This article is the third in a series that highlights the utility and versatility of advanced-technology OVDs (AT-OVDs) in cataract surgery. Here, Hong Kyun Kim, MD, PhD, of Daegu, South Korea, and Tess Huynh, MBBS, FRANZCO, of Liverpool, Australia, discuss which AT-OVDs they prefer in particular surgical situations, and why. To watch related videos, visit Eyetube.net and enter the keyword “Discovisc” in the search bar.
Hong Kyun Kim, md, phd
Arshinoff devised a system of OVD classification that initially divided ophthalmic viscosurgical devices (OVDs) into higher-viscous cohesive agents and lower-viscous dispersive agents based on their physicochemical and rheological properties.1 Cohesive OVDs are made of hyaluronic acid, while dispersive OVDs are usually composed of chondroitin sulfate and hyaluronic acid.
Ever since hyaluronic acid 1% was first used in OVDs, they have become an important surgical device for protecting the corneal endothelium and maintaining adequate space during cataract surgery.2 Hyaluronic acid has a high viscosity with a high molecular weight. Generally, it has excellent characteristics for creating space in the eye and providing a stable surgical environment. Also, cohesive OVDs that contain hyaluronic acid are easier to remove at the end of surgery than dispersive agents. Because phacoemulsification is usually performed under high fluidic turbulence, however, the ability of cohesive OVDs to maintain space and protect the corneal endothelium is quite limited due to rapid removal.
Dispersive OVDs containing mixtures of chondroitin sulfate and hyaluronic acid have a lower viscosity and are molecularly attracted to intraocular tissues with lower surface tension and lower pseudoplasticity. Thus, dispersive OVDs have the optimal characteristics for protecting the corneal endothelium during phacoemulsification. Several studies have demonstrated the protective effect of Viscoat OVD (Alcon Laboratories, Inc.).3-5 However, by itself, Viscoat OVD is not good at creating space in the eye and is not easily removed from the anterior chamber. Arshinoff's soft shell technique,6 which combines use of a cohesive and a dispersive OVD to take advantage of the benefits of each, has been shown to be highly efficacious for maintaining the anterior chamber with the cohesive layer and protecting the corneal endothelium with the dispersive layer. Subsequently, Alcon Laboratories, Inc., created the DuoVisc viscoelastic system, which contains this ideal combination.
Next, Alcon Laboratories, Inc., introduced DisCoVisc OVD, which combines a medium-weight and medium-strength hyaluronic acid with chondroitin sulfate. DisCoVisc OVD has the dispersive characteristics of chondroitin sulfate, but it maintains space in the eye like a traditional cohesive product.7 Due to its rheological properties, DisCoVisc OVD is a powerful space maintainer, yet functions as a retentive endothelial protector during phacoemulsification. At the end of surgery, DisCoVisc OVD exits the eye much more easily than other dispersive OVDs.8
Clinical Test
In a small, experimental laboratory study, my colleagues and I compared the behavior of four types of OVDs: cohesive Healon (Abbott Medical Optics Inc.), dispersive VISCOAT OVD, viscoadaptive Healon5 (Abbott Medical Optics Inc.), and viscodispersive DisCoVisc OVD in a standard porcine cataract surgical model. These data are currently unpublished; however, my colleagues and I are planning a larger study based on the preliminary findings, the results of which will be submitted for publication at a later date.
Space Creating Ability
To compare the space-creating and space-maintaining ability of each OVD, we measured the changes in the anterior chamber depth (ACD) at three time points using immersion A-scan. We recorded the ACD preoperatively and after making the corneal and sideport incisions. We injected each OVD into the anterior chamber through the sideport incision until we observed the outflow of OVD. Then we repeated the A-scan and recorded the results. The difference between each measurement of the ACD reflects the space-creating ability of the OVD. A larger difference in the pre- and post-injection measurements meant better space-creating ability (Figure 1).
When we operate on a patient with a shallow anterior chamber or positive lenticular pressure, such as those with an intumescent cataract, the space-creating ability of a cohesive OVD was very important for preventing unwanted radial capsular tearing. According to the results of our study, DisCoVisc and Healon5 OVDs would be very useful in such cases.
After my colleagues and I measured the ACD a second time, we refilled the anterior chamber with each OVD and performed a continuous curvilinear capsulorhexis in the standard manner. Once the capsulorhexis was completed, we measured the ACD again. The difference between the pre- and post-capsulorhexis measurements reflected the amount of outflow of OVD during this step. The smaller the difference, the safer the capsulorhexis can be performed, especially in eyes with a shallow anterior chamber. According to our results, DisCoVisc OVD showed the least change in ACD. Healon5 was second place, followed by Healon and VISCOAT OVD.
OVD Retention
To protect the corneal endothelium during phacoemulsification, the retention of OVD is very important. Bissen-Miyajima reported in vitro behavior of OVDs during phacoemulsification.9 My colleagues and I modified some aspects of the experiment to achieve results for the OVDs on trial. We performed the capsulorhexis and hydrodissection with the aid of methylcelluose. After completing hydrodissection, we removed the remaining methylcellulose and refilled the anterior chamber with the fluorescein-stained OVD on trial. Then we measured the retention time, defined as the time from the beginning of phacoemulsification to completion of the OVD's aspiration (Figure 2).
Removal Time
Some kinds of OVD are easily removed, but some OVDs resist aspiration. Figure 3 shows the removal time of OVDs, which is defined as the time from the start of OVD aspiration to the time it is fully aspirated. After implanting an IOL, the ease with which we were able to remove the OVDs minimized the risk of leaving any material behind.
Study Conclusions
In our experiment, my colleagues and I confirmed the variable performance of OVDs based on their composition. All of the OVDs have a unique character and special purpose. For example, the dispersive VISCOAT OVD demonstrated a strong coating ability, whereas cohesive OVDs exited the eye easily after surgery.
The results of this study suggest that the choice of an OVD for cataract surgery can be customized to the needs of the case. Challenging cases, such as those with a shallow anterior chamber, a high lenticular pressure, or a very low endothelial cell capacity, will benefit from customizing the type of OVD to the patient's condition. Routine cataract surgeries, however, are suitable for the viscodispersive properties of the DisCoVisc OVD. Although I select an OVD based on the eye's condition, my first choice of OVD in routine cases is DisCoVisc OVD. It is helpful in most cases, and I feel comfortable that the postoperative results will be great.
Clinical Cases
Case 1
A 73-year-old man with uveitic glaucoma presented to our clinic for cataract surgery. He had 20/10 UCVA in the right eye and 20/1000 in the left eye. The nuclear density of his left lens was grade 4 by NOCS II classification. Considering his remnant endothelial cell capacity, I chose to use DisCoVisc OVD. On the first postoperative day, his left eye recovered 20/20 visual acuity. At 1 month, when I compared the serial specular microscopic examination to the preoperative test, the cell density coefficient of variation and hexagonality had not changed.
Even very weak ultrasonic energy can be very dangerous for eyes with very low corneal endothelial cellular reserve like this one. In such cases, the dispersive characteristic of DisCoVisc OVD is very helpful.10,11
Case 2
A 48-year-old male presented with a complicated intumescent cataract in his right eye. Due to swelling of the lens, the anterior chamber was very shallow, and so I decided to use DisCoVisc OVD for its spacecreating ability. Because of the high lenticular pressure, if I did not use a powerful space creator, we would not have been able to control for capsulorhexis tearing. Because the eye had a fibrotic plaque on the posterior capsule, I made a posterior capsulorhexis with the aid of DisCoVisc OVD.
DisCoVisc OVD has very unique and helpful characteristics for cataract surgery. I usually use this combination agent in most of my cataract surgery cases.
Tess Huynh, Mbbs, Fra nzco
As a corneal surgeon, I want to do all I can to protect the corneal endothelium whenever I operate. The low molecular weight and short molecular chain of VISCOAT OVD make it a dispersive viscoelastic. In contrast, DisCoVisc OVD has a zero-shear viscosity that places it in a new class of OVD (viscodispersive), because it features properties of both dispersive and cohesive agents. This advanced-technology (AT) OVD has been shown to have better retention than other OVDs during phacoemulsification,8,12 thereby resulting in better protection of the corneal endothelium.
I continue to use VISCOAT and DisCoVisc OVDs when operating on dense cataracts, because I want corneal protection as well as the availability of a cohesive OVD to assist me through a difficult or complicated cataract extraction, where I may need to tamponade the vitreous or iris. I may even need to add extra endothelial protection with a dispersive OVD if the surgery is taking longer than expected.
A number of recent papers have compared VISCOAT OVD and DisCoVisc OVD to other OVDs on the market.13-15 Apart from the physical protection these agents provide, they also offer inhibitory effects on the formation of free radicals in the eye during surgery, which is another way they protect the endothelium.10,11
Clinical Case
A 57-year-old male presented with an intumescent cataract in his right eye and a traumatic cataract in the left eye. His preoperative visual acuities were hand motions OD and 20/100 (Snellen Chart) OS. I removed the right cataract successfully with my routine phacochop technique using trypan blue dye and DuoVisc OVD containing Viscoat and Provisc OVDs. I then implanted an Acrysof IQ Toric lens (Alcon Laboratories, Inc.), after which the patient saw 20/20 on the first postoperative day. The left eye, however, was a lot more challenging due to two clock hours of zonular dehiscence and vitreous in the anterior chamber. I ensured a generous endothelial coating of Viscoat OVD throughout the procedure. I also placed a capsular tension ring and performed an anterior vitrectomy. I used three sutures to close the 2.2-mm wound. The two sideport incisions I made for the anterior vitrectomy also served to address the eye's pre-existing corneal astigmatism. The patient saw 20/40 on day 1 and 20/25 after I removed his sutures at 1 week.
Hong Kyun Kim, MD, PhD, is an assistant professor and a corneal and cataract surgeon in the department of ophthalmology at Kyungpook Nat'l University in Daegu, South Korea. He has no financial interest in the products or companies mentioned. Dr. Kim may be reached at okeye@hanmir.com.
Tess Huynh, MBBS, FRANZCO, is a refractive, corneal, and cataract surgeon at PersonalEYES and South West Vision Institute in Australia. She has no financial interest in the products or companies mentioned. Dr. Huynh may be reached at tesshuynh@hotmail.com.
- Arshinoff SA. Dispersive and cohesive viscoelastic materials in phacoemulsification. Ophthalmic Pract. 1995;13:98-110 .
- Balazs EA, inventor; Biotrics, Inc., assignee. Ultrapure hyaloronic acid and the use thereof. US patent 4,141,973. October 17, 1979.
- McDermott ML, Hazlett LD, Barrett RP, Lambert RJ. Viscoelastic adherence to corneal endothelium following phacoemulsification. J Cataract Refract Surg. 1998;24:673-683.
- Poyer JF, Chan KY, Arshinoff SA. New method to measure the retention of viscoelastic agents on rabbit corneal endothelial cell line after irrigation and aspiration. J Cataract Refract Surg. 1998;24:84-90.
- Holme´n JB, Lundgren B. Scheimpflug photography study of ophthalmic viscosurgical devices during simulated cataract surgery. J Cataract Refract Surg. 2003;29:568-574.
- Arshinoff SA. Dispersive-cohesive viscoelastic soft shell technique. J Cataract Refract Surg. 1999;25:167-173.
- Petroll WM, Jafari M, Lane S, et al. Quantitive assessment of ophthalmic viscosurgical device retention using in vivo confocal microscope. J Cataract Refract Surg. 2005;31:2363-2368.
- DisCoVisc product insert. Alcon Laboratories, Inc.; Fort Worth, TX.
- Bissen-Miyasima H. In vitro behavior of ophthalmic viscosurgical devices during phacoemulsification. J Cataract Refract Surg. 2006;32:1026-1031.
- Takahashi H, Suzuki H, Shiwa T, Sakamoto A. Alteration of free radical development by OVD in phacoemulsification. J Cataract Refract Surg. 2006;32(9):1545-1548.
- Vasavada A, Ong M, Cordova D, Hartzer M. Protective effect of ophthalmic viscosurgical devices (OVDs) against hydrogen peroxide-induced oxidative damage to corneal endothelial cells: an in-vitro model. Paper presented at: The ASCRS Symposium on Cataract, IOL, and Refractive Surgery; OVD free paper session; April 3-8, 2009; San Francisco, CA.
- Petroll WM, Jafari M, Lane SS, et al. Quantitative Assessment of viscoelastic retention using in vivo confocal microscopy. J Cataract Refract Surg. 2005:31(12):2363-2368.
- Moschos MM, Chatziralli IP, Sergentanis TN. Viscoat versus Visthesia during phacoemulsification cataract surgery: corneal and foveal changes. BMC Ophthalmol. 2011;29(11):9.
- Oshika T, Okamoto F, Kaji Y, et al. Retention and removal of a new viscous dispersive ophthalmic viscosurgical device during cataract surgery in animal eyes. British J Ophthalmol. 2006;90(4):485-487.
- Higashide T, Sugiyama K. Use of viscoelastic substance in ophthalmic surgery - focus on sodium hyaluronate. Clin Ophthalmol. 2008;2(1):21-30.