Ophthalmic laser irradiation apparatus

An ophthalmic laser irradiation apparatus for irradiating a laser beam onto a patient's eye capable of preventing a deviation of an irradiation position of the laser beam due to a change in a pupil (iris), and performing laser irradiation within high precision. The apparatus has an irradiation optical system for irradiating the laser beam onto the eye, an illumination unit, including an illumination light source, in which light intensity of visible illumination light onto the eye is adjustable, a detection unit which detects at least one of a pupil area and a pupil diameter of the eye, a setting unit which sets a reference value of at least one of the pupil area and the pupil diameter, and an informing unit which informs at least one of a detection value of the detection unit along with the set reference value and a comparison result thereof.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an ophthalmic laser irradiation apparatus for irradiating a laser beam onto a patient's eye.

2. Description of Related Art

As an ophthalmic laser irradiation apparatus for irradiating a laser beam onto a patient's eye, for example, there is a corneal laser surgery apparatus which ablates a corneal tissue by irradiating an excimer laser beam and changes corneal curvature to correct a refractive error of the eye. In addition, as the ophthalmic laser irradiation apparatus, there is an apparatus provided with an alignment mechanism for aligning an irradiation position of the laser beam (hereinafter, also simply referred to as an “irradiation position”) with reference to a predetermined position of the eye, and further provided with a tracking mechanism for aligning (moving) the irradiation position even if the eye (an eyeball) moves during operation. Further, as an apparatus provided with those alignment mechanism and tracking mechanism, such an apparatus is proposed that determines the irradiation position with reference to a position (part) relating to a pupil (including an iris which forms the pupil) such as a pupil center position.

The pupil (iris), however, changes (dilates, contracts, and the like) depending on brightness. Further, due to the charge in the pupil (iris), also various positions (parts) such as the pupil center position change (deviate) Therefore, in a case where the irradiation position is determined with reference to the position (part) relating to the pupil (iris), if the pupil (iris) changes, the irradiation position is misaligned, and it causes an error in a post-operative correction result.

SUMMARY OF THE INVENTION

The present invention has been made in view of the above circumstances and an object to overcome the above problems and to provide an ophthalmic laser irradiation apparatus capable of preventing a deviation of an irradiation position of a laser beam due to a change in a pupil (iris), and performing laser irradiation with high precision.

To achieve the objects and in accordance with the purpose of the present invention, an ophthalmic laser irradiation apparatus is provided with an irradiation optical system for irradiating a laser beam onto a patient's eye, an illumination unit, including an illumination light source, in which light intensity of visible illumination light onto the eye is adjustable, a detection unit which detects at least one of a pupil area and a pupil diameter of the eye, a setting unit which sets a reference value of at least one of the pupil area and the pupil diameter, and an informing unit which informs at least one of a detection value of the detection unit along with the set reference value and a comparison result thereof.

In another aspect of the present invention, an ophthalmic laser irradiation apparatus is provided with an irradiation optical system for irradiating a laser bean onto a patient's eye, an illumination unit, including an illumination light source, in which light intensity of visible illumination light onto the eye is adjustable, a detection unit which detects at least one of a pupil area and a pupil diameter of the eye, a setting unit which sets a reference value of at least one of the pupil area and the pupil diameter, and a control unit which controls the illumination unit to adjust the light intensity of the visible illumination light so that a detection value of the detection unit becomes the set reference value.

In another aspect of the present invention, an ophthalmic laser irradiation apparatus is provided with an irradiation optical system for irradiating a laser beam onto a patient's eye, an illumination unit, including an illumination light source, in which light intensity of visible illumination light onto the eye is adjustable, a detection unit which detects at least one of a pupil area and a pupil diameter of the eye, a setting unit which sets a reference value of at least one of the pupil area and the pupil diameter, and a control unit which judges whether a detection value of the detection unit becomes the set reference value and controls laser irradiation based on a judgment result.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

A detailed description of one preferred embodiment of an ophthalmic laser irradiation apparatus consistent with the present invention is provided below with reference to the accompanying drawings.FIG. 1is an external view of a corneas laser surgery apparatus.FIG. 2is a view illustrating respective driving units in the present apparatus.FIG. 3is a schematic configuration of an optical system and a control system in the present apparatus.

An excimer laser source10and the like are included in a main body1of the surgery apparatus. An excimer laser beam emitted from the laser source10is directed to an arm unit2. An observation optical unit5disposed on a tip portion of the arm unit2is provided with a binocular microscope unit3for observing a patient's eye E, an illumination unit4, an eyeball position detection system, and the like. The illumination unit4includes a visible illumination light source41which emits visible light and an infrared illumination light source42which emits infrared light. The light source41is made so that illumination light intensity is adjustable to change a pupil (iris) of the eye E.

The laser beam directed to the arm unit2is directed to the eye E by optical elements (described below) such as mirrors disposed inside. The arm unit2is moved in an X-direction (in a right-and-left direction to an operator) by an X-direction arm driving unit51, and in a Y-direction (in a back-and-forth direction to the operator) by a Y-direction arm driving unit52, respectively. In addition, the observation optical unit5is moved in a Z-direction (in a direction of a laser irradiation optical axis) by a Z-direction driving unit53. Each of the driving units51,52and53consists of a motor, a sliding mechanism, and the like.

A controller6is provided with a joystick7for giving a signal to move the arm unit2in the X- and Y-directions, a switch60for performing alignment in the Z-direction, a switch61for performing ON/CFF switching for automatic alignment, a switch62for switching over from a standby state to a ready (ready for laser irradiation) state, a switch63for adjusting the illumination light intensity of the light source41, a switch64for switching over an automatic mode/a manual mode for the light intensity adjustment of the light source41, and the like. A foot switch8transmits (inputs) a trigger signal for laser emission. A computer9, consisting of a main body90, a monitor91, a keyboard92, a mouse93and the like, inputs various data such as a necessary surgical condition, and performs calculation, display and storing of laser irradiation control data.

Irradiation Optical System

The laser beam emitted from the laser source10is reflected by mirrors11and12, and further reflected by a plane mirror13. The mirror13is moved by a driving unit14in the direction of the arrow indicated inFIG. 3. An image rotator15is rotatably driven by a driving unit16about a central optical axis as the center, and rotates the laser beam about the optical axis. A variable circular aperture unit18, an opening diameter of which is varied by a driving unit19, limits an ablation region. Mirrors17,22and23change the direction of the laser beam. A projecting lens24projects the opening of the aperture unit16onto the cornea Ec of the eye E.

A dichroic mirror25has a property of reflecting the excimer laser bean of 193 nm and transmitting the visible light and the infrared light. The laser beam passed through the projecting lens24is reflected by the dichroic mirror25to be directed to the cornea Ec. L indicates a reference optical axis for the laser irradiation.

Observation System

Above the dichroic mirror25, arranged are a visible fixation lamp26, an objective lens27, a dichroic mirror30having a property of reflecting the infrared light and transmitting the visible light, and the microscope unit3. The operator observes an anterior-segment of the eye E illuminated by the light source41through the microscope unit3.

Eyeball Position Detection System

An image forming lens31, a mirror32, an infrared transmission filter35and a CCD camera33are arranged sequentially on an optical path on a reflecting side of the dichroic mirror30. An image of the anterior-segment of the eye E illuminated by the light source42is picked up by the CCD camera33. An output signal from the CCD camera33is inputted into an image processing unit43. An eyeball position detection system is shared as a pupil diameter detection system.

Control System

A control unit50for controlling the entire apparatus is connected with the laser source10, the controller6, the computer9, an alarm55, and the respective driving units51,52and53. In addition, the output signal from the CCD camera33is inputted into the image processing unit43, and processed information from the image processing unit43is inputted into the control unit50. The control unit50controls to detect a pupil position (eyeball position) and a pupil diameter based on the signal detected by the image processing unit43, and controls the respective driving units51,52and53, and the light source41.

One example of methods of detecting the pupil position and the pupil diameter will be hereinafter described.FIG. 4is a view showing the image of the anterior-segment picked up by the CCD camera33, andFIG. 5is a view showing distribution of light intensity on the line A-A′ inFIG. 4. As shown in via5, since the light intensity at the pupil, the iris and a sclera is different, positions (coordinates) of a pupil edge in a lateral direction may be detected from distribution information on the light intensity on the line A-A′, and its center position (coordinates) maybe further detected from the positions of the pupil edge. In the same way as is described, positions (coordinates) of the pupil edge in a vertical direction may be detected from distribution information on the light intensity on the line B-B′, and its center position (coordinates) may be further detected. Then, from both the center positions, a pupil center position (coordinates) is obtained with reference to a position of an optical axis of the detection system (i.e., the reference optical axis L of the irradiation optical system), which is adjusted to have a predetermined positional relationship on an image-pickup element of the CCD camera33. Incidentally, concerning the lines for detection in the lateral and vertical directions, it is preferable that the distribution information on the light intensity on a plurality of lines are obtained while taking the center of the image-pickup element of the CCD camera33as the center, and averaged. In addition, when the processing time permits, a position of a barycenter of a pupil region may be obtained to be defined as the pupil center position.

Incidentally, the pupil diameter, for example, may be obtained as a distance between the positions of the leftmost edge and the rightmost edge among the positions of the pupil edge detected as above. Alternatively, it may be obtained as a distance between the positions of the uppermost edge and the lowermost edge. In addition, an area of the pupil region may be obtained from the distribution of the light intensity on the eye E.

Next, in the apparatus having the constitution as above, its operation will be described using a flow chart inFIG. 6. The operator inputs various data such as a correction amount of the eye E previously obtained and the surgical condition, by means of the keyboard92. The computer9calculates a corneal ablation amount based on the inputted data to obtain the laser irradiation control data, and transmits the data to the control unit50.

Further, into the computer9, the operator inputs (sets) a desired pupil diameter of the eye E at the time of the laser irradiation (operation), and a permissible range taking the desired pupil diameter as a reference value. As the desired pupil diameter, the pupil diameter obtained by a corneal share measurement apparatus before the operation may be inputted, or a relatively larger pupil diameter may be inputted if the patient places greater importance to night vision. As the desired pupil diameter and the permissible range thereof, various ones are inputted depending on the operator, the surgical condition and the like. For example, assume that the desired pupil diameter is 4 mm, and the permissible range is ±0.5 mm to the desired pupil diameter. Incidentally, the permissible range ray be inputted by the operator together with the desired pupil diameter, or may be set by the apparatus based on the inputted desired pupil diameter. Besides, when the area of the pupil region is to be obtained, a desired pupil area and the permissible range thereof are inputted (set).

Upon completion of preparation for the operation, the arm unit2provided with an irradiation exit of the laser beam is placed above the eye E. Each of the light sources41and42is lit, and the eye E is fixated on the fixation lamp26. At this point, illuminations in an operating room except those in the apparatus may be turned off so that the pupil of the eye E is not affected thereby. The operator observes the anterior-segment or the eye E through the microscope unit3, and moves the observation optical unit5by operating the joystick7and the switch60until the entire pupil becomes identifiable. At this point, the control unit50controls to actuate the respective driving units51,52and53based on the signals from the joystick7and the switch60to move the arm unit2in the X- and Y-directions, and the observation optical unit5in the Z-direction, respectively.

When the pupil of the eye E becomes identifiable and the operator pushes the switch62, the control unit50controls to start detecting the pupil diameter based on the output signal from the CCD camera33, and determine whether or not the pupil diameter of the eye E falls within the permissible range taking the desired pupil diameter as the reference value which is previously set. In a case where the detected pupil diameter does not fall within the permissible range, the alarm55sounds to inform the operator thereof. Also, a detection value of the pupil diameter and the desired pupil diameter (set reference value) are displayed (the permissible range may be further displayed) on the monitor91. This display allows the operator to know whether the pupil diameter of the eye E becomes the desired pupil diameter or not. In a case where the manual mode is selected for the light intensity adjustment of the light source41, the light intensity may be adjusted with the switch63. Besides, a comparison result such as a difference between the detection value of the pupil diameter and the desired pupil diameter (set reference value) may be displayed, and also an instruction on an increase or a decrease in the light intensity may be displayed after a value of the increase or decrease in the light intensity is obtained from the comparison result.

Here, in a case where the automatic mode is selected by the switch64for the light intensity adjustment of the light source41, the control unit50controls to adjust the light intensity of the light source41based on the detected pupil diameter. When the illumination light intensity of the light source41increases, the pupil contracts. To the contrary, when the illumination light intensity decreases, the pupil dilates. Therefore, when the detected pupil diameter is larger than an upper limit value of the permissible range, the illumination light intensity may be adjusted to increase. To the contrary, when the detected pupil diameter is smaller than a lower limit value of the permissible range, the illumination light intensity maybe adjusted to decrease. Incidentally, automatic adjustment of illumination light intensity may be performed until the detected pupil diameter reaches the desired pupil diameter, not until it falls within the permissible range.

When the detected pupil diameter comes to fall within the permissible range, the control unit50controls to inform the operator accordingly by means of the monitor91or the alarm55. Next, the operator further operates the joystick7and the switch60to perform alignment in the X-, Y- and Z-directions so that an unillustrated reticle and the pupil have a predetermined relationship.

The present apparatus is made to be able to perform automatic alignment in the X- and Y-directions based on the detection of the pupil center position by the eyeball position detection system. The automatic alignment is actuated by setting the switch61ON, When the pupil center position becomes detectable by the eyeball position detection system, the control unit50controls the driving units51and52to move the arm unit2in the X- and Y-directions so that the reference optical axis L for the laser irradiation corresponds to the pupil center position.

By pushing the switch62after confirming the completion of the alignment, automatic tracking is actuated to move the arm unit2so that a reference position on the image-pickup element of the CCD camera33(the position of the reference optical axis L) corresponds to the pupil center position. The detected pupil center position is compared with the reference position at all times. When the eye E moves beyond a predetermined permissible range, the control unit50controls to move the arm unit2in the X- and Y-directions based on comparison information so that the pupil center position may fall within the permissible range of the reference position. Incidentally, it is not always necessary that the position of the reference optical axis L corresponds to the pupil center position. It is essential only to store a positional relationship between the position of the reference optical axis L and the pupil center position by pushing the switch62after the pupil center position is aligned to a desired state, and to maintain the positional relationship.

Pushing the switch62brings the laser source10to a state ready to emit the laser beam. When the operator depresses the foot switch8, the control unit50controls the laser source10to emit the laser beam. The emitted laser beam is irradiated onto the cornea Ec for ablation.

Hereinafter, a brief description will be given on corrective surgery by means of the irradiation optical system in the present embodiment. In the case of ablating a myopic spherical component, the control unit50controls to limit the ablation region by the aperture unit18, and sequentially move the mirror13to move (scan) the laser beam in a Gaussian distribution direction. Then, each time the laser beam finishes moving in one direction (one scan), the moving (scanning) direction of the laser beam is changed by rotation of the image rotator15(for example, three directions at intervals of 120°) to ablate the region limited by the aperture unit18approximately uniformly. By performing these processes each time the opening diameter of the aperture unit18is changed sequentially, the spherical component of the cornea Ec, which is deep in the center part and shallow in the peripheral part, may be ablated.

There is a case where the pupil changes also during the laser irradiation (during the operation) due to strain on the patient and the like. Therefore, the control unit50controls to continue the detection of the pupil diameter also during the laser irradiation. In a case where the detected pupil diameter deviates from the permissible range of the desired pupil diameter, the control unit50controls to stop the laser emission from the laser source10(stopping the laser emission includes also a case that a shutter is inserted into an optical path of the irradiation optical system). At the same time, the alarm55gives a warning to the operator. In a case where the automatic mode is selected for the light intensity adjustment, the control unit50controls to automatically adjust the light intensity of the light source41. In a case where the automatic mode is not selected, the monitor91or the alarm informs the operator that the pupil diameter deviates from the permissible range, so that the operator manually adjusts the light intensity based on this information. When the pupil diameter falls within the permissible range, the laser irradiation is made ready again and the operator may resume the laser irradiation with the foot switch8.

As described above, a deviation of the pupil center position which is the reference position of the alignment and the tracking at the time of the laser irradiation is reduced by bringing the pupil diameter of the patient's eye to be a desired length, so that the deviation of the irradiation position is also reduced.

Incidentally, if the pupil diameter does not fall within the permissible range even the light intensity of the light source41is adjusted, the alarm55and the monitor91inform the operator accordingly. In this case, the operator may respond at his/her discretion, for example, by charging the desired pupil diameter, the permissible range thereof.

Various modifications may be applied to the above-described preferred embodiment. For example, instead of the light source41or observation which is used as illumination means for changing the pupil (iris) of the eye E, the fixation lamp26may be employed and the light intensity thereof may be adjusted.

Further, the irradiation optical system may include a mirror (two galvanometers or the like) which scans the laser beam formed into a small spot of 0.1-1.0 mm two-dimensionally in the X- and Y-directions. In this case, the irradiation position may be moved by driving and controlling the scanning mirror. In addition, in the case of the irradiation optical system which includes an aperture unit with a variable opening diameter for limiting the ablation region, the irradiation position may be moved by eccentrically moving an axis of the projecting lens which projects an opening of the aperture unit onto the cornea.

Furthermore, the present invention may apply to any apparatus which determines the irradiation position with reference to the position (part) relating to the pupil (iris), such as an apparatus which performs alignment of the irradiation position based on a contrast between the sclera and the iris (refer to Japanese Patent Application Unexamined Publication No. 2003-505178), and an apparatus which performs alignment of the irradiation position based on a mark previously provided on the eye (iris and the like) (refer to Japanese Patent Application Unexamined Publication No. 2003-511206).