EyeWorld is the official news magazine of the American Society of Cataract & Refractive Surgery.
Issue link: https://digital.eyeworld.org/i/831102
EW GLAUCOMA 74 June 2017 by Tony Realini, MD, MPH period of study, the mean rate of progression was –0.48 dB/year. The data were analyzed to deter- mine which correlated better with visual field progression: the mean of all the Goldmann IOP readings collected during the 5 years of study, or the CLS data collected during the single 24-hour recording session at the end of the 5-year period. "The CLS signal recorded in one session did better than Goldmann tonometry over 5 years," he said. "A single 24-hour recording with the CLS provided a signature that correlated with the rates of visual field progression 5 years prior to its recording better than the mean Goldmann IOP collected over years. "Twenty four-hour recording with the CLS may be useful to iden- tify patients at high risk for progres- sion and may aid in clinical deci- sion-making," Dr. de Moraes said. He cautioned that this was a study of past progression and does not indicate that the CLS data is predictive of future progression, but added, "The results of studies testing its predictive value are pending." Practical applications Virtually every clinical health parameter measured today is done so using equipment and techniques that were unimagined 50 years ago. In contrast, IOP is measured using virtually the same equipment and methods that were in routine use a half-century ago. Given the many known limitations of Goldmann tonometry, there is room for im- provement. The notion that the IOP measurements obtained by different tonometers might provide different levels of information on glaucoma progression risk is intriguing. Future studies may clarify the relative strengths and limitations of these new tonometers, and perhaps— if the data are compelling—one may emerge as the new clinical standard. EW Editors' note: The physicians have no financial interests related to their comments. Contact information de Moraes: demoraesmd@gmail.com Susanna: binsusanna@gmail.com In clinical terms, "IOPcc may be more valuable than Goldmann IOP when assessing the risk of visual field progression in glaucoma pa- tients," Dr. Susanna said. Triggerfish contact lens sensor The Triggerfish contact lens sensor (CLS, Sensimed, Lausanne, Switzer- land) recently gained FDA approval as a tool for continuous IOP mea- surement over a 24-hour period. The device does not strictly measure IOP, but rather detects changes in ocular volume and from these changes infers associated changes in IOP. "The CLS captures continuous structural changes at the corneo- scleral junction that correlate to volume changes that are significant- ly associated with rates of visual field progression," said Gustavo de Moraes, MD, Columbia University, New York. The structural component is crucial, Dr. de Moraes said, because "pressure alone does not explain why people progress. How the eye responds to that pressure, and to changes in pressure, is also import- ant in determining progression risk." He presented the results of a study in which 24-hour CLS record- ing was conducted in 445 eyes of 445 glaucoma patients. These pa- tients had previously completed an average of 10 visual field tests over an average of 5 years preceding their CLS session. The baseline visual field mean deviation of the group was approximately –7 dB, and over the of IOP compensated for corneal biomechanical effects (IOPcc). Bianca Susanna, MB, Uni- versity of California, San Diego, conducted a prospective study evaluating the relationship between IOP measured with a variety of tonometers and the observed rate of visual field progression by standard automated perimetry. In addition to Goldmann applanation tonom- etry (GAT), IOP was collected using the iCare rebound tonometer (RBT, Icare, Raleigh, North Carolina) and the ORA (IOPcc). Over an average of 2.5 years of follow-up, the mean IOP measured by GAT, RBT, and ORA was 14.2 mm Hg, 13.3 mm Hg, and 15.8 mm Hg, respectively. "Mean IOPcc from the ORA had the strongest relationship with visu- al field loss over time," Dr. Susanna said, "and was significantly stronger than the models using IOP from GAT or RBT." In fact, while CH remained significant in models using IOP measurements from RBT (and nearly significant in a GAT model, with a p value of 0.067), CH was not significant in the ORA IOPcc model. This suggests that IOP and CH each contain independently relevant in- formation about visual field progres- sion risk, and that the ORA IOPcc measurement (but not IOP from GAT or RBT) might be considered an aggregate measure that incorpo- rates both the relevant IOP and CH information. I t is well established that IOP is a powerful predictor of glauco- ma progression. For decades, the Goldmann tonometer has remained the clinical standard instrument for measuring IOP. This instrument's shortcomings have been well documented, the most im- portant of which is its susceptibility to measurement error on the basis of structural and biomechanical prop- erties of the cornea, such as central corneal thickness (CCT) and corneal hysteresis (CH). In recent years, innovative new tonometers have been developed, some expressly designed to min- imize these CCT- and CH-related artifacts. Some have the added advantage of being operable by patients for self-tonometry, provid- ing the opportunity for expanded collection of IOP data beyond the standard limits of sporadic office hours measurements. Might one of these new tonom- eters supplant Goldmann tonometry as a better clinical standard? What bar would a new tonometer have to clear in order to drive a paradigm shift in IOP measurement tech- nique? At the 2017 American Glaucoma Society annual meeting in Coro- nado, California, several glaucoma specialists presented data suggesting that new tonometers may provide better IOP information than Gold- mann tonometry—specifically that IOP measurements with some of the new tonometers may correlate better with glaucoma progression risk than Goldmann tonometry. Ocular Response Analyzer and IOPcc The Ocular Response Analyzer (ORA, Reichert Technologies, Depew, New York) operates as a non-contact tonometer, applying a metered jet of air to the corneal surface and mea- suring the pressure at two applana- tion points: one as the jet is increas- ing in pressure, and another as the jet of air is decreasing in pressure and the cornea returns to its resting configuration. The instrument mea- sures a Goldmann equivalent IOP (IOPg), corneal hysteresis (CH)—a measure of the viscoelastic proper- ties of the cornea—and an estimate Evolution of tonometry: Are we overdue for a new clinical standard? Presentation spotlight " Pressure alone does not explain why people progress. How the eye responds to that pressure, and to changes in pressure, is also important in determining progression risk. " —Gustavo de Moraes, MD