字幕表 動画を再生する 英語字幕をプリント This is Video 8 on employing the Medmont E300 Corneal Topographers, Contact Lens Module. Lets open up a patient file, select a Topography. Click on 'Home', and then, 'Contact Lens'. When you first start out select the manufacturers that are available from North America, (or your Country) you'll note the boxes presently checked are all the manufacturers available from North America that have put their Contact Lenses designs into Medmont Studio. You can click 'Ok'. You won't have to open up this manufactures icon unless a new manufacturer has been added to a recent release of the Medmont Studio software. Otherwise you're just going to enter the patient's RX if it isn't already entered in the patient file, so on the main window where you enter patient information, if you punch in your patient Spectacle RX it automatically comes up in the contact lens design window. Next let's select the specific lens we want to fit on this eye. Let's design for this patient a simple Multi Curve that we can get from any lab in the world. Say 'Okay'. The software will then drop a theoretical contact lens on top of your patients eye, and it will default the Base Curve generally very close to Flat K. You will manipulate the contact lens parameters to produce the best possible Fluorescein pattern. And we start by first determining Visible Iris Diameter, and we click on 'Annotate', and then ,Ruler', and measure Visible Iris Diameter. We are getting a close to 12 Millimeter HVID. We'll select to delete that annotation and you can do that by, right-clicking, and then deleting. Next let's pick up the contact lens, and place it some more near the, Geometric Center. So ignore the Placido, and center the contact lens in relationship with the Sclera. So looking at the white of the eye around here and placing your contact lens as it appears centered, not to the Placido Rings that you can see just outside of the lens, but more so to the Iris or Limbus. Next lets choose the lens diameter that we would prefer. In this case we fit the patient with a 9.5. 'Apply'. And click your cursor in the center and measure the Tear Film Clearance, or 'TFC' along the right hand side here. It's indicated to be 24 Microns. For Fluorescein to be seen by the human eye it must be in excess of 20 Microns. In other words, for us to see Fluorescein behind our Slit Lamp, we must have a thickness of Tear Layer and density of Fluorescein Molecules somewhere in the neighborhood of 20 or more Microns. If you want to see a nice even central Fluorescein Pattern on your actual fit you must have a Tear Film Clearance at the Apex of at least 20 Microns. With 24 Microns that would be comfortable, we are looking for somewhere between 20 to 25 on a normal eye. Next take this white axis line and find the point on the graph where the lens seems to land on opposing sides, and it appears that on our , With the Rule Corneal Astigma, this lens lands very close to nine o'clock, and again on its opposing side at three o'clock, so we have Apical Clearance of approximately 24 Microns down to touch at nine o'clock, you see the dotted section of the line here corresponding with the dotted section on the graph, solid section of the line here corresponding solid section there. So we have our 24 Microns Apical Clearance heading down to three o'clock we have our touch and then our edge lift, our Apical Clearance toward nine o'clock, with our edge lift. So this is and ideal relationship to keep the lens on lateral center. Then we take our axis line and drag it to the Vertical Meridian and we can see that this patient has a fair amount of Tear Layer Clearance heading toward twelve and heading toward six o'clock, dotted section of the line here corresponding with the dotted section of the line here, solid section of the line there corresponding with solid section here. If we click our cursor at the edge of the inner pink circle which is the, Optic Zone Junction. we're showing 41 Microns heading North, and 85 Microns heading South, or inferior. This is a significant amount of Inferior Clearance and would likely cause the lens to tilt and rock across the Vertical Meridian because there is excessive lift of the lens at twelve and six o'clock. This is a Fluorescein pattern of the actual lens on eye designed from our Medmont, and you can see that this contact lens has an acceptable level of Apical Clearance. Fluorescein can just be seen under the center of the contact lens, so this is good, we have landing at nine o'clock and landing at three o'clock with a healthy edge lift on both sides. The problem however; is the significant Inferior Lift, and Superior Lift, that's causing the lens to tilt and also ride high. This patient needs a Toric GP Lens. So let's go back to our contact lens and try to better designed it from our Medmont software. Click on 'Display' to bring up the, 'Edit' box again, and select 'Toric'. Now we create two Meridians of Curvature, and 'Apply' that. The same rules apply to the, Toric Contact Lens. We want to create a lens that lands at three and nine o'clock, and lifts at twelve and six o'clock. Presently our contact lens is not landing across the Horizontal Meridian, the Horizontal Meridian, you can also see is our Flat Meridian by that blue line. So let's steepen the Base Curve along the Flat Meridian by a half Diopter step. On the Vertical Meridian, we appear to be very near to bearing or definite bearing at, twelve and six. We want our contact lens to lift so it can freely move with each blink and create a good Tear Pump. So let's flatten the lens across the Steep Meridian so that our contact lens will be able to move with each blink. And click 'Apply'. Now we have a lens that lands at three and nine o'clock and along the Vertical Meridian it lifts at twelve and six o'clock. This would be ideal for a good RGP fit. The last thing that one might do is adjust the, Optic Zone Size, to soften its Peripheral Landing. Notice this narrow, Point of Bearing, and a very steep angle as the lens comes back toward the Cornea and touches. Lets increase the Peripheral Curve Width, reduce the, Optic Zone Size, slightly and see what that does to those Points of Bearing. When we apply notice how you shallow out how that lens comes back towards the Cornea, and creates a much wider softer Area of Bearing. Now here's the actual lens that was fit by these same parameters, and you notice you've got virtually 360 Degrees of alignment, but appears to be a very thin channel at twelve and six o'clock which would allow the lands to freely move with each blink. So the Tear Film definitely shows what appears to be bearing at three and nine o'clock and then that bearing thins out throughout twelve and six o'clock to allow for the lens to freely move in the Vertical Meridian. And we also have much better centration then we had with the Spherical GP Lens. This concludes the section on Using the Contact Lens Module in your Medmont E300 Corneal Topographer