CN119564401A - Ophthalmic pressure control system, kit of parts and method - Google Patents

Abstract

The present invention relates to an ophthalmic pressure control system, comprising: a pressure regulator having an input port and an output port; and an infusion line having a proximal end and a distal end, the proximal end being connected to the output port of the pressure regulator, and the distal end being detachably connected to an ophthalmic irrigation module. In addition, the system comprises: a control unit driving the pressure regulator to control the infusion fluid pressure at the distal end of the ophthalmic irrigation module. The control unit is arranged to perform a fluid calibration process, the fluid calibration process comprising the step of determining the fluid impedance of the ophthalmic irrigation module. The infusion line is associated with a set of components, the set of components comprising a first ophthalmic irrigation device and a second ophthalmic irrigation device, or the ophthalmic irrigation module is an ophthalmic irrigation device for surgery.

Description

Ophthalmic pressure control system, kit of parts and method

The application is a divisional application with the application date of 2019, 9 and 9, the application number 201910848180.1 and the application name of ophthalmic pressure control system, complete set of parts and method.

Technical Field

The present invention relates to an ophthalmic pressure control system comprising:

The system includes a pressure regulator having an input port and an output port, an infusion line having a proximal end and a distal end, the proximal end being connected to the output port of the pressure regulator and the distal end being removably connected to the ophthalmic irrigation module, and a control unit driving the pressure regulator to control an infusion fluid pressure at the distal end of the ophthalmic irrigation module.

Background

In ophthalmic surgery, a smaller probe is inserted into the eye through an insertion port (e.g., a cannula that passes through the pars plana of the eye) to cut, remove, or otherwise treat tissue. Typically, infusion fluids are used to irrigate the interior of the eye by flowing fluid into the eye through an ophthalmic irrigation module that penetrates the eye. The flush module is supplied by an infusion line that is pressurized by a fluid pressure regulator. During treatment of tissue in the interior of the eye, the amount of fluid exiting the eye via the insertion port may vary over time, e.g., depending on the surgical action.

In prior art systems, the control unit may be used to control the fluid flowing toward the eye, the control unit driving a pressure regulator to control the infusion fluid pressure at the distal end of the ophthalmic irrigation module. The control process may be based on a fluid pressure sensed in the interior of the eye. As an alternative, european patent EP2538900B1 in the name of the same applicant discloses estimating the fluid pressure without using a fluid pressure sensor.

Disclosure of Invention

It is an object of the present invention to provide an ophthalmic pressure control system wherein the process of controlling the infusion fluid pressure at the distal end of the ophthalmic irrigation module is improved. Furthermore, according to the invention, the control unit is arranged for performing a fluid calibration procedure comprising the step of determining a fluid impedance of the ophthalmic irrigation module, wherein the infusion line is associated with a kit of parts comprising a first ophthalmic irrigation device for surgery, the kit of parts further comprising a second ophthalmic irrigation device for calibration, such that the ophthalmic irrigation module detachably connected to the infusion line is the second ophthalmic irrigation device of the kit of parts, or wherein the ophthalmic irrigation module is the ophthalmic irrigation device for surgery.

By performing a calibration procedure, the static and/or dynamic fluid response to the action of the pressure regulator may be evaluated, thereby improving the system to compensate for pressure loss inside the eye due to surgical action in the eye, e.g. in terms of compensation speed and accuracy, e.g. for setting the fluid pressure in the eye to a predefined set point.

According to one aspect of the invention, it is proposed that the fluid impedance of the ophthalmic irrigation module may have a significant contribution to the fluid behavior of the ophthalmic pressure control system due to the relatively small size of the irrigation module. By determining the fluid impedance of the ophthalmic irrigation module, the overall fluid response of the system can be more accurately estimated, further improving the pressure control process.

By using the system according to the invention, the intraocular pressure can be kept stable at the values set by the surgeon, regardless of any surgical procedure.

Furthermore, the kit of parts comprises a first ophthalmic irrigation device for surgery, the kit of parts further comprising a second ophthalmic irrigation device for calibration, such that the ophthalmic irrigation module detachably connected to the infusion line is the second ophthalmic irrigation device of the kit of parts, by associating the infusion line with the kit of parts, the control unit may perform a fluid calibration procedure without being physically connected to the first irrigation device actually used in the surgical procedure, the fluid calibration procedure comprising the step of determining the fluid impedance of the irrigation module. The calibration procedure may then be performed while the first irrigation device for surgery is located elsewhere, e.g., at the surgical site, e.g., penetrating the eye. After the calibration procedure is completed, the second irrigation device for calibration may be replaced with an irrigation device for surgery while the irrigation device for surgery is still in the surgical position, thereby minimizing surgical actions.

Advantageously, the determined fluid impedance may be compared to a plurality of predetermined fluid impedance calibration reference values associated with respective types of ophthalmic irrigation devices. Since ophthalmic irrigation devices used during calibration in practice belong to a group comprising a limited number of device types, the fluid impedance determination may be used to identify the type of device (i.e. the first device) to be used during the surgical procedure, e.g. depending on the geometry and/or size of the device. The fluid impedance calibration reference value may be measured in advance during laboratory conditions and/or using a dedicated measurement sensor, and may be provided with the first device and the second device, e.g. digitally providing a document of the devices. Identification of the head device can then be obtained without the need to determine the fluid impedance very accurately. In principle, even a relatively coarse, inaccurate determination of the fluid impedance of the second device may be used to identify the type of the first device, especially if a comparison with a plurality of predetermined fluid impedance calibration reference values may be performed with positive results under a high probability mechanism. If the fluid impedance value determined during the calibration procedure matches a particular reference value of a plurality of predetermined fluid impedance calibration reference values within a selected probability interval, a positive identification may be made with the type of ophthalmic irrigation device associated with the reference value. Then, upon identifying the type of first device, the identified known fluid impedance information of the first device may be advantageously used to evaluate the static and/or dynamic fluid response to the action of the pressure regulator, even when a relatively comprehensive or coarse determination of the fluid impedance is performed during the calibration process.

The predetermined fluid impedance calibration reference value may be matched to the fluid impedance of the corresponding type of first ophthalmic irrigation device. The first and second ophthalmic irrigation devices of the kit then have the same fluid impedance, and the matched predetermined fluid impedance calibration reference values may be used to evaluate the fluid response.

Optionally, the predetermined fluid impedance calibration reference is different from, but related in a specific way to, the fluid impedance of the corresponding type of first ophthalmic irrigation device. The first and second ophthalmic irrigation devices of the kit then have mutually different fluid impedances, but are mutually related in a specific way. The device type may be determined by determining a fluid impedance of the second ophthalmic irrigation device and associating the determined fluid impedance value of the second device with a corresponding type of the first ophthalmic irrigation device. The step of associating the determined fluid impedance value with the type of the respective first ophthalmic irrigation device may be applied by using information of a relation between the predetermined fluid impedance calibration reference value on the one hand and the fluid impedance of the respective type of the first ophthalmic irrigation device on the other hand. The information may be obtained in any manner (e.g., as a table).

By associating the predetermined fluid impedance calibration reference values with different fluid impedance values of the respective first devices in a specific manner, the fluid impedances of the first and second devices in the kit of parts are different from each other in a specific known manner. The fluid impedance of the second device for calibration may then be set to an impedance mechanism that can be measured quickly, saving calibration time. As an example, the second device of the kit of parts may have a fluid impedance that is significantly lower than the fluid impedance of the first device.

The first ophthalmic irrigation device may include an actuator mechanism, for example, an actuator mechanism including a phacoemulsification needle and cannula, while the second ophthalmic irrigation device is a passive device. However, the first irrigation device may be identical to the second irrigation device, e.g. both devices comprise an actuator mechanism or both devices are passive, e.g. implemented as infusion cannulas.

Optionally, the ophthalmic irrigation module detachably connected to the distal end of the infusion line during calibration is an ophthalmic irrigation device for surgery. Then, even when the device for surgery is located at a site of penetration into the eye, a calibration procedure including a step of determining the fluid impedance of the ophthalmic irrigation module may be performed to probe the device.

Also in this embodiment, the determined fluid impedance may be compared to a plurality of known, predetermined fluid impedance calibration reference values associated with the respective type of ophthalmic irrigation device, thereby relaxing the accuracy requirements for fluid impedance determination.

Furthermore, the invention relates to a kit of parts.

The invention also relates to a method of controlling the pressure of an infusion fluid.

Furthermore, the invention relates to a computer program product. The computer program product may include a storage medium having stored thereon computer-executable instructions. For example, a computer program product may comprise a set of computer executable instructions stored on a data carrier (e.g., a CD or DVD). A set of computer executable instructions that allow a programmable computer to carry out the method as defined above may also be downloaded from a remote server (e.g. over the internet). The computer program product may also include a memory storing computer-executable instructions and a processor coupled to the memory. The processor is capable of executing the computer-executable instructions to perform corresponding operations.

It should be noted that the technical features described above or below may each be embodied independently in a system or method, i.e. isolated from the context in which the feature is described, separated from other features, or combined with only a number of other features described in the context in which the feature is disclosed. Each of these features can also be combined in any combination with any of the other features disclosed.

Drawings

The invention will now be further elucidated on the basis of a number of exemplary embodiments and the accompanying drawings. In the drawings:

FIG. 1 shows a schematic view of an ophthalmic pressure control system according to the present invention, and

Fig. 2 shows a flow chart of the method according to the invention.

It should be noted that the drawings only show preferred embodiments according to the invention. In the drawings, like reference numerals designate identical or corresponding parts throughout the several views.

Detailed Description

Fig. 1 shows a schematic view of an ophthalmic pressure control system 1 according to the present invention. The system 1 includes a fluid pressure regulator 2 having an input port 3 and an output port 4. The system 1 is further provided with an infusion line 5, the infusion line 5 having a proximal end 6 and a distal end 7, the proximal end 6 being connected to the output port 4 of the fluid pressure regulator 2. In the embodiment shown, the distal end 7 of the infusion line 5 is detachably connected to an ophthalmic irrigation device 8. The infusion line 5 may be implemented as a so-called high flow infusion line. Furthermore, the system 1 comprises a control unit 9 driving the fluid pressure regulator 2 for controlling the infusion liquid pressure at the distal end 19 of the ophthalmic irrigation device 8.

During operation of the system 1, the distal end 19 of the ophthalmic irrigation device 8 penetrates the interior of the patient's eye for flowing irrigation fluid into said interior of the eye. By flowing irrigation fluid into the eye, any internal pressure loss in the eye due to surgical actions in the eye can be compensated for. When the fluid pressure regulator 2 is activated, irrigation fluid pressure is applied at the distal end 19 of the ophthalmic irrigation device 8. During operation of the system, the control unit 9 drives the fluid pressure regulator 2 in order to control the infusion fluid pressure at the distal end 19 of the ophthalmic irrigation device 8.

For the purpose of regulating the fluid pressure through the infusion line 5, the fluid pressure regulator 2 may be provided with an infusion bottle feeding the fluid pressure regulator 2, the infusion line 5 via a drip chamber connected to the input port 3 of the fluid pressure regulator 2.

The control unit 9 is further arranged for performing a fluid calibration procedure comprising the step of determining the fluid impedance of the ophthalmic irrigation device 8, such that the control unit may statically and/or dynamically control the infusion fluid pressure at the distal end 19 of the ophthalmic irrigation device 8. By characterizing the fluid impedance of the ophthalmic irrigation device 8, which is provided with an internal channel for flowing irrigation fluid towards the interior of the eye, the static and/or dynamic response of the ophthalmic irrigation device 8 can be predicted, thereby improving fluid pressure control at the distal end of the module during eye surgery. When performing an eye pressure compensation procedure, for example, the fluid system behavior of the calibration system in terms of volume and time, the desired fluid flow characteristics may be set.

In a first embodiment shown in fig. 1, the ophthalmic irrigation device 8 is a passive device having the same fluid impedance as the corresponding ophthalmic irrigation device 10, the ophthalmic irrigation device 10 comprising an actuator mechanism for surgical activity. The actuator mechanism may, for example, comprise a phacoemulsification needle and cannula. The fluid impedance of the irrigation module may depend on the size and/or geometry, e.g., length, diameter, curve, etc., of the fluid channel through the interior of the irrigation module. By using the passive counterparts of the respective ophthalmic irrigation devices 10, the control unit 9 may perform a fluid calibration procedure comprising the step of determining the fluid impedance of the ophthalmic irrigation device 8 without being physically connected to the ophthalmic irrigation device 10 itself. The ophthalmic irrigation device 8 may be used as an analog module adapted to perform a fluid calibration procedure.

In practice, the ophthalmic irrigation device 10 (e.g., phacoemulsification cannula) may reside in a position to penetrate the eye, such as through a cannula present in the conjunctiva/sclera of the eye. The passive counterpart of the active irrigation device may then be detachably connected to the infusion line 5 to perform a calibration procedure, and subsequently the ophthalmic irrigation device 8 may be removed from said infusion line 5, while the ophthalmic irrigation device 10 is subsequently detachably connected to the infusion line 5 for operatively providing the infusion fluid to the interior of the eye in a controlled manner. In other words, the ophthalmic irrigation device 8 detachably connected to the infusion line 5 is replaced by a corresponding ophthalmic irrigation device 10 having the same fluid impedance but comprising an actuator mechanism.

In fig. 1, the ophthalmic irrigation device 8 is connected to the distal end 7 of the infusion line 5, while the ophthalmic irrigation device 10 is not connected. The ophthalmic irrigation device 8 and the ophthalmic irrigation device 10 have the same or similar fluid impedance, as measured from the proximal ends of the ophthalmic irrigation devices 8, 10, thereby forming a set of related ophthalmic modules or kits 11. The kit 11 comprises an ophthalmic irrigation device 10 for surgery, the ophthalmic irrigation device 10 comprising an actuator mechanism, and the kit 11 further comprises an ophthalmic irrigation device 8 for calibration, the ophthalmic irrigation device 8 being implemented as a passive device having the same fluid impedance as the ophthalmic irrigation device 10. The ophthalmic irrigation device 10 is used for surgery, e.g. for placement in or on the eye, while the ophthalmic irrigation device 8, which is used as a simulation module, is used for determining the fluid impedance of the ophthalmic irrigation device 10. The ophthalmic irrigation device 8 may be implemented as a disposable tool (e.g., a dummy cannula) that can be pre-assembled on the distal end 7 of the infusion line 5 as a representative tool of the ophthalmic irrigation device 10. During calibration, the fluid resistance of the ophthalmic irrigation device 8 may be measured. The ophthalmic irrigation device 8 can then be removed and the infusion line 5 can in principle be used for surgery.

Kit of parts may be provided for each gauge of a particular ophthalmic device, e.g., for each cannula gauge. Furthermore, the first device and the second device of each kit have the same or similar fluid impedance, which means that there is a limit to the tolerance of the internal channel geometry of the devices such that the estimated intraocular pressure has a predefined limit.

It should be noted that the ophthalmic irrigation device 10 may also be implemented as a passive device without the need for an actuator, for example, as an infusion cannula inserted into the eye. The ophthalmic irrigation device used during the fluid impedance determination step may then be the same as another ophthalmic irrigation device connected to the distal end of the infusion line after the fluid impedance determination step is completed (i.e., during surgery). In this case, the kit 11 may comprise two identical ophthalmic irrigation devices, namely an ophthalmic irrigation device 10 for performing surgical actions (e.g. for placement in or on the eye), and an ophthalmic irrigation device 8 for determining the fluid impedance of the devices. It should be noted that both identical ophthalmic irrigation devices may be passive, i.e. without any actively driven components or actuator mechanisms, or may be active, i.e. comprise actively driven components or actuator mechanisms.

Thus, the infusion line 5 may be associated with a kit of parts comprising the ophthalmic irrigation device 10 for surgery, the kit of parts further comprising the ophthalmic irrigation device 8 for calibration, the ophthalmic irrigation device 10 and the ophthalmic irrigation device 8 having the same fluid impedance, such that the ophthalmic irrigation module detachably connected to the infusion line 5 is the ophthalmic irrigation device 8 of the kit of parts.

Advantageously, the determined fluid impedance of the ophthalmic irrigation device 8 is compared with a plurality of predetermined fluid impedance calibration reference values reflecting the fluid impedance of the second device and associated with the respective type of ophthalmic irrigation device 10. If a predetermined fluid impedance calibration reference value, which is the same as the determined fluid impedance of the ophthalmic irrigation device 8, can be found within predefined limits, the type of ophthalmic irrigation device 10 is identified and the predetermined fluid impedance calibration reference value can be used to evaluate the static and/or dynamic fluid response to the action of the pressure regulator, even when a relatively comprehensive or rough determination of the fluid impedance is performed during the calibration procedure.

Optionally, the predetermined fluid impedance calibration reference value reflecting the fluid impedance of the ophthalmic irrigation device 8 is different from the fluid impedance of the respective type of ophthalmic irrigation device 10, but is related to said type of ophthalmic irrigation device 10 in a one-by-one correspondence. Further, by determining the fluid impedance of the ophthalmic irrigation device 8 and associating the determined fluid impedance value with the corresponding type of the first ophthalmic device using the above-described correspondence-by-correspondence information obtained in some way (e.g., using a table or algorithm), the device type may be determined. As an example, if the first device impedance is relatively high, the fluid impedance value of the ophthalmic irrigation device 8 is at least one level lower than the fluid impedance value of the ophthalmic irrigation device 10, thereby saving calibration time.

It should be noted that as a further alternative, the determined fluid impedance of the ophthalmic irrigation device 8 is not compared with a predetermined reference value. The determined fluid impedance itself may then be used to evaluate the static and/or dynamic fluid response to the action of the pressure regulator.

In a second embodiment, the ophthalmic irrigation module removably connected to the distal end of the infusion line is an ophthalmic irrigation device 10 for surgery, optionally in a position of eye penetration. The ophthalmic irrigation device 10 may include an actuator mechanism. Then, a calibration procedure including the step of determining the fluid impedance of the ophthalmic irrigation module may be performed with the surgically used ophthalmic irrigation device 10, even when the ophthalmic irrigation device 10 is in a position to penetrate the eye.

Further, for the purpose of identifying the type of device at hand, the determined fluid impedance of the ophthalmic irrigation device 10 may be compared to a plurality of predetermined fluid impedance calibration reference values reflecting the fluid impedance of the device.

Fig. 2 shows a flow chart of the method according to the invention. The method is for controlling an infusion fluid pressure at a distal end of an ophthalmic irrigation module. The method 100 includes providing a fluid pressure regulator having an input port and an output port (step 110), providing an infusion line having a proximal end and a distal end (step 120), the proximal end being connected to the output port of the pressure regulator, removably connecting the distal end of the infusion line to an ophthalmic irrigation module (step 130), providing a control unit (step 140) driving the fluid pressure regulator to infuse fluid pressure at the distal end of the control ophthalmic irrigation module, and performing a fluid calibration procedure (step 150) including the step of determining a fluid impedance of the ophthalmic irrigation module, wherein the infusion line is associated with a kit of parts including a first ophthalmic irrigation device for surgery, the kit of parts further including a second ophthalmic irrigation device for calibration, the first ophthalmic irrigation device and the second ophthalmic irrigation device having the same fluid impedance, such that the ophthalmic irrigation module removably connected to the infusion line is the second ophthalmic irrigation device of the kit of parts, or wherein the ophthalmic irrigation module is the ophthalmic irrigation device for surgery.

The method may further comprise the step of disconnecting the second ophthalmic irrigation device. The second ophthalmic irrigation device may then be replaced by the first ophthalmic irrigation device.

The step of performing the fluid calibration process may be performed using a dedicated hardware structure (such as an FPGA and/or ASIC assembly) that includes the step of determining the fluid impedance of the ophthalmic irrigation module. Additionally, the method may be at least partially performed using a computer program product comprising instructions for causing a processor of a computer system to perform the steps described above. In principle, some steps may be performed on a single processor. It should be noted, however, that at least one step may be performed on a separate processor, for example, the step of determining the fluid impedance of the ophthalmic irrigation module.

The present invention is not limited to the embodiments described herein. It will be appreciated that many variations are possible.

These and other embodiments will be apparent to those skilled in the art and are considered to fall within the scope of the invention as defined in the appended claims. For purposes of clarity and conciseness of description, features are described herein as part of the same or separate embodiments. However, it is to be understood that the scope of the invention may include embodiments having a combination of all or some of the features described.

Claims (7)

1. An ophthalmic pressure control system, comprising: a fluid pressure regulator having an input port and an output port; an infusion line having a proximal end connected to the output port of the pressure regulator and a distal end removably connected to the ophthalmic irrigation module; and a control unit that drives the pressure regulator to control the infusion fluid pressure at the distal end of the ophthalmic irrigation module, Wherein, the control unit is arranged for performing a fluid calibration procedure comprising the step of determining a fluid impedance of the ophthalmic irrigation module, and wherein the ophthalmic irrigation module is an ophthalmic irrigation device for use in surgery. 2. A method of controlling the pressure of an infusion fluid at a distal end of an ophthalmic irrigation module, comprising the steps of: providing a fluid pressure regulator having an input port and an output port; providing an infusion line having a proximal end and a distal end, the proximal end being connected to an output port of the pressure regulator; removably connecting the distal end of the infusion line to the ophthalmic irrigation module; providing a control unit that drives the fluid pressure regulator to control the infusion fluid pressure at the distal end of the ophthalmic irrigation module, and A fluid calibration procedure is performed including the step of determining a fluid impedance of the ophthalmic irrigation module, wherein the ophthalmic irrigation module is an ophthalmic irrigation device for use in surgery. 3. The method of claim 2, further comprising the step of comparing the determined fluid impedance to a plurality of predetermined fluid impedance calibration reference values associated with corresponding types of ophthalmic irrigation devices. 4. The method of claim 3, wherein the predetermined fluid impedance calibration reference value matches the fluid impedance of the corresponding type of ophthalmic irrigation device. 5. The method of claim 3, wherein the predetermined fluid impedance calibration reference value is different from the fluid impedance of the corresponding type of first ophthalmic irrigation device but is related to the fluid impedance of the corresponding type of first ophthalmic irrigation device in a one-to-one correspondence. 6. The method of any one of claims 3-5, further comprising the step of replacing the second ophthalmic irrigation device with the first ophthalmic irrigation device. 7. A computer program product for controlling an infusion fluid pressure at a distal end of an ophthalmic irrigation module, the ophthalmic irrigation module being removably connected to a distal end of an infusion line having a proximal end connected to an output port of a pressure regulator, the computer program product comprising computer readable code for causing a processor to execute steps of performing a fluid calibration process, the fluid calibration process comprising the step of determining a fluid impedance of the ophthalmic irrigation module, wherein the ophthalmic irrigation module is an ophthalmic irrigation device for use in surgery.