Goldmann applanation tonometer

The Goldmann applanation tonometer, the most commonly used tonometer, enables a reliable measurement of IOP to within ± 0.5 mm Hg. This tonometer, because it flattens or applanates the cornea and does not indent it, gives accurate information about the pressure in the undisturbed eye. Scleral rigidity can be disregarded because less than 0.5 mm of volume is displaced. It also causes little increase in pressure, so that minimal massage effect is produced by repeated measurements that might lower the pressure. A plastic tip is attached to a sensitive balance mounted on the slit lamp ( Fig. 25.7 ). This small tip is designed to minimize both the “inward” pull from the liquid tear film on the cornea and the “outward” push from the elastic cornea. The volume of displaced fluid inside the eye is so small that any variation in ocular rigidity can be ignored. When the circular tip with a 3.06-mm diameter is used to applanate the cornea, no significant elevation of eye pressure is created.

Goldmann applanation tonometry. (A) Basic features of tonometer, shown in contact with patient’s cornea. (B) Enlargement of (A) shows tear film meniscus created by contact of biprism and cornea.

(From Shields MB, ed. Textbook of Glaucoma . 4th ed. Baltimore: Williams & Wilkins; 1998.)

One disadvantage of the Goldmann applanation tonometer is its lack of portability. However, handheld applanation tonometers have been devised. Other disadvantages are that the technique requires training for successful use. In addition, corneal distortion associated with conditions, such as scarring or high astigmatism, creates difficulty in obtaining reliable endpoint measurements. Corneal abrasions are always a potential hazard if the assistant is too aggressive during the pressure reading or if any underlying corneal problem is present. Infection is a potential risk as well, thus cleaning the tip or single-use tips are necessary.

The method of applanation tonometry is as follows: a drop of a local anesthetic solution is placed into the lower conjunctival sac. Then a drop of fluorescein from a fluorescein strip (small strips of filter paper impregnated with fluorescein) is instilled into the eye. Combination drops, which include both an anesthetic and fluorescein, are available. After the drop is instilled, the patient’s head is positioned at the slit-lamp microscope with the chin on the chin rest and forehead pressed firmly against the headrest.

Once the cornea is in focus, the appropriate blue filter is used and the slit diaphragm is opened completely. In the beam, the whole surface of the patient’s eye should glow (fluoresce) in a bright greenish yellow. The blue light should be approximately 45 to 60 degrees to the side of the tonometer and should illuminate the front end of the prism head. The low magnification is used on the slit-lamp microscope. The patient’s lids must be open and unblinking. It is necessary to avoid any contact between the tonometer and the lid margin or lashes because this contact only induces further blinking. The patient is instructed to look straight ahead or at some target device attached to the slit lamp or the examiner’s ear to ensure fixation. Once the patient is ready, the tonometer, with the measuring drum set at 1 g (1 on the dial), is brought forward by the joystick of the slit lamp until it comes into contact with the center of the cornea.

Looking through one eyepiece of the microscope, the examiner sees, at the moment of contact, a bright yellow-green spot that quickly separates into two bright yellow-green semicircular arcs as the tonometer is moved slightly farther forward. These arcs should be in sharp focus and of equal circumference both above and below the horizontal dividing line. Any necessary correction should be made by the control lever or the height adjustment control on the slit lamp. The calibrated drum on the side of the tonometer is then turned toward higher numbers corresponding to increasing force of applanation. As this occurs, the two semicircular arcs move until they overlap, the inner edge of the upper semicircle becoming aligned with the inner edge of the lower semicircle ( Fig. 25.8 ). This is the desired endpoint at which the reading is taken from the drum.

(A) Split half circles at beginning of applanation. Intraocular pressure is read when the inner half circles touch one another (endpoint), as shown in (B).

The reading obtained is multiplied by 10 to convert the number to equivalent millimeters of mercury of IOP. Therefore 1 on the drum is equal to 10 mm Hg. It is best to take at least two readings from each eye to obtain an average value. If the values obtained on two successive readings are approximately the same, the technique is probably adequate.

Checking the calibration of the Goldmann applanation tonometer

Applanation tonometers should be calibrated for accuracy by the use of a central weight regularly. For the Goldmann tonometer, a short rod of measured weight is attached to the balancing arm of the tonometer and the rod set at 0, 2, and 6 respectively. At each measure, the measuring drum should be placed at the corresponding stop. At each stop, the tonometer head should move only ± 0.05 g (0.5 mm Hg) of these settings ( Fig. 25.9 ).

Calibration bar for Goldmann applanation tonometer.

The applanation tonometer consists of a plastic removable tip that contains a prism. This tip has a flat anterior surface, which is brought into contact with a fluorescein-stained tear film of the cornea, which it displaces to the periphery of the contact zone until a surface of known and constant size, 3.06 mm, is flattened. The prism within the tip splits the image of this 3.06 mm circle into two semicircles. The inner border of the semicircles, when they are touching, represents the line of demarcation between the cornea flattened by applanation and the cornea not flattened. Thus this is the endpoint of the measurement of an applanation circle of 3.06 mm. This tip is connected to a spring device that allows measurement of the amount of pressure needed to flatten the cornea and is regulated by a knob on the side that has markings of this amount of pressure. The knob can regulate the spring tension to produce a force that is between 0 and 8 g. Once the inner semicircles are touching following turning the knob to apply adequate pressure to flatten the cornea, this number is read from the knob’s outer ring.

Errors in Goldmann tonometry

• 1.
  

  If the fluorescein ring is too wide ( Fig. 25.10 ), too much fluorescein may have been instilled. In this case, a small tissue can be used to absorb excess fluorescein and the procedure repeated. Alternatively, the measuring prism may not have been cleaned of previous fluorescein. A wide band results in an erroneous high reading.

  
  

  
  

  
  

  

  
  

  
  

  Too much fluorescein has been instilled.

  
  
  
  
• 2.
  

  If the fluorescein band is too narrow ( Fig. 25.11 ), evaporation of the stained tear layer during protracted measurement has occurred. The reading on the drum will be lower than normal. The patient should be told to blink several times and the measurement repeated.

  
  

  
  

  
  

  

  
  

  
  

  Too narrow a fluorescein band caused by too little fluorescein or evaporation of fluorescein.

  
  
  
  
• 3.
  

  The two semicircles may not be on the middle field ( Fig. 25.12 ). The patient may have moved slightly or the chin rest may not be properly adjusted; thus the fluorescein rings are not two exact semicircles because of incorrect centering of the tonometer head. This produces a considerably elevated IOP. The slit lamp should be adjusted up or down to obtain two exact semicircles.

  
  

  
  

  
  

  

  
  

  
  

  Unequal semicircles caused by incorrect centering of the tonometer head.

  
  
  
  
• 4.
  

  If the patient’s head is not pressed firmly against the forehead bar, there may be intermittent contact of the prism with the cornea, resulting in apparent pulsations of the fluorescein rings. However, note that the normal cardiac cycle pulsation can be seen as pulsation of the rings.

  
  
• 5.
  

  With a spherical or near-spherical cornea, measurement can be made in any meridian. However, if astigmatism greater than 3.00 diopters exists, the flattened area becomes elliptical rather than circular. In this instance, the tonometer prism head should be set with the axis corresponding to the axis of the minus cylinder.

  
  
• 6.
  

  Standard applanation tonometry with fluorescein cannot be used over a soft contact lens. The MacKay-Marg tonometer, a pneumatic tonometer, or an electronic tonometer may be used in this situation.

  
  
• 7.
  

  Breath-holding or a tight collar can create a false high reading.

  
  
• 8.
  

  If it is necessary to hold the lids apart with the fingers and thumb, care must be taken to avoid pressing on the globe; this will falsely raise the IOP.

Evaluating the pressures

If the pressure is found to be more than 21 mm Hg with the Goldmann applanation tonometer measurements, the eye is considered abnormal. A pressure of 21 mm Hg should be regarded as borderline. Pressures between 18 and 21 mm Hg are generally normal, but the patient should be seen for repeated examinations. This reading may be unsafe in corneas that are thin.

The pressure normally varies in an eye at different times of day. It is highest in most people in the morning and lowest during the waking hours, the time when ophthalmologists conduct their clinics. It is because of this diurnal variation that the tension may be borderline or less than borderline and the patient may still have glaucoma. In addition to the diurnal variation, there are other low-tension glaucomatous states in which the pressure recordings may be normal or even below normal and the patient may still have clinical evidence of the disease. Although applanation tonometry is the best method of discovering the most characteristic risk factor for glaucoma, it is not an infallible test, for the reasons mentioned.

As mentioned, elevated IOP without demonstrable damage to the optic nerve and without visual field changes is called ocular hypertension . These cases require relentless and meticulous repeated observations.

The monitoring of glaucoma requires an ongoing evaluation of pressure, optic disc assessment, and visual field change.

Hints for tonometry use

• 1.
  

  Educate the patient . Less anxiety is created if the examiner tells the patient that the tonometer tip will touch the tear film instead of saying the tip will actually touch the eye.

  
  
• 2.
  

  Instill topical anesthetic . Again, tell the patient what to expect: “This drop may feel cold or may even sting for a few seconds.” Tell the patient to dab the eye with tissue paper, and to avoid rubbing or wiping the eye. After the anesthetic is given, touch the conjunctiva with a strip of fluorescein-impregnated paper. A drop of a combination topical anesthetic–fluorescein mixture, such as Fluress can be used.

  
  
• 3.
  

  Alignment . Place the patient’s chin on the rest and press the forehead against the headband. The patient’s eyes should be open. Ask the patient to stare straight ahead and not at the blue slit light.

  
  
• 4.
  

  Slit lamp and tonometer alignment . Set the magnification on low (this is much easier to use). Position the tonometer with the plastic tip centered and position the light so that the tonometer tip is as brightly illuminated as possible—usually a 45-degree angle between the light and tip. Do not forget to use the blue filter! Remember, if corneal astigmatism is greater than 3.00 diopters, set the tip corresponding to the axis of the minus cylinder of the astigmatism ( Fig. 25.13 ).

  
  

  
  

  
  

  

  
  

  
  

  Markings on the tonometer head for alignment with high cylinders.

  
  

  (From Kaiser, P. K., Massachusetts eye and ear infirmary illustrated manual of ophthalmology, 4th ed. St. Louis: Elsevier; 2014.)

  
  
  
  
• 5.
  

  Move the slit lamp toward the patient, with the joystick held back. Once 3 to 5 mm away from the cornea, slowly advance the slit lamp forward with the joystick. At this point, the examiner can look through the left eyepiece and begin to see a faint purple semicircle created by the reflected corneal image of the prism tip. These arcs will touch each other just before the tip actually touches the cornea.

  
  
• 6.
  

  Align tonometer mires . Just as the tip touches the cornea, two bright green semicircles appear. If this does not happen, pull the joystick back, recheck both patient and tonometer alignment, wipe the tip, and start again. If the semicircles are slightly out of line, alignment can be adjusted without repositioning the slit lamp.

  
  
• 7.
  

  Proper measurement depends on the two arcs being sharply focused, symmetric, and bright. Rotate the dial on the tonometer scale until the inner edges of the two arcs exactly align ( Fig. 25.14 ). To calculate the IOP, multiply the scale reading × 10. Pulsatile movements of the mires can be frustrating as the examiner tries to carefully touch the two inner edges together. A setting halfway between the two extreme pulse pressures will provide the truest pressure measurements.

  
  

  
  

  
  

  

  
  

  
  

  Tonometer scale is adjusted to align inner edges of the two fluorescein arcs on the cornea.

  
  

  (From Stamper RL. Becker-Shaffer’s Diagnosis and Therapy of the Glaucomas , Copyright © 2009, Elsevier Inc. All rights reserved.)

  
  

Perkins handheld applanation tonometer

The principle of this instrument is the same as that of the Goldmann applanation tonometer, in that an applanating surface is placed in contact with the cornea and that force applied is varied until a fixed diameter of applanation is achieved. In the handheld instrument, the Goldmann doubling prism tip is mounted on a counterbalanced arm and the change in force is obtained by rotation of a spiral spring. The instrument operates on two AA batteries, and a tiny light bulb underneath the doubling prism gives off a cobalt blue glow. The instrument can be used in any position and need not be held vertically. The patient can be sitting or lying flat.

The method of use is as follows: the eye is anesthetized with one drop of a fluorescein solution (Fluress). The tonometer should be held so that the thumb rests on the thumb wheel, controlling the spring. The light is switched on by turning the thumb wheel until the scale reading is above 0 and the filter holder is adjusted to illuminate the end of the doubling prism, when the latter is at approximately its midpoint of travel, which is the position used for measurement.

The instrument has a forehead rest that can be used when the tonometer is positioned on the patient’s cornea. It is easier to hold the tonometer obliquely, with the handle slanted away from the patient’s nose. Care should be taken that the prism is not touching the lids, in which case the readings obtained will be invalid.

The doubling prism is applied to the center of the patient’s cornea, with the scale reading 1. Semicircles of fluorescein should now be visible through the viewing lens; force is adjusted by turning the thumb wheel until the inner margins of the semicircles coincide. The tonometer is then removed from the eye and the reading noted. The reading is multiplied by 10 to give the tension in millimeters of mercury. The usual method is to repeat the reading for each eye twice and, if elevated, to take three readings.

If the semicircles appear large and are not reduced by altering the force of the spring, the tonometer has been pushed too close to the eye. Withdrawing it slightly will bring the prism within the range of free movement.

Electronic applanation tonometer

Electronics represents the final adaptation of the applanation principle and is best represented by the MacKay-Marg tonometer or the Electro Medical Technology tonometer. With this technique, as the tip is applied to the eye, the pressure flexes an ultrathin membrane. This pressure is indirectly transmitted to a force transducer. The pressure waveform is converted into electrical impulses proportional to the applied pressure and recorded on a graph with a thermal stylus. This original device is no longer available, but several miniaturized versions that function on similar principles have been developed and appear accurate and reliable.

Other applanation tonometers

Several lightweight, portable, handheld tonometers are available. One of them, the Tono-Pen ( Fig. 25.15 ), is a pen-like instrument that permits repeated accurate reading by applanation. It is a very useful instrument that incorporates its own battery power supply and digital readout and provides both an IOP reading and an indicator of the reliability of the value. The results correlate well with the Goldmann tonometer, although it slightly overestimates low IOPs and underestimates high IOPs. It can take measurements in an eye with an irregular or edematous cornea or through a soft contact lens in a variety of clinical settings because the area of applanation is much smaller than with the Goldmann applanation tonometer. Also available are applanation tonometers that can measure the IOPs through the use of an operating room microscope. This operating room device allows the surgeon to estimate whether the IOP is high, medium, or low at the end of intraocular surgery. Another is the AccuPen, a handheld tonometer that uses high-resolution, real-time waveform analysis to provide accurate IOP measurements. It uses gravity offset technology, which requires less calibration compared with other handheld tonometers. The user enters the central corneal thickness and the AccuPen creates an adjusted IOP.

The Tono-Pen XL to measure intraocular pressure.

(From Thomsen TW, et al. Measurement of Intraocular Pressure: Tono-Pen Technique . © Copyright 2011 Elsevier Inc.)

Icare® tonometers

The Icare® rebound tonometer uses a tiny plastic-tipped, single-use probe surrounded by a magnetic field. A magnetic coil “fires” the probe forward onto the cornea, creating a very small applanation region. The time it takes the probe to return to its resting position is indicative of the IOP. There is no air puff involved like other noncontact tonometers and the contact time is so brief that often no anesthetic need be used. The first version of the rebound tonometer is the Icare TA01i. The disadvantage of this tonometer is that the probe fell out of the tonometer if it was faced downward.

The Icare PRO adds a sensor that allows for IOP measurements in the supine position. In addition, the probe does not fall out if the tonometer is not in the upright position and there is greater accuracy when measuring IOP.

The Icare HOME tonometer is easy to use for patients who need to monitor their IOP consistently. It can automatically identify which eye is being measured and the patient only has to place the tonometer in front of their face without tilting the device and wait for a “green” ring signal to measure. If the tonometer is in an incorrect position, the device will display a red signal and the probe is not launched.

The Icare IC100 allows for self IOP measurements and improves on the upright position sensor. The newest generation Icare IC200, allows for 200 degrees of positional freedom so measuring the IOP for patients can be done in various positions.

Dynamic contour tonometer

The dynamic contour tonometer (DCT) is a digital tonometer that provides a direct transcorneal measurement of IOP. This tonometer is based on the principle that, by surrounding and matching the contour of a sphere, the pressure on the outside equals the pressure on the inside. In the DCT, the tip of the probe matches the contour of the cornea. A pressure transducer built into the center of the probe measures the outside pressure, which should equal the inside pressure, and the IOP is recorded digitally. The DCT eliminates the systematic errors inherent in other tonometers, such as the influence of corneal thickness and rigidity.