, and then can perform three-dimensional optical coherent tomography.

Fig. 11 is a schematic internal side view of the optical fiber scanning probe according to the fifth embodiment of the present invention. Fig. 12 is a schematic cross-sectional view of the optical fiber scanning probe of Fig. 11 along line 12-12. The fifth embodiment is similar to the first embodiment, but it should be noted that in this embodiment, the rotating element 20e of the optical fiber scanning probe 1e includes a torque cord 210, a base 220, a sleeve 230, and a fixing seat. 250. In detail, the torque cord 210 is sleeved in the sleeve 230, and the base 220 is disposed on the outer surface of the sleeve 230 so that the base 220 protrudes from the side of the torque cord 210. The torque cord 210 and the optical fiber 30 pass through the fixing base 250, and the base 220 and the fixing base 250 are separated from each other by a distance.

The fixing base 250 has a through groove 252, and the optical fiber 30 passes through the fixing base 250 through the through groove 252. In one embodiment, the aperture of the through-groove 222 is larger than the diameter of the optical fiber 30, which can provide a buffer space for the optical fiber 30 to move or twist in the fixing base 250, whereby the rear end portion of the optical fiber 30 is restricted by the fixing base 250 and fixed The seat 250 can be used to limit the travel of the optical fiber 30 during scanning, to avoid the phenomenon of bending of the optical fiber 30 due to inertial force when the optical fiber 30 stops scanning, to improve the stability of the optical fiber 30 during scanning, and to reduce the interference of the optical fiber 30 with the torque rope 210 during scanning. The chance of being entangled.

The optical fiber scanning probe disclosed in this idea can be widely used in various optical devices, one of which is used as a scanning probe built into an endoscope or a cardiac catheter. Fig. 13 is a schematic diagram of an endoscope according to an embodiment of the present invention. The endoscope 2 includes a housing 21, a photosensitive element 22, and the optical fiber scanning probe of any of the foregoing embodiments. The endoscope 2 shown in FIG. 13 includes the optical fiber scanning probe 1 a of the first embodiment and the photosensitive element 22, both of which are disposed in the housing 21. In detail, the axial extension direction of the optical fiber scanning probe 1 a and the axial extension direction of the photosensitive element 22 are substantially parallel. The housing 21 has a bellows structure so that the endoscope 2 can be bent to change the facing direction of the optical fiber scanning probe 1a.

To sum up, in the optical fiber scanning probe disclosed in this originality, when the rotating element rotates around the axis of the torque rope, since the torque rope and the optical fiber are eccentrically arranged, the rotating element will drive the free end of the optical fiber to proceed along an arc path. scanning. When the optical fiber is scanned, the end face of the free end of the optical fiber maintains the same direction, which helps to ensure that no additional optical lens is required to correct the optical path when scanning the tissue of the specimen, thereby contributing to the miniaturization of the optical fiber scanning probe. In addition, the torque cord in the rotating element has the characteristic of not generating torsional strain during rotation, so the free end of the optical fiber can be prevented from moving in the radial direction of the rotating element, which helps to obtain stable quality scanned images.

In addition, the driving source is arranged outside the probe casing, which helps reduce the size of the probe casing and enhance the miniaturization of the optical fiber scanning probe. In addition, when applied to an endoscope, the tip of the optical fiber scanning probe will enter the body of the living body, and because the driving source is not arranged in the probe casing, the risk of electric shock or electromagnetic interference of the living body can be avoided.

Although the present invention is disclosed in the foregoing embodiments, these embodiments are not intended to limit the present invention. Without departing from the spirit and scope of the original idea, all changes and modifications made belong to the scope of patent protection of the present invention. For the scope of protection defined by the present invention, please refer to the attached scope of patent application.

1a, 1b, 1c, 1d, 1e: fiber optic scanning probe 2: Endoscope 21: Shell 22: photosensitive element 10.10c: Probe sleeve 110: clip 20, 20b, 20c, 20e: rotating elements 210: Torque rope 220: Pedestal 220c: seat body 221: rack 225: Swivel 230: sleeve 240: Elastic 241: Pivot 250: fixed seat 252: piercing 30: Optical fiber 310: free end 311: end face 40: drive source A0, A1, A2: axis D1: First direction D2: second direction R: arc path

Fig. 1 is a schematic diagram of the optical fiber scanning probe according to the first embodiment of the present invention. Fig. 2 is an internal three-dimensional schematic diagram of the optical fiber scanning probe of Fig. 1. Fig. 3 is a schematic internal side view of the optical fiber scanning probe of Fig. 2. Fig. 4 is a schematic diagram of the internal front view of the optical fiber scanning probe of Fig. 1. Fig. 5 is a three-dimensional diagram of the interior according to the second embodiment of the present invention. Fig. 6 is a schematic diagram of the internal front view of the optical fiber scanning probe according to the third embodiment of the present invention. Fig. 7 and Fig. 8 are schematic diagrams showing that the distance between the optical fiber and the torque rope in Fig. 6 is adjusted. Fig. 9 is a schematic diagram of the internal side view of the optical fiber scanning probe according to the fourth embodiment of the present invention. Fig. 10 is an internal front view schematic diagram of the optical fiber scanning probe of Fig. 9. Fig. 11 is a schematic internal side view of the optical fiber scanning probe according to the fifth embodiment of the present invention. Fig. 12 is a schematic cross-sectional view of the optical fiber scanning probe of Fig. 11 along line 12-12. Fig. 13 is a schematic diagram of an endoscope according to an embodiment of the present invention.

10: Probe sleeve

20: Rotating element

210: Torque rope

220: Pedestal

230: sleeve

30: Optical fiber

310: free end

311: end face

A1, A2: axis

Claims (11)

An optical fiber scanning probe, comprising: a rotating element including a torque rope, the torque rope can be rotated with the axis of the torque rope as the rotation center; and at least one optical fiber is eccentrically arranged on the rotating element, and the axis of the at least one optical fiber The core is substantially parallel to the axis of the torque rope; wherein, when the rotating element rotates with the axis of the torque rope as the rotation center, the rotating element drives a free end of the at least one optical fiber to scan along an arc path. According to the optical fiber scanning probe described in claim 1, wherein when the rotating element rotates, the normal direction of one end surface of the free end of the at least one optical fiber is maintained substantially parallel to the axis of the torque rope. According to the optical fiber scanning probe described in claim 1, wherein the rotating element further includes a base and a sleeve, the torque cord is arranged in the sleeve, and the base is arranged on an outer side of the sleeve. The surface, and the at least one optical fiber is disposed on the base. The optical fiber scanning probe described in item 3 of the scope of patent application further includes a probe sleeve and a base, wherein the rotating element and the at least one optical fiber are both arranged in the probe sleeve, and the base is arranged through an elastic member In the sleeve, the seat body is provided on the outer surface of the sleeve, the seat body has a pivoting member, the pivoting member is rotatably provided on the seat body, the base has a rack, the pivot The rotating member interacts with the probe sleeve to separate or engage the rack and the pivoting member, thereby adjusting the distance between the axis of the at least one optical fiber and the axis of the torque rope. The optical fiber scanning probe described in item 3 of the scope of patent application, wherein the number of the at least one optical fiber is multiple, and the distance between the respective axis of each of the optical fibers and the axis of the torque rope of the rotating element is not the same . According to the optical fiber scanning probe described in item 3 of the scope of patent application, the rotating element further includes a fixing base, the torque cord and the at least one optical fiber pass through the fixing base, and the fixing base is spaced from the base. According to the optical fiber scanning probe described in item 6 of the scope of patent application, wherein the fixing base has a through groove, the at least one optical fiber passes through the fixing base through the through groove, and the aperture of the through groove is larger than that of the at least one optical fiber diameter. The optical fiber scanning probe described in item 1 of the scope of patent application further includes a probe sleeve, wherein the rotating element and the at least one optical fiber are both arranged in the probe sleeve. The optical fiber scanning probe described in item 8 of the scope of patent application further includes a driving source arranged outside the probe sleeve, and the torque cord of the rotating element is connected to the driving source. According to the optical fiber scanning probe described in claim 1, wherein the rotating element further includes a rotating body, the torque rope and the at least one optical fiber are arranged on the rotating body, and the axis of the at least one optical fiber and the torque rope The axis is separated by a distance. An endoscope, comprising: a housing; a photosensitive element; and the optical fiber scanning probe according to any one of items 1 to 10 in the scope of the patent application; wherein the photosensitive element and the optical fiber scanning probe are arranged in the Inside the housing, and the axial extension direction of the optical fiber scanning probe is substantially parallel to the axial extension direction of the photosensitive element.

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