Corneal pachymetry

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Corneal pachymetry
Pachymeter (by itucker at Flickr).jpg
A typical ultrasound pachymeter

Corneal pachymetry is the process of measuring the thickness of the cornea. A pachymeter is a medical device used to measure the thickness of the eye's cornea. It is used to perform corneal pachymetry prior to refractive surgery, for Keratoconus screening, Cataract, LRI surgery[1] and is useful in screening for patients suspected of developing glaucoma among other uses.

Process[]

It can be done using either ultrasonic or optical methods . The contact methods, such as ultrasound and optical such as confocal microscopy (CONFOSCAN), or noncontact methods such as optical biometry with a single Scheimpflug camera (such as SIRIUS or PENTACAM), or a Dual Scheimpflug camera (such as GALILEI), or Optical Coherence Tomography (OCT, such as Visante) and online Optical Coherence Pachymetry (OCP, such as ORBSCAN). Corneal Pachymetry is essential prior to a refractive surgery procedure for ensuring sufficient corneal thickness to prevent abnormal bulging of the cornea, a side effect known as ectasia.

Pachymeters[]

The instrument used for this purpose is known as a pachymeter. Conventional pachymeters are devices that display the thickness of the cornea, usually in micrometres, when the ultrasonic transducer touches the cornea. Newer generations of ultrasonic pachymeters work by way of Corneal Waveform (CWF). Using this technology, the user can capture an ultra high-definition echogram of the cornea, somewhat like a corneal A-scan. Pachymetry using the corneal waveform process allows the user to more accurately measure the corneal thickness, verify the reliability of the measurements that were obtained, superimpose corneal waveforms to monitor changes in a patient's cornea over time, and measure structures within the cornea such as micro bubbles created during femto-second laser flap cuts.[2]

Indications[]

Corneal pachymetry is essential for other corneal surgeries such as Limbal Relaxing Incisions. LRI[3] is used to reduce corneal astigmatism by placing a pair of incisions of a particular depth and arc length at a steep axis of corneal astigmatism. By using the corneal pachymetry the surgeon will reduce the chances of perforation of the eye and improves surgical outcome. Newer generations of pachymeters will help surgeons by providing graphical surgical plans to eliminate astigmatism. Prior to cataract surgery, it is also important to measure pachymetry to detect a condition known as Fuch’s Corneal Endothelial Dystrophy.[4] In this condition, the cornea is thickened due to Oedema (swelling) because it cannot pump out enough of the aqueous (water). This is because there has been a loss of endothelial cells lining the corneas internal back surface. Cataract surgery could cause further damage to the cornea and potentially lead to sight loss in such patients.

Corneal pachymetry is also considered an important test in the early detection of glaucoma. In 2002, the five-year report of the Ocular Hypertension Study (OHTS) was released. The study reported that corneal thickness as measured by corneal pachymetry was an accurate predictor of glaucoma development when combined with standard measurements of intraocular pressure. As a result of this study and others that followed, corneal pachymetry is now widely used by both glaucoma researchers and glaucoma specialists to better diagnose and detect early cases. Newer generation pachymeters have the ability to adjust the intraocular pressure that is measured according to the corneal thickness. Tonometers have to make an assumption of the patient’s corneal thickness when measuring the eye’s IOP (intra ocular pressure). If the patient’s real corneal thickness is a lot different, the accuracy of the measured results will be incorrect and the true intra ocular pressure may be much different.[4] Also, it’s postulated that patients with thinner corneas are at higher risk of developing glaucoma.

Technology[]

Modern devices use ultrasound technology, while earlier models were based on optical principles. The ultrasonic Pachymeters traditionally have been devices that provide the thickness of the human cornea in the form of a number in micrometres that is displayed to the user. The newer generation of ultrasonic pachymeters work by way of Corneal Waveform (CWF). Using this technology, the user can capture an ultra-high-definition echogram of cornea, think of it as a corneal A-scan. Pachymetry using the corneal waveform allows the user to more accurately measure the corneal thickness, have the ability to check the reliability of the measurements that were obtained, have the ability to superimpose corneal waveform to monitor the change of patients cornea over time, and ability to measure structures within the cornea such as micro bubbles created in the cornea during femto-second laser flap cut.[2] One issue with contact pachymeters is the need for topical anaesthetic as well as recurrent sterilisation of the pachymeter probe and the inherent cross infection risks. The need for consumables can mean the long-term costs can be higher than they might at first appear.

Modern optical devices generally use a form of confocal scanning or low coherence interferometry. There is a new device now entering the market which provides a handheld version of this technology, providing greater portability, convenience, and ease of use. It compares favourably to small, handheld ultrasound pachymeters often found in hospitals, refractive clinics, and optometry consulting rooms.[1]

References[]

  1. ^ "Archived copy". www.micromedinc.com. Archived from the original on 26 March 2010. Retrieved 17 January 2022.{{cite web}}: CS1 maint: archived copy as title (link)
  2. ^ a b Eisner, R; Israel, R (November 1, 2006). "Corneal waveform measurements has advantages in pachymetry". Ocular Surgery News. Vol. 24, no. 21.
  3. ^ "Limbal Relaxing Incisions Made Simple | OphthalmologyWeb: The Ultimate Online Resource for Ophthalmologists". Ophthalmologyweb.com. 2008-08-27. Retrieved 2015-02-22.
  4. ^ a b "Optometry - Handeld Optical Pachymeter". Occuity. Retrieved 2021-06-30.
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