Patient interface for opthalmologic diagnostic and interventional procedures
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61B-013/00
A61B-018/18
A61F-009/009
A61B-003/14
A61F-009/008
A61B-005/00
A61B-018/20
A61B-008/10
출원번호
US-0602496
(2015-01-22)
등록번호
US-9968486
(2018-05-15)
발명자
/ 주소
Gooding, Phillip
Beltran, Christine
Wiltberger, Michael
출원인 / 주소
Optimedica Corporation
대리인 / 주소
Abbott Medical Optics Inc.
인용정보
피인용 횟수 :
0인용 특허 :
42
초록▼
One embodiment is directed to a patient interface system for ophthalmic intervention on an eye of a patient, comprising: a housing; an optical lens coupled to the housing and having a focal axis; a eye surface engagement assembly coupled to the housing and comprising an inner seal having an inner se
One embodiment is directed to a patient interface system for ophthalmic intervention on an eye of a patient, comprising: a housing; an optical lens coupled to the housing and having a focal axis; a eye surface engagement assembly coupled to the housing and comprising an inner seal having an inner seal diameter and being configured to circumferentially engage the eye, an outer seal having an outer seal diameter and being configured to circumferentially engage the eye, and a tissue migration bolster structure configured to be positioned circumferentially between the inner and outer circumferential seals and to prevent migration of tissue of the eye toward the eye surface engagement assembly when a vacuum load is applied within the assembly to cause vacuum engagement of the inner and outer seals against the eye.
대표청구항▼
1. A patient interface system for ophthalmic laser intervention on a patients eye, comprising: an upper portion having a generally cylindrical housing surrounding an aperture and further having a lower end, the upper portion further having an upper end adapted to couple to an ophthalmic laser surger
1. A patient interface system for ophthalmic laser intervention on a patients eye, comprising: an upper portion having a generally cylindrical housing surrounding an aperture and further having a lower end, the upper portion further having an upper end adapted to couple to an ophthalmic laser surgery and imaging system, the upper portion further including an optical lens secured therein having a lower face and a focal axis co-axially aligned with the aperture;a lower portion having a frustoconical housing of a first material surrounding an access aperture and a circular upper seal, the upper seal having two annular seal elements spaced apart to define an annular vacuum space therebetween, the lower portion further having a first set of vacuum lines for transmitting a source of vacuum to the vacuum space, wherein the lower end of the upper portion is sized and shaped to contact the two annular seal elements of the upper seal of the lower portion thus enabling releasable suction engagement of the lower portion to the upper portion when a vacuum is supplied to the vacuum space, the lower portion further having a circular lower seal of a material more flexible than the first material the circular lower seal being secured to a lower end of the frustoconical housing, the lower seal defining a pair of walls spaced apart and defining therebetween an annular vacuum chamber, the lower portion further having a second set of vacuum lines for transmitting the source of vacuum to the vacuum chamber thus enabling releasable suction engagement of the lower seal with a cornea and/or sclera when the vacuum is supplied to the vacuum chamber regardless of whether the upper portion is engaged with the lower portion; andan annular tissue migration bolster ring of a metallic material less flexible than the lower seal material of the lower portion, and positioned between the pair of walls of the lower seal to prevent migration of tissue of the eye toward the patient interface system when a vacuum load is applied within the vacuum chamber,wherein when the upper portion is engaged with the lower portion and the lower portion is engaged with the patient's eye, the aperture in the upper portion is co-axially aligned with the access aperture in the lower portion, the lower face of the optical lens is spaced from the eye and a liquid reservoir is defined between the patients eye, the lower face of the optical lens, and within the frustoconical housing of the lower portion such that when liquid fills the reservoir by gravity it provides an optical interface between the optical lens and the eye. 2. The system of claim 1, wherein the lower housing has a handle projecting radially outward from the frustoconical housing, and the first and second sets of vacuum lines terminate in first and second vacuum ports adjacent the handle. 3. The system of claim 1, wherein an upper end of the lower housing is generally cylindrical. 4. The system of claim 1, wherein the pair of walls of the lower seal is axially spaced so as to define a partial spherical surface to conform to a surface of the eye, and the tissue migration bolster ring also includes a partial spherical surface to conform to the surface of the eye. 5. The system of claim 1, wherein the tissue migration bolster ring comprises a port relief on one side adapted to communicate with the second set of vacuum lines in the lower portion, and also includes an orientation feature that mates with a corresponding feature on the lower portion to indicate a correct orientation of the tissue migration bolster ring relative to the lower portion to ensure communication between the port relief and the second set of vacuum lines. 6. The system of claim 1, wherein one or both of the housings are made of a translucent material to enable light passage therethrough. 7. The system of claim 1, further including a vacuum distribution ring mounted in an upper end of the lower portion configured to transmit a vacuum load from the first set of vacuum lines to the annular vacuum space. 8. The system of claim 1, further including first and second discrete, diametrically-opposed, registration fiducials formed on an inner wall of the frustoconical housing, and a third registration fiducial formed on the inner wall of the frustoconical housing angularly spaced from both of the first and second registration fiducials, the fiducials comprising visible markers that may be imaged by the ophthalmic laser intervention and imaging system. 9. The system of claim 1, wherein the lower portion further defines at least one access port providing open communication between the liquid reservoir and a surrounding atmosphere through which liquid may be easily added to or removed from the liquid reservoir. 10. A patient interface system for ophthalmic laser intervention on an eye of a patient, comprising: an upper portion having a generally cylindrical housing surrounding an aperture and a lower end, the upper portion having an upper end adapted to couple to an ophthalmic laser intervention and imaging system, the upper portion further including an optical lens secured therein having a lower face and a focal axis co-axially aligned with the aperture;a lower portion having a frustoconical housing of a first material surrounding an access aperture and an upper end of the lower portion adapted to releasably engage the lower end of the upper portion, the lower portion further having a circular lower seal of a material more flexible than the first material, the circular lower seal being secured to a lower end of the frustoconical housing, the lower seal defining a pair of walls spaced apart and defining therebetween an annular vacuum chamber, the lower portion further having a set of vacuum lines for transmitting a source of vacuum to the vacuum chamber thus enabling releasable suction engagement of the lower seal with a cornea and/or sclera when a vacuum is supplied to the vacuum chamber regardless of whether the upper portion is engaged with the lower portion; andan annular tissue migration bolster ring of a metallic material less flexible than the lower seal material of the lower portion, and positioned between the pair of walls of the lower seal to prevent migration of tissue of the eye toward the patient interface system when a vacuum load is applied within the vacuum chamber,wherein when upper portion is engaged with the lower portion and the lower portion is engaged with the eye of the patient, the aperture in the upper portion is co-axially aligned with the access aperture in the lower portion, the lower face of the optical lens is spaced from the eye, and a liquid reservoir is defined between the eye, the lower face of the optical lens, and within the frustoconical housing of the lower portion such that when liquid fills the reservoir by gravity it provides an optical interface between the optical lens and the eye, andwherein the lower portion further defines at least one fluid access port providing open communication between the liquid reservoir and a surrounding atmosphere through which liquid may be easily added to or removed from the liquid reservoir. 11. The system of claim 10, wherein the lower housing has a handle projecting radially outward from the frustoconical housing, and the first set of vacuum lines terminates in a vacuum port adjacent the handle. 12. The system of claim 10, wherein the pair of walls of the lower seal is axially spaced so as to define a partial spherical surface to conform to the surface of the eye, and the tissue migration bolster ring also includes a partial spherical surface to conform to a surface of the eye. 13. The system of claim 10, wherein the pair of walls of the lower seal is axially spaced so as to define a partial spherical surface to conform to the surface of the eye, and the tissue migration bolster ring also includes a partial spherical surface to conform to the surface of the eye. 14. The system of claim 10, wherein the tissue migration bolster ring comprises a port relief on one side adapted to communicate with the set of vacuum lines in the lower portion, and also includes an orientation feature that mates with a corresponding feature on the lower portion to indicate a correct orientation of the tissue migration bolster ring relative to the lower portion to ensure communication between the port relief and the set of vacuum lines. 15. The system of claim 10, wherein one or both of the housings are made of a translucent material to enable light passage therethrough. 16. The system of claim 10, further including first and second discrete, diametrically-opposed registration fiducials formed on an inner wall of the frustoconical housing, and a third registration fiducial formed on the inner wall of the frustoconical housing angularly spaced from both of the first and second registration fiducials, the fiducials comprising visible markers that may be imaged by the ophthalmic laser intervention and imaging system. 17. The system of claim 10, wherein there are three fluid access ports. 18. The system of claim 17, wherein the lower housing has a handle projecting radially outward from the frustoconical housing and at least one of the fluid access ports is located adjacent to the handle.
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