JPWO2020006169A5 - - Google Patents

Description

The above description is intended to be exemplary rather than limiting. For example, the examples described above (or one or more embodiments thereof) can be used in combination with each other. Other embodiments may be used by those skilled in the art who have considered the above description. The abstract is provided in accordance with US Patent Law Enforcement Rule 1.72 (b) so that the reader can quickly identify the nature of the Technical Disclosure. The abstract is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. Further, in the above detailed description, various features may be grouped together in order to simplify the present disclosure. This should not be construed as intended that the unclaimed disclosed features are essential to any claim. Rather, the subject matter of the invention may be features that are less than all of the particular disclosed embodiments. Therefore, the following claims are incorporated into the detailed description as examples or embodiments, each claim is self-sustaining as a separate embodiment, and these embodiments can be combined with each other in various combinations or substitutions. Is intended. The scope of the invention should be determined by reference to the appended claims, along with the full scope of equivalents to which such claims are entitled.
The technical ideas contained in this disclosure are described below.
(Appendix 1)
It ’s a device,
With the left cover, which is sized and shaped to fit over the left eye so as to define the left cavity between the left cover and the anterior surface of the patient's left eye.
A left pressure source configured to communicate with the left cavity and regulate the fluid pressure in the left cavity.
With the right cover, which is sized and shaped to fit over the right eye so as to define the right cavity between the right cover and the anterior surface of the patient's right eye.
A right pressure source configured to communicate with the right cavity and regulate the fluid pressure in the right cavity.
A control circuit connected to at least one of the left pressure source and the right pressure source, wherein the system control circuit is such that the left pressure source is independent of the right pressure source and the fluid pressure in the left cavity. The apparatus comprising the control circuit, the right pressure source being configured to be able to adjust the fluid pressure in the right cavity independently of the left pressure source.
(Appendix 2)
A left cavity sensor that communicates with the left cavity and detects an index of the left eye environment in the left cavity.
A right cavity sensor that communicates with the right cavity and detects an index of the right eye environment in the right cavity.
With a redundant sensor configured to detect at least one of the left eye environment index, the right eye environment index, and the index of the relationship between the left eye environment index and the right eye environment index. ,
The device according to Appendix 1, comprising a system sensor comprising.
(Appendix 3)
The left cavity sensor comprises a left pressure sensor that detects an index of left pressure in the left cavity.
The right cavity sensor comprises a right pressure sensor that detects an index of right pressure in the right cavity.
The device according to Appendix 2, wherein the redundant sensor includes a redundant sensor that detects an index of the relationship between the index of the left eye environment and the index of the right eye environment.
(Appendix 4)
The redundant sensor is configured to detect the difference between the index of the left pressure in the left cavity by the left differential pressure sensor and the index of the right pressure in the right cavity by the right differential pressure sensor. The device according to Appendix 2, which includes a sensor.
(Appendix 5)
Difference configured such that the redundant sensor detects the difference between the index of left pressure from the left cavity sensor by the left differential signal sensor and the index of right pressure from the right cavity sensor by the right differential signal sensor. The device according to Appendix 2, which includes a dynamic signal sensor.
(Appendix 6)
The system control circuit is at least one of an index of the left eye environment in the left cavity, an index of the right eye environment in the right cavity, and an index of the relationship between the left eye environment and the right eye environment. The device according to Appendix 2, which is configured to receive and process one.
(Appendix 7)
The system control circuit
A left control circuit coupled to the left pressure source and capable of receiving and processing at least one of the indicators of the left eye environment and the relationship between the left eye environment and the right eye environment.
A right control circuit capable of communicating with the right pressure source and receiving and processing at least one of the indicators of the right eye environment and the relationship between the left eye environment and the right eye environment. The device according to Appendix 6, which includes.
(Appendix 8)
The left control circuit comprises a left control circuit configured to adjust the left pressure source to generate a non-atmospheric pressure in the left cavity towards the left target cavity pressure in the left cavity.
Addendum, the right control circuit comprises a right control circuit configured to adjust the right pressure source to generate a non-atmospheric pressure in the right cavity towards the right target cavity pressure in the right cavity. 7. The device according to 7.
(Appendix 9)
Left configured to communicate with the left control circuit and detect at least one of the index of left intraocular pressure (IOP) in the left eye and the index of cerebrospinal fluid pressure (CSFP) in the patient. With a biosensor
7. Addition 7 comprising a right biosensor configured to communicate with the right control circuit and detect at least one of the index of right IOP in the right eye and the index of CSFP in the patient. Equipment.
(Appendix 10)
The left control circuit receives the index of the left IOP and adjusts the left pressure source so as to generate a non-atmospheric pressure toward the left target IOP level [G] based on the received index of the left IOP. Including the left control circuit configured in
The right control circuit receives the index of the right IOP and adjusts the right pressure source to generate a non-atmospheric pressure toward the right target IOP level [G] based on the received index of the right IOP. 9. The apparatus according to Appendix 9, which comprises a right control circuit configured in.
(Appendix 11)
The left control circuit configured to generate non-atmospheric pressure towards the left target IOP level comprises the left target IOP level in the range of about 10 mmHg to about 21 mmHg in the left eye.
The right control circuit configured to generate non-atmospheric pressure towards the right target IOP level includes the right target IOP level in the range of about 10 mmHg to about 21 mmHg in the right eye, according to Appendix 10. Equipment.
(Appendix 12)
The left control circuit adjusts the left pressure source to generate non-atmospheric pressure in the left cavity so as to equalize the index of the left transsieving plate pressure gradient (TLPG) associated with the left eye. Equalizing the index of the left TLPG, including the left control circuit configured as described above, comprises reducing the index of the left TLPG from a first left TLPG level to a lower second left TLPG level.
The right control circuit is configured to adjust the right pressure source to generate non-atmospheric pressure in the right cavity so as to equalize the index of the right TLPG associated with the right eye. 9. The apparatus according to Appendix 9, wherein equalizing the index of the right TLPG reduces the index of the right TLPG from a first right TLPG level to a lower second right TLPG level.
(Appendix 13)
The left control circuit is configured to adjust the left pressure source to generate non-atmospheric pressure in the left cavity so as to improve the index of axonal transport in the left optic nerve of the left eye. Including the circuit
The right control circuit is configured to adjust the right pressure source to generate non-atmospheric pressure in the right cavity so as to improve the index of axonal transport in the right optic nerve of the right eye. Including the circuit
The apparatus according to Appendix 9, wherein improving the index of axonal transport increases the speed of axonal transport from a first axonal transport level to a higher second axonal transport level.
(Appendix 14)
The left control circuit is configured to adjust the left pressure source to generate non-atmospheric pressure in the left cavity so as to treat, suppress or prevent the eye disease of the left eye. Including,
The right control circuit is configured to adjust the right pressure source to generate non-atmospheric pressure in the right cavity so as to treat, suppress or prevent the eye disease of the right eye. The device according to Appendix 9, including.
(Appendix 15)
A left passive cavity check valve that communicates with the left cavity and is configured to limit the left pressure in the left cavity to the left cracking pressure, and a right pressure in the right cavity that communicates with the right cavity. The device according to Appendix 1, comprising a right passive cavity check valve configured to limit the cracking pressure.
(Appendix 16)
The left, which is a method of using the device and is sized and shaped such that the device fits over the left eye so as to define a left cavity between the left cover and the anterior surface of the patient's left eye. Said to define the right cavity between the cover, the left pressure source configured to communicate with the left cavity and regulate the fluid pressure in the left cavity, and the right cover and the anterior surface of the patient's right eye. A right cover sized and shaped to fit over the right eye and a right pressure source configured to communicate with the right cavity and adjust the fluid pressure in the right cavity, said left pressure. The source is configured to adjust the fluid pressure in the left cavity independently of the right pressure source, and the right pressure source adjusts the fluid pressure in the right cavity independently of the left pressure source. In the above method configured as
With the device, an index of the left eye environment, an index of the right eye environment, an index of the left intraocular pressure (IOP) in the left eye, an index of the right IOP in the right eye, and a cerebrospinal fluid pressure in the patient (the index of the cerebrospinal fluid in the patient). The step of receiving at least one of the indicators of CSFP) and
The left pressure source to generate non-atmospheric pressure in the left cavity based on at least one of the received indicators, and the right cavity based on at least one of the received indicators. A method comprising: adjusting at least one of the right pressure sources to generate non-atmospheric pressure within.
(Appendix 17)
The step of receiving the index comprises receiving the index of the left eye environment including the index of the left pressure source, and the step of adjusting the pressure source adjusts the left pressure source based on the index of the left cavity pressure. Including doing
The step of receiving the index comprises receiving the index of the right eye environment including the index of the right pressure source, and the step of adjusting the pressure source adjusts the right pressure source based on the index of the right cavity pressure. The method according to Appendix 16, which comprises the above.
(Appendix 18)
The step of receiving the index comprises receiving the index of the left IOP, and the step of adjusting the pressure source comprises adjusting the left pressure source based on the index of the left IOP.
16. Addition 16, wherein the step of receiving the index comprises receiving the index of the right IOP, and the step of adjusting the pressure source comprises adjusting the right pressure source based on the index of the right IOP. the method of.
(Appendix 19)
The step of receiving the index comprises receiving the index of the left cavity pressure and the left IOP, and the step of adjusting the pressure source adjusts the left pressure source based on the index of the left cavity pressure and the left IOP. Including that
The step of receiving the index comprises receiving the index of the right cavity pressure and the right IOP, and the step of adjusting the pressure source adjusts the right pressure source based on the index of the right cavity pressure and the right IOP. The method according to Appendix 16, including the above.
(Appendix 20)
The step of receiving the index comprises receiving the index of the left transsieving plate pressure difference (TPD) associated with the left eye, and the step of adjusting the pressure source equalizes the index of the left TPD. Including adjusting the left pressure source
The step of receiving the index comprises receiving the index of the right TPD associated with the right eye, and the step of adjusting the pressure source adjusts the right pressure source so that the index of the right TPD is equalized. Including doing
16. The method of Appendix 16, wherein equalizing the TPD index comprises reducing the TPD index from a first TPD level to a lower second TPD level.
(Appendix 21)
A device that regulates fluid pressure applied to at least one of a left cavity located above a patient's left eye and a right cavity located above the patient's right eye to treat, suppress or prevent eye disease. And
The relationship between the index of the left eye environment communicating with the left cavity and the right cavity and the index of the left eye environment in the left cavity, the index of the right eye environment in the right cavity, and the index of the left eye environment and the index of the right eye environment. A differential sensor configured to detect at least one of the indicators of
An index of the left eye environment in the left cavity, an index of the right eye environment in the right cavity, and an index of the relationship between the index of the left eye environment and the index of the right eye environment communicating with the system sensor. A device comprising a control circuit configured to receive and process at least one of these.
(Appendix 22)
A left cavity sensor coupled to the system control circuit and detecting an index of the left eye environment in the left cavity, and a right coupled to the system control circuit and detecting an index of the right eye environment in the right cavity. 21. The apparatus of Appendix 21, comprising at least one of the cavity sensors.
(Appendix 23)
The differential sensor detects the difference between the index of the left pressure in the left cavity detected by the left differential pressure sensor and the index of the right pressure in the right cavity detected by the right differential pressure sensor. 21. The apparatus of Appendix 21, comprising a differential pressure sensor configured as described above.
(Appendix 24)
The differential sensor detects the difference between the index of the left pressure from the left pressure sensor detected by the left differential signal sensor and the index of the right pressure from the right pressure sensor detected by the right differential signal sensor. 21. The apparatus of Appendix 21, comprising a differential signal sensor configured as described above.
(Appendix 25)
21. The apparatus of Appendix 21 comprising a pressure source that communicates with at least one of the left cavity and the right cavity and is configured to apply non-atmospheric pressure to at least one of the left cavity and the right cavity.
(Appendix 26)
25. The apparatus of Appendix 25, wherein the pressure source comprises a pressure source configured to apply non-atmospheric pressure to the left cavity and the right cavity.
(Appendix 27)
A left cavity valve configured to communicate with the left cavity and adjust the index of the left pressure in the left cavity.
22. The apparatus of Appendix 22 comprising a right cavity valve that communicates with the right cavity and is configured to adjust the index of the right pressure in the right cavity.
(Appendix 28)
27. The apparatus of Appendix 27, wherein the left valve comprises at least one of a passive left valve and an active left valve, and the right valve comprises at least one of a passive right valve and an active right valve.
(Appendix 29)
The right cavity valve comprises an active left cavity valve configured to adjust the left pressure index based on at least one of the indicators received by the system control circuit. 28. The apparatus of Appendix 28, comprising an active right cavity valve configured to adjust the right pressure index based on at least one of the indexes received by the system control circuit.
(Appendix 30)
Left configured to communicate with the system control circuit and detect at least one of the index of left intraocular pressure (IOP) in the left eye and the index of cerebrospinal fluid pressure (CSFP) in the patient. With a biosensor
A right biosensor configured to communicate with the system control circuit and detect at least one of the index of the right IOP in the right eye and the index of CSFP in the patient.
The right cavity valve comprises an active left cavity valve configured to adjust the index of the left pressure based on at least one of the indicators received from the left biosensor. 27. The apparatus of Appendix 27, comprising an active right cavity valve configured to adjust the index of right pressure based on at least one of the indicators received from the right biosensor.
(Appendix 31)
The system control circuit is configured to receive the left IOP index and adjust the left pressure in the left cavity towards the left target IOP level by the active left valve based on the received left IOP index. Including the left control circuit
The system control circuit is configured to receive the index of the right IOP and adjust the right pressure in the right cavity towards the right target IOP level by the active right valve based on the received index of the right IOP. The device according to Appendix 30, comprising the right control circuit.
(Appendix 32)
The system control circuit was configured to regulate the left pressure in the left cavity by the left active valve so as to equalize the index of left transsieving plate pressure difference (TPD) associated with the left eye. Equalizing the index of the left TPD, including the left control circuit, comprises reducing the index of the left TPD from a first left TPD level to a lower second left TPD level.
The system control circuit includes a right control circuit configured to regulate the right pressure in the right cavity by the right active valve so as to equalize the index of the right TPD associated with the right eye. 30. The apparatus of Addendum 30, comprising equalizing the index of the right TPD to lowering the index of the right TPD from a first right TPD level to a lower second right TPD level.
(Appendix 33)
The system control circuit includes a left control circuit configured to regulate the left pressure in the left cavity with the left active valve sufficient to improve the index of axonal transport in the left optic nerve of the left eye. ,
The system control circuit includes a right control circuit configured to regulate the right pressure in the right cavity with the active right valve sufficient to improve the index of axonal transport in the right optic nerve of the right eye. ,
30. The apparatus of Appendix 30, wherein improving the index of axonal transport increases the speed of axonal transport from a first axonal transport level to a higher second axonal transport level.
(Appendix 34)
The system control circuit includes a left control circuit configured to regulate the left pressure in the left cavity by the active left valve so as to treat, suppress or prevent the eye disease of the left eye.
Appendix 30, wherein the system control circuit comprises a right control circuit configured to regulate the right pressure in the right cavity by the active right valve so as to treat, suppress or prevent the eye disease of the right eye. The device described.
(Appendix 35)
A passive left valve that communicates with the left cavity and is configured to limit the left pressure in the left cavity to the left cracking pressure, and a passive left valve that communicates with the right cavity and limits the right pressure in the right cavity to the right cracking pressure. 21. The device of Appendix 21 comprising a passive right valve configured to limit.
(Appendix 36)
A method using a device, wherein the device communicates with a left cavity and detects an index of left pressure in the left cavity, a left pressure sensor, communicates with a right cavity and an index of right pressure in the right cavity. A system configured to communicate with the system sensor and receive and process at least one of the left pressure index and the right pressure index with a system sensor including a right pressure sensor and a redundant sensor to detect. In the above method, the method comprising a control circuit, an active left valve communicating with the left cavity and communicating with the system control circuit, and an active right valve communicating with the right cavity and communicating with the system control circuit.
A step of detecting the index of the left pressure in the left cavity and the index of the right pressure in the right cavity by the system sensor.
A method comprising the step of adjusting at least one of the active left valve based on the detected left pressure index and the active right valve based on the detected right pressure index. (Appendix 37)
The device communicates with the system control circuit and detects at least one of the index of left intraocular pressure (IOP) in the left eye and the index of cerebrospinal fluid pressure (CSFP) in the patient. The left biosensor configured to communicate with the system control circuit and detect at least one of the index of the right IOP in the right eye and the index of CSFP in the patient. Including and
The active left valve, and the right biosensor, in which the step of adjusting at least one of the active left valve and the active right valve is based on at least one of the indicators received from the left biosensor. 36. The method of Appendix 36, comprising adjusting at least one of the active right valves based on at least one of the indicators received from. (Appendix 38)
The active left valve, such that the step of adjusting at least one of the active left valve and the active right valve changes the left pressure toward the left target IOP level based on the received index of the left IOP. 37. The method of Appendix 37, comprising adjusting at least one of the active right valves to change the right pressure towards the right target IOP level based on the received right IOP index.
(Appendix 39)
The active left valve, and the active left valve, so that the step of adjusting at least one of the active left valve and the active right valve equalizes the index of the left transsieving plate pressure difference (TPD) associated with the left eye. Including adjusting at least one of the active right valves to equalize the index of right transsieving plate pressure difference (TPD) associated with the right eye.
37. The method of Appendix 37, wherein equalizing the TPD index comprises reducing the TPD index from a first TPD level to a lower second TPD level.
(Appendix 40)
The step of adjusting at least one of the active left valve and the active right valve achieves sufficient left pressure in the left cavity to improve the index of axonal transport in the left optic nerve of the left eye. Adjust at least one of the active right valve to achieve a right pressure in the right cavity that is sufficient to improve the index of axonal transport in the active left valve and the right optic nerve of the right eye. Including doing
37. The method of Appendix 37, wherein improving the index of axonal transport increases the speed of axonal transport from a first axonal transport level to a higher second axonal transport level.
(Appendix 41)
A device that limits the level of fluid pressure applied to a patient's left and right eyes.
A pressure source configured to communicate with the left cavity located above the left eye and the right cavity located above the right eye and to adjust the index of fluid pressure in the left cavity and the right cavity.
The index of the left eye environment communicating with the left cavity and the right cavity and in the left cavity, the index of the right eye environment in the right cavity, and the index of the left eye environment and the index of the right eye environment. A device comprising a differential sensor configured to detect at least one of the indicators of the relationship.
(Appendix 42)
A left cavity sensor coupled to the left cavity and detecting an index of the left eye environment in the left cavity, and a right cavity sensor coupled to the right cavity and detecting an index of the right eye environment in the right cavity. The device according to Appendix 41, comprising at least one of the above.
(Appendix 43)
The differential sensor detects the difference between the index of the left pressure in the left cavity detected by the left differential pressure sensor and the index of the right pressure in the right cavity detected by the right differential pressure sensor. 41. The device of Appendix 41, comprising a differential pressure sensor configured as described above.
(Appendix 44)
The difference configured such that the differential sensor detects the difference between the index of left pressure from the left cavity sensor by the left differential signal sensor and the index of right pressure from the right pressure sensor by the right differential signal sensor. The device according to Appendix 41, which includes a dynamic signal sensor.
(Appendix 45)
Communicating with the pressure source, the index of the left eye environment in the left cavity, the index of the right eye environment in the right cavity, and the relationship between the index of the left eye environment and the index of the right eye environment. 41. The apparatus of Appendix 41, comprising a system control circuit configured to receive and process at least one of the indicators.
(Appendix 46)
The index of the left eye environment includes an index of the left pressure in the left cavity, the index of the right eye environment includes an index of the right pressure in the right cavity, and the left eye environment and the right eye environment. 45. The apparatus according to Appendix 45, wherein the index of the relationship includes an index of the difference between the index of the left pressure and the index of the right pressure.
(Appendix 47)
25. The apparatus of Appendix 45, wherein the system control circuit comprises a pressure source circuit configured to adjust the operation of the pressure source based on at least one of the received indicators.
(Appendix 48)
47. The apparatus of Appendix 47, wherein the pressure source circuit comprises a pressure source logic circuit configured to cause a system failure based on at least one of the received indicators.
(Appendix 49)
The pressure source circuit is configured to cause the system failure if the left pressure index exceeds the left pressure safety level or at least one of the right pressure indicators exceeds the right pressure safety level. The device according to Appendix 8, which includes a pressure source circuit.
(Appendix 50)
The index of the relationship between the left eye environment and the right eye environment includes an index of the difference between the index of the left pressure and the index of the right pressure.
Addendum, the pressure source circuit comprises the pressure source circuit configured to cause the system failure if the indicator of the difference exceeds the pressure difference safety level between the left pressure and the right pressure. 48.
(Appendix 51)
A left valve that communicates with the left cavity and limits the fluid pressure in the left cavity to the left pressure safety level, and a fluid pressure that communicates with the right cavity and limits the fluid pressure in the right cavity to the right pressure safety level. 41. The apparatus of Appendix 41, comprising a right valve configured to limit to. (Appendix 52)
The device according to Appendix 51, wherein at least one of the left safety pressure level and the right safety pressure level is in the range of about -50 mmHg to about 50 mmHg gauge.
(Appendix 53)
The device according to Appendix 51, wherein at least one of the left pressure safety level and the right pressure safety level is in the range of about -35 mmHg to about 35 mmHg gauge.
(Appendix 54)
51. The apparatus of Appendix 51, wherein at least one of the left valve and the right valve comprises a passive valve.
(Appendix 55)
51. The apparatus of Appendix 51, wherein at least one of the left valve and the right valve comprises an active valve.
(Appendix 56)
A method of using the device, wherein the device communicates with a left cavity located above the patient's left eye and a right cavity located above the patient's right eye, and a left eye within the left cavity. A left cavity sensor that detects an index of the environment, a right cavity sensor that detects an index of the right eye environment in the right cavity, and a redundancy that detects the relationship between the index of the left eye environment and the index of the right eye environment. In the method described above, the method comprising a system sensor including a sensor.
The step of detecting the index of the left pressure in the left cavity and the index of the right pressure in the right cavity by the system sensor, and
A method comprising limiting the pressure applied to the left cavity and the right cavity by the pressure source.
(Appendix 57)
The device comprises at least one of a left passive valve communicating with the left cavity and a right passive valve communicating with the right cavity.
58. The method of Appendix 56, wherein the pressure limiting step comprises selecting at least one of the left cracking pressure of the left passive valve and the right cracking pressure of the right passive valve.
(Appendix 58)
The device comprises at least one of a left active valve communicating with the left cavity and a right active valve communicating with the right cavity.
The pressure limiting step opens at least one of the left active valve and the right active valve based on at least one of the detected left pressure index and the detected right pressure index. The method according to Appendix 56, including.
(Appendix 59)
Opening at least one of the left active valve and the right active valve is the left active valve and the right active based on the difference between the detected left pressure index and the detected right pressure index. 58. The method of Appendix 58, comprising opening at least one of the valves.
(Appendix 60)
58. The method of Appendix 56, wherein the pressure limiting step comprises adjusting the operation of the pressure source based on at least one of the detected left pressure index and the detected right pressure index.

Claims (15)

It ’s a device,
With the left cover, which is sized and shaped to fit over the left eye so as to define the left cavity between the left cover and the anterior surface of the patient's left eye.
A left pressure source configured to communicate with the left cavity and regulate the fluid pressure in the left cavity.
With the right cover, which is sized and shaped to fit over the right eye so as to define the right cavity between the right cover and the anterior surface of the patient's right eye.
A right pressure source configured to communicate with the right cavity and regulate the fluid pressure in the right cavity.
A system control circuit connected to at least one of the left pressure source and the right pressure source, wherein the left pressure source is independent of the right pressure source and the fluid in the left cavity. The system control circuit is configured such that the pressure can be adjusted and the right pressure source can adjust the fluid pressure in the right cavity independently of the left pressure source. Device. A left cavity sensor that communicates with the left cavity and detects an index of the left eye environment in the left cavity.
A right cavity sensor that communicates with the right cavity and detects an index of the right eye environment in the right cavity.
With a redundant sensor configured to detect at least one of the left eye environment index, the right eye environment index, and the index of the relationship between the left eye environment index and the right eye environment index. ,
The device according to claim 1, further comprising a system sensor including. The left cavity sensor comprises a left pressure sensor that detects an index of left pressure in the left cavity.
The right cavity sensor comprises a right pressure sensor that detects an index of right pressure in the right cavity.
The apparatus according to claim 2, wherein the redundant sensor includes a redundant sensor that detects an index of a relationship between the index of the left eye environment and the index of the right eye environment. The redundant sensor is configured to detect the difference between the index of the left pressure in the left cavity by the left differential pressure sensor and the index of the right pressure in the right cavity by the right differential pressure sensor. The device of claim 2, comprising a sensor. Difference configured such that the redundant sensor detects the difference between the index of left pressure from the left cavity sensor by the left differential signal sensor and the index of right pressure from the right cavity sensor by the right differential signal sensor. The device according to claim 2, comprising a dynamic signal sensor. The system control circuit is at least one of an index of the left eye environment in the left cavity, an index of the right eye environment in the right cavity, and an index of the relationship between the left eye environment and the right eye environment. The device according to claim 2, which is configured to receive and process one. The system control circuit
A left control circuit coupled to the left pressure source and capable of receiving and processing at least one of the indicators of the left eye environment and the relationship between the left eye environment and the right eye environment.
A right control circuit capable of communicating with the right pressure source and receiving and processing at least one of the indicators of the right eye environment and the relationship between the left eye environment and the right eye environment. The device of claim 6, including. The left control circuit comprises a left control circuit configured to adjust the left pressure source to generate a non-atmospheric pressure in the left cavity towards the left target cavity pressure in the left cavity.
The right control circuit comprises a right control circuit configured to adjust the right pressure source to generate a non-atmospheric pressure in the right cavity towards the right target cavity pressure in the right cavity. Item 7. The apparatus according to Item 7. Left configured to communicate with the left control circuit and detect at least one of the index of left intraocular pressure (IOP) in the left eye and the index of cerebrospinal fluid pressure (CSFP) in the patient. With a biosensor
7. A claim 7 comprises a right biosensor configured to communicate with the right control circuit and detect at least one of the index of the right IOP in the right eye and the index of CSFP in the patient. The device described. The left control circuit is configured to receive the left IOP index and adjust the left pressure source to generate non-atmospheric pressure towards the left target IOP level based on the received left IOP index. Including the left control circuit
The right control circuit is configured to receive the right IOP index and adjust the right pressure source to generate non-atmospheric pressure towards the right target IOP level based on the received right IOP index. 9. The apparatus of claim 9, comprising the right control circuit. The left control circuit configured to generate non-atmospheric pressure towards the left target IOP level comprises the left target IOP level in the range of about 10 mmHg to about 21 mmHg in the left eye.
10. The right control circuit configured to generate non-atmospheric pressure towards the right target IOP level comprises the right target IOP level in the range of about 10 mmHg to about 21 mmHg in the right eye. The device described. The left control circuit adjusts the left pressure source to generate non-atmospheric pressure in the left cavity so as to equalize the index of the left transsieving plate pressure gradient (TLPG) associated with the left eye. Equalizing the index of the left TLPG, including the left control circuit configured as described above, comprises reducing the index of the left TLPG from a first left TLPG level to a lower second left TLPG level.
The right control circuit is configured to adjust the right pressure source to generate non-atmospheric pressure in the right cavity so as to equalize the index of the right TLPG associated with the right eye. 9. The apparatus of claim 9, wherein equalizing the index of the right TLPG comprises reducing the index of the right TLPG from a first right TLPG level to a lower second right TLPG level. The left control circuit is configured to adjust the left pressure source to generate non-atmospheric pressure in the left cavity so as to improve the index of axonal transport in the left optic nerve of the left eye. Including the circuit
The right control circuit is configured to adjust the right pressure source to generate non-atmospheric pressure in the right cavity so as to improve the index of axonal transport in the right optic nerve of the right eye. Including the circuit
The apparatus according to claim 9, wherein improving the index of axonal transport increases the speed of axonal transport from a first axonal transport level to a higher second axonal transport level. The left control circuit is configured to adjust the left pressure source to generate non-atmospheric pressure in the left cavity so as to treat, suppress or prevent the eye disease of the left eye. Including,
The right control circuit is configured to adjust the right pressure source to generate non-atmospheric pressure in the right cavity so as to treat, suppress or prevent the eye disease of the right eye. The device of claim 9, including. A left passive cavity check valve that communicates with the left cavity and is configured to limit the left pressure in the left cavity to the left cracking pressure, and a right pressure in the right cavity that communicates with the right cavity. The device of claim 1, comprising a right passive cavity check valve configured to limit the cracking pressure.