Source: https://patents.google.com/patent/ES2542013T3/en
Timestamp: 2020-05-26 11:11:02
Document Index: 722183477

Matched Legal Cases: ['art 200', 'art 2', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 150', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 200', 'art 125', 'art 125', 'art 125', 'art 125', 'art 125', 'art 125']

ES2542013T3 - Pneumatically operated ophthalmic examination endoscope - Google Patents
Pneumatically operated ophthalmic examination endoscope Download PDF
ES2542013T3
ES2542013T3 ES12712806.4T ES12712806T ES2542013T3 ES 2542013 T3 ES2542013 T3 ES 2542013T3 ES 12712806 T ES12712806 T ES 12712806T ES 2542013 T3 ES2542013 T3 ES 2542013T3
ES12712806.4T
2011-03-22 Priority to US201161466364P priority Critical
2011-03-22 Priority to US201161466364P priority
2012-03-21 Application filed by Alcon Research Ltd filed Critical Alcon Research Ltd
2012-03-21 Priority to PCT/US2012/029909 priority patent/WO2012129278A2/en
2015-07-29 Publication of ES2542013T3 publication Critical patent/ES2542013T3/en
Ophthalmic endoscope (100), comprising: a handpiece (150) attachable to a cannula assembly (110) having a longitudinal axis, the cannula assembly comprising an inner tube (130) concentric with an outer tube (140) ; the handpiece also comprising an engine (125, 200), the engine (125) comprising a mechanical piston (210) that can be moved in a longitudinal direction by a pressurized fluid, the mechanical piston (210) providing movement to a shaft transmission (212); and a transmission system (127) for coupling the movement of the shaft to the cannula assembly, adapted to provide a counter-rotating movement to the inner tube and the outer tube around the longitudinal axis of the cannula, the transmission system (127) comprising systems of uncoupled gears for independent drive control of the inner tube (130) and the outer tube (140).
65 E12712806
Pneumatic operated ophthalmic examination endosonde.
The embodiments described herein refer to the field of ophthalmic microsurgical endosondas. More particularly, the embodiments described herein refer to the field of Optical Coherence Tomography (OCT) and the field of ophthalmic microsurgical techniques.
The field of ophthalmic microsurgical interventions is evolving rapidly. Typically, these interventions involve the use of endosondas that are capable of reaching the tissue that is being operated or diagnosed. Such interventions make use of endoscopic surgical instruments that have a control device attached to a remote control console. The current state of the art provides endosondas that are quite complex in operation, frequently requiring moving parts that are operated using complex mechanical systems. In many cases, an electric motor is included in the design of the endoscope. Most prior art devices have a cost that makes it difficult to discard them after an intervention or only a few surgical interventions. In addition, prior art devices generally use endosondas that have cross sections of several millimeters. These endosondas are of little practical use for ophthalmic microsurgical techniques. In ophthalmic surgery, dimensions of one (1) millimeter or less are preferred to cover typically involved areas without affecting unrelated tissue.
Scanning systems that allow time-dependent light direction for diagnostic or therapeutic purposes have been used in endoscopic surgical instruments. These instruments typically use endosondas that provide imaging, treatment or both over a large area of tissue without requiring the movement of the endoscope in relation to its surroundings. However, efforts to develop scanning endosondas compatible with ophthalmic surgery have slowed down due to the difficulty of providing a lightweight, compact drive system at a low cost. This is particularly true for forward-facing ophthalmic scanning endosonates, which may require stems that rotate in the opposite direction with fixed or controlled relative speeds.
Therefore, there is a need for a simple and efficient system to provide ophthalmic microsurgical endosondas for single-use designs. There is also a need for disposable endosondas that have lightweight components that can be injection molded from low cost materials, such as plastic.
US 2006/0004397 teaches an endorsement that has coupled gear systems.
A drive system for an endoscope according to the embodiments described herein may include a source of fluid energy; an endoscope that has a handpiece and a cannula assembly that has a longitudinal axis. The cannula assembly includes a concentric inner tube with an outer tube; wherein the handpiece may further include a motor driven by the fluid energy source, the engine providing movement to a transmission rod; and a transmission system to couple the movement of the stem to the cannula assembly; wherein the transmission system provides a movement in the opposite direction to the inner tube and the outer tube around the longitudinal axis of the cannula.
In addition, according to the embodiments described herein, a drive system for an endoscope may include an electric power source; an endoscope that has a handpiece and a cannula assembly that has a longitudinal axis. The cannula assembly includes a concentric inner tube with an outer tube; wherein the handpiece may further include a motor driven by the source of electrical power, the motor providing movement to a transmission rod; and a transmission system to couple the movement of the stem to the cannula assembly; wherein the transmission system provides a rotating movement in the opposite direction to the inner tube and the outer tube around the longitudinal axis of the cannula.
According to some embodiments described, a fluid console for use in endoscopic ophthalmic microsurgery may include a pneumatic module to obtain a pneumatic force from an external source and provide an adjustable pneumatic force; a scanning module coupled to the pneumatic module; and an endosonde coupled to the scanning module.
Figure 1 shows a microsurgical endorsement that includes an optical scanning element, a handpiece, a coupling cable and an engine part according to some embodiments.
Figure 2 shows a partial cross section of a part of a handpiece that includes an engine part, a transmission system and a cannula assembly according to some embodiments.
Figure 3A shows a partial cross section of a part of a handpiece that includes an engine part, a transmission system and a cannula assembly according to some embodiments.
Figure 3B shows a piston, a drive shaft, a rotating gear and a transmission bearing according to some embodiments.
Figure 3C shows a partial cross section of a part of a handpiece that includes an engine part, a transmission system and a cannula assembly attached to the handpiece using a threaded guide according to some embodiments.
Figure 4 shows a partial cross section of a part of a handpiece that includes an engine part, a transmission system and a cannula assembly according to some embodiments.
Figure 5 shows a partial cross section of a part of a handpiece that includes an engine part, a transmission system and a cannula assembly according to some embodiments.
Figure 6 shows a partial cross section of a part of a handpiece that includes an engine part, a transmission system and a cannula assembly according to some embodiments.
Figure 7 shows a partial cross section of a part of a handpiece that includes an engine part, a transmission system and a cannula assembly according to some embodiments.
Figure 8A shows a partial cross section of a part of a handpiece that includes an engine part and a cannula assembly according to some embodiments.
Figure 8B shows a top-bottom view of an engine part of Figure 8A according to some embodiments.
Figure 9 shows a partial cross section of a part of a handpiece that includes an engine part, a transmission system and a cannula assembly according to some embodiments.
Figure 10 shows a fluid console that includes a pneumatic module and an exploration module according to some embodiments.
In the figures the elements that have the same reference number have the same or similar functions.
Microsurgical interventions that use endoscopic instruments may include an endoscope that has a simple and cheap drive coupling system. The endosonda can be a portable endosonda for direct manipulation by specialized personnel. In some embodiments, the endoscope may be controlled by a robotic arm or a computer controlled device. Endosondas have a proximal end near the operating controller (either a specialist or a device), and a distal end near or in contact with the tissue. The endosondas according to the embodiments described herein may have small dimensions, be easy to handle from a proximal end and be minimally invasive in the surrounding tissue. In the distal part, the endosonda ends with a tip from which the endosonda performs a certain action on a target tissue located in the vicinity of the tip. For example, the endoscope may supply light from its tip and receive reflected or scattered light from the tissue, coupled through the tip. The endosonde tip may include moving elements that allow the tip to perform its action. In some embodiments, the tip may further include fixed elements to provide a fluid barrier and separate tissue from internal moving elements.
In some embodiments, the endoscope may include a handpiece at the proximal end, and a cannula system at the distal end in contact with the tissue. The cannula system can be symmetric around
of a longitudinal axis (LA). In some embodiments, the cannula system may include an optical scanning element. The cannula system may further include two concentric cannula tubes, an inner tube and an outer tube. Furthermore, according to the embodiments described herein, it is desirable to provide a rotating movement in the opposite direction to the inner tube relative to the outer tube using a single drive system. Also, according to some embodiments described herein, the drive system may use fluid flow, such as pneumatic flow energy. Other embodiments may use electrical energy to power the drive system.
The drive system in the portable endoscope can transform pneumatic flow energy into a mechanical piston movement. Thus, the movement of the piston can be used to drive a gear train to rotate the two cannula tubes in the opposite direction at the distal end of the endoscope. The movement of the piston is transferred to the cannula tubes that rotate in the opposite direction through a transmission system. In some embodiments, the transmission system may include an oscillating gear such as a helical or splined gear. The gear can also be allowed to rotate along the piston rod in one direction only (through a one-way bearing, for example) around the longitudinal axis of the cannula tubes. In some embodiments, a transmission system may include a gear system for converting a single shaft inlet from the piston into a counter-clockwise rotating movement coupled to the cannula tubes.
An actuation system like the one above can also include a double piston engine and a transmission system that includes uncoupled gear systems for independent drive control of each of the inner and outer tubes. In some embodiments, the drive system can convert the movement of the piston into a rotational movement of a shaft using a crankshaft system. If the piston movement is parallel to the axis of the cannula, then a gear system is used to rotate the two cannulas in the opposite direction around their individual axes. In some embodiments, the gear system may include bevel gears.
In some embodiments, a drive system may include a constant or adjustable (non-oscillatory) fluid flow to rotate a single fan connected to a shaft coupled to a transmission system. A drive system like the one above may include double fan motors for driving uncoupled gear systems for independent drive control of each of the inner and outer tubes. An actuation system may include double fan motors, each of them directly coupled to a cannula tube used for independent drive control.
Figure 1 shows a microsurgical endorsement 100 that includes an optical scanning element 110, a handpiece 150, a coupling cable 195 and a motor part 200 according to some embodiments. The optical scanning element 110 may also be referred to as "cannula assembly" according to some embodiments. The element 110 includes the distal end of the endoscope 100, which can be extended along the axis of the endoscope and have a limited cross section. For example, in some embodiments, the cannula assembly 110 may be about 0.5 mm in diameter, while handpiece 150 may have a substantially cylindrical shape several millimeters in diameter.
In some embodiments, the assembly 110 may be in contact with the tissue, including target tissue for ophthalmic microsurgical intervention. Thus, the assembly 110 can be coated with materials that prevent infection or tissue contamination. In addition, surgical interventions and protocols may establish hygienic standards for assembly 110, all of which are incorporated herein by reference in their entirety. For example, it may be desirable for the assembly 110 to be discarded after it has been used once. In some situations, the assembly 110 can be discarded at least every time the intervention is performed on a different patient, or on a different part of the body.
The embodiments of the endosonde 100 and the assembly 110 can meet industrial standards such as EN ISO 14971 (2007), "Medical devices - Application of Risk Management to Medical Devices"; ISO / TS 20993 (2006), “Biological evaluation of medical devices-Guidance on a risk management process”; ISO 14001 (2004), “Environmental management systems - Requirements with guidance for use”; ISO 15752 (2009), “Ophthalmic instruments - endoilluminstaors - fundamental requirements and test methods for optical radiation safety”; and ISO 15004-2 (2007), “Ophthalmic instruments - fundamental requirements and test methods– Part 2: Light hazard protection”.
Other embodiments of the cannula assembly 110 compatible with Figure 1 may be used. For example, embodiments such as those described in US patent application entitled "Counter-rotating Ophthalmic Scanner Drive Mechanism" by Mike Papac, Mike Yadlowsky and John Huculak, filed on the same date as the present application and assigned to Alcon Laboratories, Inc.
The handpiece 150 may be closer to the proximal end of the endoscope, and may have a larger cross-section compared to the element 110. The element 150 may be adapted for manual operation of the endoscope 100 according to some embodiments. Element 150 can be adapted for
robotic operation or for holding by an automated device or a remotely operated device. Although assembly 110 may be in contact with living tissue, element 150 may not be in direct contact with living tissue. Thus, even when the element 150 can meet the hygienic standards, these can relax somewhat compared to those used for the assembly 110. For example, the element 150 may include parts and components of the endosonde 100 that can be used repeatedly before being discarded
Thus, some embodiments of the endoscope 100 as described herein may include multiple components in the element 150, and less expensive replaceable components may be included in the assembly 110. Some embodiments may have a removable element 110 that is disposable, while that handpiece 150 can be used more than once. In some embodiments, the cannula assembly 110 can be fixed to the handpiece 150 by an adhesive joint. According to other embodiments, the assembly 110 can be removed from the handpiece 150 to allow easy replacement of the endoscope 100 for repeated interventions. Some embodiments compatible with Figure 1 may have a disposable element 150 and a disposable assembly 110.
In some embodiments, the removable cannula assembly 110 may include a vertical pressure insert with independent external screw locking. A keyway may be required to maintain the angular position of the inner tube 130 relative to the outer tube 140 during insertion of the assembly 110 into the handpiece 150. Alternatively, a small adhesive point or a disposable mechanical alignment pin can be used to maintain the relative angular position of the inner tube 130 relative to the outer tube 140 during insertion of the assembly 110 into the handpiece 150. The disposable alignment pin can be removed or discarded after installation. The adhesive can be exceeded by the transmission power in the initial use. For fiber-based probes, the fiber and the support tube can be retractable. Thus, the fiber can retract when the assembly 110 is removed and repositioned. A retractable mechanism can include a spring against a mechanical stop or it can be manual. A retractable mechanism for a fiber-based endorsement can prevent damage to the fiber in a removable assembly 110.
The cable 195 may be included in some embodiments to couple the endoscope 100 to a remote console or controller device (not shown in Figure 1). The cable 195 may include the power transmission elements for transferring electrical or pneumatic power to an actuator or mechanical motor in the motor part 200. The cable 195 may include transmission elements for transporting optical information and power, such as a laser beam or a laser pulse, from a console or remote controller to the tissue. An optical transmission element can also carry optical information from the tissue to a console or remote controller for processing. For example, cable 195 may include at least one or more optical fibers to transmit place to and from the tissue. In some embodiments, one optical fiber can transmit light to the tissue and another optical fiber can transmit light from the tissue. In addition, some embodiments can transmit light to and from the tissue through an optical fiber.
According to some embodiments compatible with Figure 1, the endoscope 100 is controlled through the remote console and all operating buttons and manual actuators are located remotely. Some of the control operations may include "connecting" or "disconnecting" the pneumatic power or adjusting the rotational speed of the cannula assembly 110. Some embodiments use a Graphical User Interface (GUI) to provide controls on the console. In other embodiments, the surgeon or medical staff may use a foot switch or a voice command to control the operation of the endoscope 100. Some embodiments, such as that illustrated in Figure 1, include a button 160 on one side, which provides direct control of certain operations in the endoscope 100 by pressing the button. Other devices used in conjunction with the endoscope 100, such as forceps or scissors, may also include actuators that the surgeon can squeeze with his hand to "connect" and "disconnect."
The cable 195 may also include tubing lines (not shown in Figure 1) to provide a pneumatic force to the motor part 200. For example, a first tubing line may include a flow of inlet fluid that provides a pneumatic force to the engine part 200. In addition, a second tubing line may include an outlet fluid flow that provides an escape for the engine portion 200. In addition, according to some embodiments, a first tubing line may include a fluid inlet that provides a first pressure to the motor part 200. A second tubing line may include an inlet fluid that provides a second pressure to the motor part 200. In some embodiments, the cable 195 may provide electrical power to the motor part 200. For example, the motor part may include at least one electric motor that receives power from the cable 195.
Some embodiments compatible with Figure 1 may include a handpiece 150 with a removable cannula assembly 110. The assembly 110 may be easily removable from the handpiece 150 by an automatic fastening system or a bayonet system. Handpiece 150 may include a bearing and a sleeve coupled to the proximal end of assembly 110 to provide support and stability.
In embodiments such as that shown in Figure 1, it may be desirable that the microsurgical endoscope 100 has a minimum cross-sectional area. This can reduce the invasiveness of the intervention
surgical in the target tissue, especially in areas adjacent to the areas of interest. In order to limit the cross-sectional area of the cannula assembly in the endoscope 100, the mechanical elements involved in the movable parts of the endoscope need to be placed close to each other.
The motor part 200 can be included at a distal end of the handpiece 150. According to embodiments of the endosonde 100 as illustrated in Figure 1, the part 200 can have a narrowed profile in order to couple the part handpiece 150 with the assembly 110. For example, in some embodiments the handpiece 150 may have a larger diameter (of the order of several mm to 1 cm or more), and the assembly 110 may have a smaller diameter (from 100 µm or less at a few hundred µm to 0.5 mm or more). Part 200 may include engine 125 and drive shaft 212 to couple engine 125 to drive system 127. Part 200 will be described in detail in relation to the embodiments compatible with Figures 2-8 and Figure 10 following.
Figure 2 shows a part of the handpiece 150 that includes the engine part 200 and the assembly 110 according to some embodiments. The engine 125 may include a piston 210, a pneumatic fluid channel 201 and the pneumatic fluid channel 202. The transmission system 127 in the embodiments compatible with Figure 2 may be a helical groove that includes helical gears 220, 230 and 240. In some embodiments, the transmission system 127 may include a splined gear in any one of the gears 220, 230 and 240. The shaft 212 couples the piston 210 to the helical gear 220.
According to Figure 2, the pneumatic flow channel 201 provides pneumatic force to the piston 210 in one direction through a first pressure. The pneumatic flow channel 202 provides pneumatic force to the piston 210 in the opposite direction through a second pressure. For example, an increase in the pressure in the channel 201 can push the piston 210 "down". Instead, an increase in the pressure in the channel 202 can push the piston 210 up. The opposite configuration can also be applied, namely, a reduction of the pressure in the channel 202 pulls the piston 210 "upwards". Also, a reduction of the pressure in the channel 201 can pull the piston 210 "down". Also, a combination of "pushing" and "pulling" pneumatic forces can be used in some embodiments. For example, while reducing the pressure in the channel 201, the pressure in the channel 202 can be increased. Thus, a tensile force of the channel 201 can be added to a pushing force in the channel 202 to move the piston 210 "down " Also, a pushing force from the channel 201 can be added to a pulling force in the channel 202 to move the piston 210 "upward". The pneumatic force provided to piston 210 through channels 201 and 202 may include a vacuum system. Thus, a vacuum can be coupled to a channel 201 (or 202) to reduce the pressure in the channel below that of the opposite channel 202 (or 201).
The motor part 200 according to Figure 2 may include a sealing gasket 215 around the shaft 212. The sealing gasket 215 may be an O-ring formed of a resilient material, such as rubber. The sealing gasket 210 can prevent the fluid inside the motor 125 from coming into contact with the space within assembly 110. Thus, the sealing gasket 215 prevents contamination of the elements within the assembly 110 by the fluid for the motor 125. The sealing gasket 215 also maintains the pressure level within the motor 125 at an appropriate value.
The transmission system 127 may include helical gears 220, 230 and 240 according to the embodiments compatible with Figure 2. The gears 220, 230 and 240 may have parallel shafts. As illustrated in Figure 2, the rotation axis of the gear 220 is the longitudinal axis (LA) of the assembly 110. The gear 230 has a rotation axis labeled SA2 and the gear 240 has a rotation axis labeled SA1. In embodiments compatible with Figures 2-9, the longitudinal axis of assembly 110 is labeled LA. The shaft in the system 127 around which a rotating movement is provided to the inner tube 130 is labeled SA2 in embodiments compatible with Figures 2-9. The shaft in the system 127 around which a rotating movement is provided to the outer tube 140 is labeled SA1 in embodiments compatible with Figures 2-9. According to the embodiments compatible with Figure 2, axes SA1 and SA2 are parallel to axis LA. Other embodiments may have different configurations for the SA1 and SA2 axes relative to the LA axis. Furthermore, according to Figures 2-9, the axes SA1 and SA2 can be parallel to each other, having a distance "D" between them. It is noted that in the embodiments compatible with Figure 2, the distance between LA and SA1 may not be the same as the distance between LA and SA2. Some embodiments compatible with the concept illustrated in Figure 2 may be such that the axes LA, SA1 and SA2 may not be included in the same plane, but are included within the outside diameter of the assembly 110. Other embodiments may have axes LA, SA1 and SA2 oriented at any angle with respect to each other. In addition, some embodiments may include collinear LA, SA1 and SA2 axes with each other.
According to Fig. 2, the gear 220 can be fixed to the shaft 212 and the gears 230 and 240 can be allowed to rotate around the shafts 217. The gear 220 is moved "up" and "down" by the shaft 212 when the forces pneumatic move piston 210 according to the description above. When the gear 220 is moved, it pushes on the grooves of the gears 230 and 240. The thrust of the gear 220 on the gears 230 and 240 exerts a torque that induces a rotation in the gears 240 and 230 around the shafts 217.
Figure 2 includes a cannula assembly 110. The assembly 110 is coupled to the engine 125 in the handpiece 150 through the transmission system 127. The assembly 110 may include concentric tubes or "cannulas" 130 and 140 according to some forms of realization. The inner tube 130 and the outer tube 140 can be aligned with their symmetry axes along the axis LA. The inner tube 130 and the outer tube 140 are hollow and may be able to move relative to each other in a rotating and counter-rotating movement around the LA axis. The reference to inner tube 130 as "rotating" and outer 140 as "counter-rotating" is arbitrary and establishes the relative movement between tubes 130 and 140. In some embodiments, while tube 130 rotates "in the direction of needles. of the clock ”, the tube 140 can rotate“ counterclockwise ”around the LA axis. The opposite configuration can take place, in which tube 130 rotates "counterclockwise" and tube 140 rotates "clockwise".
The rotation of the tubes 130 and 140 is provided by the motor 125 through the gears 230 and 240, as shown in Figure 2. The gears 230 and 240 can rotate in the same direction at any time in time, providing tubes of cannula 130 and 140 cogiratorios. In embodiments compatible with Figure 2 used for optical scanning (for example, in OCT), a rotating scanning pattern of an optical beam may result. In such a configuration, cogiratory tubes 130 and 140 can still provide a fixed linear optical scan pattern by synchronizing the detection so that each adjacent point along a fixed line is optically captured during a different revolution of the cannula assembly 110. Other Embodiments of cogiratory tubes 130 and 140 compatible with Figure 2 can be used for rotating optical line scans in volume imaging. The gears 230 and 240 are coupled to the cannula tubes 130 and 140, respectively, through threaded guides in the inner wall of the cannulas or tubes.
Some embodiments compatible with Figure 2 may include a stationary cannula 120. Cannula 120 can provide a protective cover to assembly 110. Also, cannula 120 can prevent or reduce a shear stress induced in the target tissue by viscoelastic forces that they act during the rotation of the outer tube 140. The use of the stationary cannula 120 is optional and can be determined by the type of target tissue into which the endoscope 100 will be introduced.
The materials used to form the cannula elements 120, 130 and 140 can be any of a variety of biocompatible materials. For example, some embodiments may include elements 120, 130 and 140 made of stainless steel or plastic materials. In addition, some embodiments may have part or all of elements 120, 130 and 140 coated with a protective layer. The coating material may be a layer of gold or some biocompatible polymer. In some embodiments, the role of the coating layer may be to provide lubrication and friction relief to the moving parts in the assembly
110. For example, the coating materials may reduce friction between the inner face of the tube 140 and the outer face of the tube 130. In some embodiments, the role of the coating layer may be to provide protection to the fabric in direct contact with set 110.
To reduce friction between the inner tube 130 and the outer tube 140 when they rotate in the opposite direction relative to each other, some embodiments of the assembly 110 may include ball bearings 250. The bearings 250 may be interspaced at predetermined distances along of the length of the assembly 110. In embodiments that include the fixed cannula 120, the bearings 250 may be included between the outer tube 140 and the fixed cannula 120. The ball bearings 250 may be formed of a material such as stainless steel, or a hardened plastic, such as vinyl. Other materials may be used to provide friction relief to the moving parts in the assembly 110, such as copper or aluminum, and polymer coatings.
Figure 3A shows a handpiece part 150 that includes the engine part 200, the transmission system 127 and the cannula assembly 110 according to some embodiments. The engine part 200 in Figure 3A includes the engine 125 with a piston 210, a shaft 212, a sealing gasket 215 and pneumatic flow channels 201 and 202, as described above in relation to Figure 2. The assembly 110 in Figure 3A includes the inner tube 130, the outer tube 140 and, optionally, some embodiments may include ball bearings 250 and a fixed cannula 120. The assembly 110 has been described in detail in relation to the previous figure 2 .
The transmission system 127 according to Figure 3A includes a rotating helical gear 320 and gears 330, 331, 332, 335, 340 and 341. The shafts LA, SA1 and SA2 in Figure 3A are parallel to each other, as described in detail in relation to Fig. 2. The gear system 127 couples the "up" and "down" movement of the shaft 212 in a rotating direction in the opposite direction between the inner tube 130 and the outer tube 140. In the form of embodiment compatible with Figure 3A, when the helical gear 320 is allowed to rotate around the shaft 212 in one direction, this induces a rotation of the gears 330 and 340 in the opposite direction through a "helical" coupling of the threaded faces of the gears.
The gear 341 is attached to the gear 340 and provides a rotation to the inner tube 341. In some embodiments compatible with Figure 3A, the gear 341 may be fixed relative to the gear 340, rotating about the same axis SA2. Gear 331 is attached to gear 330 and provides rotation to gear 332 in the opposite direction. The gear 332 can be attached to the gear 335, which provides a rotation to the outer tube 140. In embodiments compatible with Figure 3A, the gears 330 and 331 can be fixed
one relative to another and rotate around the same axis SA2. The gears 332 and 335 can also be fixed relative to each other and rotate about the same axis 218. As a result, the transmission system 127 in Figure 3A can provide a counter-rotating movement between the inner tube 130 and the outer tube 140. For example, while gears 330 and 340 can both be rotated clockwise, inner tube 130 can be rotated counterclockwise by gear
341. And the outer tube 140 can be rotated clockwise by the gear 335, which, in turn, is rotated counterclockwise by the gear 331. The detailed coupling between the motor 125 and the rotating gear 320 is described in relation to Figure 3B.
Figure 3B shows the piston 210, the drive shaft 212, the rotating gear 320 and the transmission bearing 321 according to some embodiments. The bearing 321 allows the gear 320 to rotate around the shaft 212 when the piston 210 moves "up" and "down" according to embodiments compatible with Figures 3A and 3B. For example, when the shaft 212 is moved "down" by the piston 210, the gear 320 can be rotated clockwise or counterclockwise by the reaction torque of the gears 330 and 340 placed in contact with it (see figure 3A). Whether the gear 320 moves clockwise or counterclockwise when the piston 210 moves "down" depends on the orientation of the "helical" thread on the gear surface 320. In the embodiment illustrated in Figure 3B, the helical thread of the gear 320 is such that it rotates clockwise when the piston 210 moves "down". Some embodiments may have the opposite configuration, such that the gear 320 rotates counterclockwise when the piston 210 moves "down".
When the piston 210 moves "upward", different embodiments may be compatible with Figure 3B. In embodiments such that the transmission bearing 321 is a standard bidirectional bearing, then the gear 320 can rotate in the opposite direction to that in which it rotates when the piston 210 moves "down". This is due to the reaction torque of gears 330 and 340 brought into contact with gear 320 (see Figure 3A). In this scenario, the system 127 (see Figure 3A) provides the inner tube 130 with a rotation movement in the opposite direction relative to the outer tube 140, which is opposite to the rotation movement in the opposite direction when the piston 210 moves "towards down". For example, when the piston 210 moves "downward", the inner tube 130 can rotate clockwise and the outer tube 140 can rotate counterclockwise. And when the piston 210 moves "upward", the inner tube 130 can rotate counterclockwise and the outer tube 140 can rotate clockwise. The result will be a "winding" movement of the cannula assembly 110. A "winding" movement of the assembly 110 can reduce abrasion to the tissue in direct contact with the cannula assembly 110. A "winding" movement is such that Tubes 130 and 140 rotate in one direction during one cycle, and commute to rotate in the opposite direction in the next cycle. Thus, as long as the scanning effect is a linear path, the tissue surrounding the assembly 110 is subjected to a reduced shear.
In other embodiments compatible with Figure 3B, the bearing 321 may be a one-way bearing or a one-way bearing, so that it is allowed to rotate only in one direction (clockwise
or counterclockwise). Thus, when the shaft 212 is moved "up" and "down" by the piston 210, the result is that the gear 320 rotates the gears 330 and 340 in one direction. The direction of rotation of gears 330 and 340 can be clockwise or counterclockwise, depending on which direction the unidirectional gear is allowed to rotate
321. For example, bearing 321 may allow gear 320 to rotate only clockwise around shaft 212. In such a configuration, gears 330 and 340 will rotate counterclockwise when piston 210 moves "up" and when piston 210 moves "down".
Figure 3C shows a partial cross section of a part of the handpiece 150 that includes the engine part 200, the transmission system 127 and the detachable cannula assembly 110 according to some embodiments. The assembly 110 is fastened to the handpiece 150 using a threaded guide 350. A mechanical stop 360 secures the assembly 110 in place. Threaded guide 350 and stop 360 ensure that the proximal ends of inner tube 130 and outer tube 140 make proper contact with gears 341 and 335 of transmission system 127, respectively.
It would be obvious that other embodiments of the endosonde 100 may be possible with the handpiece 150 and the detachable cannula assembly 110. For example, instead of the threaded guide 350, the cannula assembly 110 can simply be automatically fastened on handpiece 150 and remain in place by pressure. In some embodiments, a bayonet mechanism can replace the threaded guide 350 with a groove and pins that secure the assembly 110 in place by locking it in holes or carved spaces in the handpiece 150. Other embodiments of the piece Handpieces 150 having the detachable cannula assembly 110 will be apparent to those skilled in the art in view of the concept illustrated in Figure 3C.
Figure 4 shows a part of the handpiece 150 that includes the engine part 200 and the cannula assembly 110 according to some embodiments. The engine 125 in embodiments compatible with Figure 4 includes the piston 210, the drive shaft 212 and the pneumatic flow channels 201 and 202. Also, in Figure 4,
It includes a sealing gasket 215 as described above in relation to Figure 2. The motor 125 operates in a manner compatible with the description provided in Figure 2 and in Figure 3A. The cannula assembly 110 in Figure 4 includes the inner tube 130 and the outer tube 140. Some embodiments may also include ball bearings 250 and the fixed cannula 120. The assembly 110 in Figure 4 is compatible with the description of assembly 110 in Figure 2 and in Figure 3A above.
The transmission system 127 in the engine part 200 couples the "up" and "down" movement of the shaft 212 to a counter-rotating movement of the tubes 130 and 140 in the assembly 110. According to compatible embodiments with FIG. 4, the transmission system 127 may include a crankshaft 450, shaft bearings (sleeves) 460, bevel gears 410, 415, 420, 425 and 427 and the rotating shaft 217. The crankshaft 450 converts the movement " up "and" down "the tree 212 in a rotating movement. The crankshaft 450 rotates on the part 200 through the sleeves 460 at both ends. The sleeves 460 allow rotation of the crankshaft 450 and provide support thereto. As illustrated in Figure 4, the crankshaft 450 may be perpendicular to the shaft 212. The tubes 130 and 140 that rotate in the opposite direction in the cannula assembly 110 have an axis parallel to the shaft 212. Thus, the bevel gears 410, 415 , 420, 425 and 427 can be used to convert the rotation of the crankshaft 450 into a rotation about the axis of the cannula assembly 110, as shown in the figure
According to embodiments compatible with Figure 4, gears 410 and 420 may have a shaft in the crankshaft 450 and be fixed thereto. The gear 415, oriented in a plane perpendicular to that of the gear 410, has its axis along the axis of the assembly 110. The gear 415 can be fixed to the inner tube 130 in the assembly 110. Thus, the rotation of the gear 410 with the crankshaft 450 induces a rotation of the inner tube 130. Also, the gear 427 is oriented in a plane perpendicular to that of the gear 420 and has its axis along the axis of the assembly 110. The gear 427 can be fixed to the outer tube 140 and coupled to the gear 420 through the gear 425. The gear 425 may be in the same plane as the gear 420, with its shaft in the shaft 217, parallel to the crankshaft
450. Shaft 217 rotates over part 200 through sleeve 460, allowing shaft 217 and gear 425 to rotate when gear 420 rotates. When gear 420 rotates, it transmits rotation to gears 425 and 427, making thus rotating the outer tube 140. The inclusion of the gear 425 in the transmission train from the crankshaft 450 to the outer tube 140 provides a rotation movement in the opposite direction relative to the tube 130. Consequently, in embodiments compatible with the Figure 4, the axes SA1 and SA2 can be parallel to each other and can form a plane that includes the LA axis. However, the LA axis is perpendicular to the SA1 and SA2 axes. In addition, in some embodiments compatible with Figure 4, the LA axis may not be in the plane formed by parallel axes SA1 and SA2.
Figure 4 also illustrates a path 470 of fiber optic routing. The path 470 may be a hole drilled through the motor part 200 to allow an optical fiber to reach the distal end of the assembly 110. The path 470 may include a plurality of optical fibers, such as a bundle of optical fibers. Path 470 can be formed by drilling a hole through part 200. In some embodiments, path 470 can be formed by joining two molded halves of part 200, each having a groove or channel molded to path 470.
Figure 5 shows a part of the handpiece 150 that includes the engine part 200 and the cannula assembly 110 according to some embodiments. The engine 125 in Figure 5 may include an inlet flow channel 501, a speed regulator 505, a drive fan 510 and an exhaust pipe 502. Also, a seal 215 is included in Figure 5 as the described above in relation to Figure 2. According to embodiments compatible with Figure 5, fluid flows continuously from the inlet flow channel 501 to the exhaust pipe 502. The speed regulator 505 can increase or decrease the flow rate through the fan 510. The transmission system 127 in embodiments compatible with Figure 5 is analogous to the system 127 described in relation to Figure 4. Thus, the arrangement of axes SA1 and SA2 in relation to the axis LA in the Figure 5 follows the description of Figure 4.
According to embodiments compatible with Figure 5, a fluid flows continuously from channel 501 to channel 502. When the fluid collides with fan 510, it provides a rotational movement to shaft 212 around its axis. In some embodiments, the fan 510 includes blades that span a surface area perpendicular to a plane that includes the shaft of the shaft 212. In addition, the blades can be folded so that each blade encompasses a part of a helix around the shaft 212. The helicoid is oriented in the same direction for all the blades: clockwise or counterclockwise. The specific orientation of the helicoid and the direction of the fluid flow can determine the direction of rotation of the shaft 212. As illustrated in Figure 5, the motor 125 may include the speed regulator 505 in the channel 501. The speed regulator 505 "upstream" is placed with respect to the fan 510. In embodiments compatible with Figure 5, the regulator 505 can provide a constriction in the channel 501 to create a Venturi effect on the flow. In such a configuration, a Venturi effect for an incompressible or almost incompressible fluid includes a reduction in the cross-section of the flow and an increase in the flow velocity. Thus, the transfer of the amount of movement of the fluid to the rotational movement of the shaft 212 can be increased. The degree of the speed increase can be changed by precisely adjusting the cross section of the channel 501.
Thus, some embodiments compatible with Figure 5 may provide a speed control for the rotational movement of the tubes 130 and 140 in the assembly 110.
The assembly 110 of Figure 5 is compatible with the description of the assembly 110 in Figure 2 and in Figure 3A above. Also, the fiber routing path 470 in Figure 5 is compatible with the description provided in relation to Figure 4 above.
Figure 6 shows a part of the handpiece 150 that includes the engine part 125, the transmission system 127 and the cannula assembly 110 according to some embodiments. The engine part 125 in Figure 6 is compatible with the description provided above in relation to Figure 5. The transmission system 127 is compatible with the description provided above in relation to Figure 4. Thus, as long as the axes SA1 and SA2 are parallel to each other, the LA axis is perpendicular to both. The assembly 110 in Figure 6 is compatible with the description of the assembly 110 in Figure 2 and in Figure 3A above. Likewise, a seal 215 is included in Figure 6 as described above in relation to Figure 2. According to embodiments compatible with Figure 6, the fiber routing path 470 can run along the axis LA. Thus, the bending of the optical fibers and other elements included in the path 470 is reduced to a minimum. In order to provide the path 470 as illustrated in Figure 6, the motor 125 can be placed next to the handpiece 150, increasing the length of the shaft 212.
Figure 7 shows a part of the handpiece 150 that includes the engine part 125, the transmission system 127 and the cannula assembly 110 according to some embodiments. The motor part 125 may include two motors, each motor including a fan 710-1 and 710-2 as in Figures 5 and 6, and being placed on each side of the handpiece 150 around the fiber path 470. In Figure 7, the fiber path 470 is as described in relation to Figure 6. Also, in Figure 7 sealing gaskets 215 are included as described above in relation to Figure 2. The assembly 110 in the Figure 7 is compatible with the description of the assembly 110 in Figure 2 and in Figure 3A above.
According to embodiments compatible with Figure 7, the motor 125 may include an inlet flow path 701 that feeds both fans 710-1 and 710-2. The exhaust flow can leave the engine 125 through two channels 702-1 and 702-2, after colliding with each fan 710-1 and 710-2, respectively. In addition, some embodiments may include actuators 721-1 and 721-2 that provide a speed adjustment control as described in relation to regulator 505 in Figure 5. Thus, embodiments compatible with Figure 7 they can provide a separate adjustment to the speed of fans 710-1 and 710-2. In some embodiments, the blades of the fans 710-1 and 710-2 can be oriented in opposite directions, so that the shafts 212-1 and 212-2 rotate and contragire with respect to each other. This system has the advantage of a single pneumatic force that provides a rotating movement in two opposite directions and simplifies the design of the transmission system 127.
The transmission system 127, as illustrated in Figure 7, may include gears 720-1 and 730-1 that couple the rotation of shaft 212-1 to the outer tube 140. System 127 may also include gears 720-2 and 730-2 that couple the rotation of the shaft 212-2 to the inner tube 130. Other configurations compatible with Figure 7 may be possible, for example gears 720-2 and 730-2 that couple the rotation of the shaft 212-2 to the outer tube 140 and gears 720-1 and 730-1 that couple the rotation of shaft 212-1 to inner tube 130. In such a configuration, a reorganization of gears 730-2 and 730-1 may be necessary to provide a space of clearance for inner tube 130 and gear 730-1. According to Figure 7, the axes LA, SA1 and SA2 are parallel to each other, as described in detail with respect to Figure 2 above.
According to embodiments compatible with Figure 7, while the shaft 212-1 can rotate in a given direction, the rotation provided to the tube 140 can be in the opposite direction. The same may be true for tree 212-2 and tube 130. The end result is that tubes 130 and 140 have a counter-rotating movement relative to each other. In addition, the speed of each of the tubes 130 and 140 can be adjusted independently of each other using actuators 721-1 and 721-2. The operation of the motor 125, as illustrated in Figure 7, uses the same pneumatic force to drive two counter-rotating movements.
Figure 8A shows a part of the handpiece 150 that includes the engine part 125 and the cannula assembly 110 according to some embodiments. In accordance with embodiments compatible with Figure 8A, two independent flow channels 803-1 and 803-2 are provided having a flow input 801-1 and 801-2 and an exhaust channel 802-1 and 802- 2, respectively. For each flow channel, a drive fan 810-1 and 810-2 is placed tangentially to the flow direction. Fans 810-1 and 810-2 are oriented in a plane that includes flow channels 803-1 and 803-2. Thus, the rotation axes of the fans 810-1 and 810-2 are perpendicular to the direction of the flow channels 803-1 and 803-2. Fans 810-1 and 810-2 include blades that have a surface part in a plane parallel to a plane that includes the fan shaft. In addition, fans 810-1 and 810-2 can be positioned so that the flow channels 803-1 and 803-2 are interrupted along a small part by the tip of the fan blades. When the fluid in channels 803-1 and 803-2 collides with the blades of the fans 810-1 and 810-2, the transfer of the amount of fluid movement to the blades results in a rotational movement of the fans around of its axes. Set
110 in Figure 8A is compatible with the description of the assembly 110 in Figure 2 and in Figure 3A above. Likewise, the fiber routing path 470 that runs along the LA axis is compatible with the description provided in relation to Figure 6 above. The sealing gasket 215 in Figure 8A is as described in relation to Figure 2.
According to embodiments compatible with Figure 8A, the transmission of rotational movement from the motor 125 to the inner tube 130 and the outer tube 140 can be provided directly through the fans 810-2 and 810-1, respectively. Thus, in a configuration as illustrated in Figure 8A, less longitudinal space is used in the handpiece 150; and less or no transmission gears are needed. In embodiments compatible with Figure 8A, the axes LA, SA1 and SA2 are collinear. On the other hand, it may be necessary to use two 803-1 and 803-2 flow channels, including the 801-1 and 801-2 input channels and the 802-1 and 802-2 escape channels. As illustrated in Figure 8A, the flow through channels 803-1 and 803-2 takes place in opposite directions. This provides a rotating movement opposite the inner tube 130 (fan 810-2) relative to the outer tube 140 (fan 810-1). Other configurations compatible with the concept illustrated in Figure 8A may be possible, as will be described in detail in relation to Figure 8B below.
Figure 8B shows an up-down view of a part of the motor 125 as in Figure 8A, according to some embodiments. In the two configurations shown, 851 and 852, fans 810-1 and 810-2 are represented separately for reasons of clarity. It is understood that fans 810-1 and 810-2 are placed on top of each other, sharing their rotation axes as illustrated in Figure 8A above. In configuration 851, a counter-rotating movement is provided to fans 810-1 and 810-2 by placing flow channels 803-1 and 803-2 tangentially in relation to the fans and on opposite sides relative to the centers of the fans. In such a configuration, having the fluid flow in the same direction in channels 803-1 and 803-2 results in a counter-rotating movement of fans 810-1 and 810-2. In configuration 852, a counter-rotating movement is provided to fans 810-1 and 810-2 by placing flow channels 803-1 and 803-2 tangentially in relation to the fans and on the same side in relation to the centers of the fans . In such a configuration, having the fluid flow in the opposite direction in channels 803-1 and 803-2 results in a counter-rotating movement of fans 810-1 and 810-2.
It is noted that a configuration such as 851 in Figure 8B may allow engine 125 to have a single flow inlet 801 and a single exhaust 802 for both flow channels 803-1 and 803-2. Embodiments compatible with configuration 852 in Figure 8B may have the advantage of reducing the cross-sectional space used in handpiece 150 using only one side of fans 810-1 and 810-2 for a flow channel .
Figure 9 shows a part of the handpiece 150 that includes the engine part 125, the transmission system 127 and the cannula assembly 110 according to some embodiments. The embodiments compatible with Figure 9 are analogous to the embodiments described in Figure 7 because two motors 910-1 and 910-2 provide a counter-rotating movement to the inner tube 130 and the outer tube 140. Thus, the Transmission system 127 in Figure 9 is as described in relation to Figure 7, including the relative orientations of the LA, SA1 and SA2 axes. The assembly 110 in Figure 9 is compatible with the description of the assembly 110 in Figure 2 and in Figure 3A above. Also, the fiber routing path 470 that runs along the axis of the handpiece 150 is compatible with the description provided in relation to Figure 6 above.
The motors 910-1 and 910-2 in Figure 9 can be electric motors according to some embodiments. Thus, a fluid flow may not be necessary in embodiments compatible with Figure 9, and the seal 215 may not be included in the design.
Figure 10 shows a fluid console 1000 that includes a pneumatic module 1050, a scanning module 1060 and the endoscope 100 according to some embodiments. According to Figure 10, a pneumatic force is obtained from an external source such as a wall pressure connector 1010, coupled with a "On / Off" switch 1012. The pneumatic force is adjusted by the module 1050, which includes elements 1055 and 1057. The mechanical regulator (M) 1055 is used to regulate the incoming wall pressure approximately within the inlet range for electronic regulators (E) 1056 and (E) 1057. Electronic regulators (E) 1056 and (E) 1057 provide fine and controllable pressure regulation for pressure chambers 1051 and 1052. Regulators 1056 and 1057 are included in their respective control loops to control the pressure in the corresponding chambers.
A pressure chamber 1051 provides a fluid with a first pressure (pressure 1) and a pressure chamber 1052 provides a fluid with a second pressure (pressure 2). Pressure 1 can be used for a surgical operation other than the operation of pressure 2. For example, in some embodiments pressure 1 can be used to operate a scissor system or other mechanical element using during surgery. In addition, the system can energize a cutter for vitrectomy interventions.
The pressure 2 provided by the element 1052 is coupled to a scanning module 1060 through a connection cable 1058. The cable 1055 can be a plastic tubing capable of containing a fluid at a pressure
preselected The scanning module 1060 may include an input connector 1070 to receive the cable 1055 and couple the pressure 2 to an element 1065. The element 1065 in turn converts the pressure 2 into a preselected scanning pressure (pressure 3) that is coupled through valves 1061 and 1062 to flow channels 1071 for an explorer 1 and 1072 for an explorer 2. In some embodiments compatible with the description provided so far, the explorer 1 may include some of the elements of the figures 1-8 associated with the rotation of the inner tube 130. Also, the explorer 2 may include some of the elements of Figures 1-8 associated with the rotation of the outer tube 140.
The scanning module 1060 may be an OCT scanning module according to some embodiments. In such cases, the scanner 1 may be associated with the inner tube 130 in the assembly 110, having an optical element at the distal end. Also, the scanner 2 can be associated with the outer tube 140 in the assembly 110, having an optical element at the distal end.
The probe 100 according to some embodiments described herein can provide a simple and efficient system for generating a precisely controlled counter-rotating movement in two concentric tubes. An endorsement of this type can be used as an OCT image formation endorsement, or a multipoint laser endorsement. Although endosondas can have three-dimensional structures, they can be highly constrained in cross-section and extend in a certain direction. Thus, an endosonde according to embodiments described herein may have a longitudinal axis, which is the direction of the endosonde's length, and a cross section. In addition, in some embodiments the endosondas can be axially symmetrical, at least in a part of the endosonde that can include the distal end.
In OCT imaging techniques a beam of light having a coherence length can be directed to a certain point in the target tissue using an endosonde. The coherence length provides a depth of resolution that, when modified at the proximal end of the endoscope, can be deconvolved to produce a deep picture of the lighted part of the tissue. An in-depth profile is usually called an A scan in OCT techniques. By exploring the point of illumination along a line, a scan profile A can be transformed into a two-dimensional tissue image. This may be called a B-scan intervention in OCT techniques. In some embodiments, the B scans are straight lines along a cross section of the tissue. In addition, performing repeated B scans along different lines in the tissue can provide 3D reproduction of the tissue. In some embodiments, the scans B can be a set of lines that have the same length and are arranged in a radius that starts from a common crossing point. Thus, a plurality of scans B can provide an image of a circular area in the tissue, having a depth.
According to some embodiments of the OCT 1060 scan module, a plurality of scans A can be completed for each scan step B. For example, 512 scans A can be used to complete a scan B. Some embodiments may use a smaller number of A scans per scan cycle B, thus allowing the intervention of scan B to take place at a faster rate. In such cases, the rotation and counter rotation speeds of the tubes 130 and 140 can be further increased.
To obtain a complete group of scan lines, including scan lines B arranged in preselected patterns, movable parts can be used at the distal end of the endoscope. Moving parts may include delicate optical components moved to direct a beam of light along a desired direction. Precise control of this movement is important for the effectiveness of OCT interventions. In particular, movement repeatability may be required so that scans A can be aligned along scan lines B to form a continuous image. In some embodiments, the movement of the moving parts in the endoscope may be a periodic cycle that has a closed trajectory. For example, a path can be circular, centered on the axis of the endosonde. The longitudinal axis of the endoscope may be the optical axis of an optical system.
A substantially one-dimensional endoscope having an axis of symmetry according to some embodiments described herein may provide radially oriented B scans around the axis of the endosonde. To achieve this, two counter-rotating elements can be used, synchronized accordingly by a transmission system that uses a combination of gears. For example, two counter-rotating elements concentrically arranged around the axis of the endosonde can provide an optical scan of a beam along a radial direction in a plane perpendicular to the axis of the endosonda and centered therein. Such an arrangement may use optical elements as described in detail in the document of WU et al. incorporated herein as a reference in its entirety (J. Wu, M. Conry, C. Gu, F. Wang, Z. Yaqoob and C. Yang; "Pairedangle-rotation scanning optical coherence tomography forward-imaging endoprobe", Optics Letters , 31 (9) 1265 (2006)). Some embodiments may include a synchronization system such that the relative phase and speed of the two counter-rotating elements can be regulated as desired. Thus, two counter-rotating elements can provide a linear radial scan along a plane that includes the endosonde axis. Furthermore, by adjusting the angular velocities and relative phases of the counter-rotating elements, the plane of the radial scan can be rotated around the axis of the endosonde. Some embodiments
E12712806
As described above, they may be such that the radial scan is not perfectly linear. That is, the optical beam may not move in a perfect line contained within a plane that includes the endosonde axis. In some embodiments, the movement may be substantially near the plane, on an elongated path substantially near a line contained in the plane. In some embodiments, the path of the optical beam may form an elongated "8" figure in a plane perpendicular to the axis of the endoscope and centered therein.
In some embodiments, OCT techniques use forward-directed exploration interventions. In this case, the optical illumination takes place in the forward direction of the endosonde axis. In forward-facing scans, the target tissue may be in front of the endosonde in a plane perpendicular to the axis of the endosonde. Thus, the light that travels from the tip of the endosonda to the tissue, and again from the tissue to the endosonda, can move in a direction substantially parallel to the axis of the endosonda. In some embodiments that use forward-facing scans, the target tissue may be approximately perpendicular to the axis of the endosonde, but not exactly. In addition, in some embodiments the light that travels to the target tissue and from it and from the endoscope and into it, may not be parallel to the axis of the endoscope, but may form a symmetrical pattern around the axis of the endorsement For example, the light that illuminates the target tissue in a forward-facing scan may form a solid cone or a part thereof around the axis of the endosonde. Likewise, the light collected by the endoscope in a forward-facing scan can come from the target tissue in a 3D region, including a part of a cone section around the endosonde's axis.
In some embodiments, an OCT technique can use lateral imaging. For example, in lateral imaging, the target tissue may be parallel to a plane containing the axis of the endosonde. In a situation similar to this, it may be desirable to move the illumination point in a circular path around the axis of the endoscope to create a closed loop image of the target tissue. Such a situation may arise in ophthalmic microsurgery that involves endovascular interventions. For example, in coronary angiography the inner wall of the coronary artery can be fully explored in cylindrical sections along the arterial lumen using embodiments described herein.
Some embodiments may use endosondas such as those provided here for the supply of laser light intended for therapeutic purposes. For example, in photodynamic interventions, a laser light can be explored to activate a chemical agent present in a drug previously supplied to the target tissue. In some embodiments, laser light can be used to selectively flatten or remove tissue or residual materials from the target areas. In embodiments such as those described previously, the precise control of the light supplied is provided by movable components at the distal end of the endoscope.
It is noted that the conversion of a rotational movement into a linear movement according to some embodiments described herein provides a delicate system for performing a linear movement. While a rotating movement can be continuously provided, a cyclic linear movement may require the stopping and acceleration of a mechanical element, if attempted directly. Stopping and accelerating a mechanical element subject to friction may not be desirable.
The embodiments of the invention described above are by way of example only. A person skilled in the art can recognize various alternative embodiments of those specifically described. Alternative embodiments are also intended to be within the scope of this description. Therefore, the invention is limited only by the following claims.
1. Ophthalmic endoscope (100), comprising:
5 a handpiece (150) attachable to a cannula assembly (110) having a longitudinal axis, the cannula assembly comprising an inner tube (130) concentric with an outer tube (140); comprising the handpiece also
a motor (125, 200), the engine (125) comprising a mechanical piston (210) that can be moved in a longitudinal direction by a pressurized fluid, the mechanical piston (210) providing movement to a drive shaft (212) ; Y
a transmission system (127) for coupling the movement of the shaft to the cannula assembly, adapted to provide a counter-rotating movement to the inner tube and the outer tube around the longitudinal axis of the cannula, the transmission system (127) comprising systems of uncoupled gears for independent drive control of the inner tube (130) and the outer tube (140).
2. Ophthalmic endoscope according to claim 1, wherein the transmission system (127) comprises a gear
oscillating which is allowed to rotate along the piston rod in a direction only about the axis of the cannula tubes.
3. Ophthalmic endoscope according to claim 1, wherein the transmission system (127) comprises a helical gear (220, 230, 240).
4. An ophthalmic endoscope according to claim 1, wherein the transmission system (127) comprises a splined gear.
5. Ophthalmic endoscope according to claim 1, wherein the transmission system (127) comprises a bearing
unidirectional (321). 30
6. Ophthalmic endoscope according to claim 1, wherein the engine comprises at least two piston engines.
7. Ophthalmic endoscope according to claim 6, wherein the transmission system (127) couples the movement of the piston to a rotational movement of a shaft using a crankshaft (450).
8. An ophthalmic endoscope according to claim 7, wherein the movement of the piston is parallel to the longitudinal axis of the cannula assembly and the crankshaft is perpendicular to the longitudinal axis in the cannula assembly.
9. An ophthalmic endoscope according to claim 8, wherein the transmission system (127) comprises at least two bevel gears perpendicular to each other to couple the movement of the crankshaft to the inner tube and the outer tube in the cannula assembly.
10. Ophthalmic endoscope according to any of claims 1 to 9, which also includes an outer cannula
45 stationary (120) adapted to provide a protective cover to the cannula assembly (110) comprising an inner tube (130) concentric with an outer tube (140).
ES12712806.4T 2011-03-22 2012-03-21 Pneumatically operated ophthalmic examination endoscope Active ES2542013T3 (en)
US201161466364P true 2011-03-22 2011-03-22
US201161466364P 2011-03-22
PCT/US2012/029909 WO2012129278A2 (en) 2011-03-22 2012-03-21 Pneumatically driven ophthalmic scanning endoprobe
ES2542013T3 true ES2542013T3 (en) 2015-07-29
ES12712806.4T Active ES2542013T3 (en) 2011-03-22 2012-03-21 Pneumatically operated ophthalmic examination endoscope
AU (1) AU2012231026A1 (en)
BR (1) BR112013023099A2 (en)
MX (1) MX2013009998A (en)
WO (1) WO2012129278A2 (en)
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2012-03-21 BR BR112013023099A patent/BR112013023099A2/en not_active IP Right Cessation
2012-03-21 KR KR1020137027831A patent/KR20140013041A/en not_active Application Discontinuation
EP2665450A2 (en) 2013-11-27
BR112013023099A2 (en) 2016-12-06
RU2013146965A (en) 2015-04-27
JP5947368B2 (en) 2016-07-06
US9192515B2 (en) 2015-11-24
WO2012129278A2 (en) 2012-09-27
WO2012129278A3 (en) 2012-12-27
CA2827543A1 (en) 2012-09-27
EP2665450B1 (en) 2015-06-10
JP2014509909A (en) 2014-04-24
CN103442670A (en) 2013-12-11
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MX2013009998A (en) 2013-12-06
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