- Original Article
- Open Access
Ultrasonic evaluation of pupillary light reflex
© Springer-Verlag 2009
- Published: 21 October 2009
Evaluation of pupillary light reflex (PLR) is an important neurological test with a variety of clinical applications. Obstacles such as severe soft tissue damage or hyphema may obstruct the visual access to the pupil, thus rendering direct PLR observation difficult or impossible. Multipurpose ultrasonic systems, however, can overcome this problem.
Using ultrasound imaging, a coronal view of the iris and pupil allowed visualization of PLR upon contralateral stimulation with a penlight. The technique was tested in ten healthy volunteers and a trauma case study.
Satisfactory visualization of the iris was achieved in all subjects, in an average time of 1 min 10 s. Temporal parameters of pupillary constriction, oscillations (hippos) and relaxation could also be measured on M-mode displays.
Real-time coronal imaging of the iris using multipurpose ultrasound imaging is found to be a practical, fast and recordable method that can be used for evaluating PLR.
- Pupillary light reflex
- Consensual pupillary reflex
- Neurological trauma
- Ultrasound imaging
The first ophthalmic ultrasound image was published in 1956 . Since then, ultrasound imaging technologies have evolved to offer crucial diagnostic information in many ophthalmic conditions, such as complications of ocular trauma [2–5]. Ultrasound imaging is especially helpful when visual (optical) inspection is impossible to perform or does not provide a definitive diagnosis. Ultrasound in ophthalmology is employed in several clinical applications such as general-purpose ocular imaging (B-mode), ultrasound biometry that pursues precise distance measurements (A-mode), and ultrasound biomicroscopy (UBM) limited to the anterior segment, which uses high frequencies (e.g., 50 MHz) to provide a very high resolution of 33 μm and less [6–10]. Although very useful, specialized ophthalmic scanners or UBM devices are not available in the vast majority of emergency settings. Modern multipurpose ultrasound systems, on the other hand, are increasingly available for emergency imaging needs, and they have been demonstrated to provide excellent ophthalmic images when fitted with high-frequency probes . Furthermore, high-end systems of this class employ sophisticated focusing, harmonic imaging and other optimization techniques that are not yet feasible in the “ophthalmic” ultrasound systems. In the absence of slit lamp capability or other imaging options, this imaging modality may seek to obtain information that is normally outside the generally recognized scope of ocular ultrasound.
The condition of the iris and its response to stimuli is of interest in a variety of conditions. Reviews on pupillary light reflex (PLR) and its clinical implications have been published [3, 12]. For example, absence of the PLR has been shown to be a risk factor independently associated with death in craniofacial trauma . Prognostic consideration of pupillary diameter and constrictive ability was also recommended by the American Association of Neurological Surgeons . Due to the importance of PLR evaluation, it seems prudent to consider other potential means of PLR assessment for instances when soft tissue damage, corneal opacity or hyphema may obstruct visual access to the pupil. Of the various pupillometry methods that have been described, the majority still require specialized hardware and expertise and are not available in the majority of emergency settings [15–17]. Multipurpose ultrasound imagers, however, are used in emergency settings worldwide, rapidly establishing a new role of sonography as a first-line modality for emergency departments at the patient’s bedside [18–20]. These conventional multipurpose ultrasound scanners fitted with high-frequency probes in the 10–12 MHz range can be used to evaluate the condition of the globe and its components . Taking advantage of the capabilities of these scanners, we developed a practical method to assess pupillary response to light.
The experiments described here have been part of a large ground-based study conducted by NASA to develop ultrasound imaging procedures for long-duration space flight. Since the only ultrasound device currently flown in space is a multi-purpose system (HDI-5000, ATL/Philips, Bothell, WA, USA), procedures and protocols were sought to take utmost advantage of the capability in the majority of foreseeable medical conditions in space, including ophthalmic trauma, blunt head injuries and body injuries, to name a few.
This technique can also be performed from a superior approach to the eye. Using this approach, the patient is instead instructed to look downward at a fixed object toward his or her feet. The probe is placed transversely on the superior margin of the orbit (frontal bone). With the probe facing toward the orbit, it is then tilted about 45° upwards until the iris and pupil are seen in full view. The consensual PLR can then be elicited as described above.
Using the described procedure, coronal imaging of the iris was achieved in all subjects in less than 2 min with an average time of 1 min 10 s (range of 15 s–2 min). The discrete anechoic circle of the pupil surrounded by the typically patterned iris was clearly demonstrated in the near-field of the live image (Figs. 1, 2). Thanks to the shallow situation of the target, optimal focusing and convenient zooming were possible, thus further enhancing the quality of the image. As shown in Fig. 1, the pupillary diameter is confidently measured and rounded to the second decimal of a centimeter (0.1 mm). Upon contralateral stimulation with a penlight, consensual PLR can easily be observed in real-time on the eye being examined (Video 1). Using M-mode settings, pupillary diameter can also be visualized over a period of time. On the M-mode strip, the superior-to-inferior diameter of the pupil was represented as a black band across the strip (Fig. 2). Temporal parameters of pupillary constriction, oscillations (called hippos) and relaxation could also be measured on M-mode displays.
The remarkable absence of lens interference is explained by the fact of the very acute incident angle of the ultrasound beam and near-ideally smooth and regular surface; thus, the lens does not produce any echoes that could return back to the probe. The iris, on the other hand, is an excellent scatterer due to its complex structure, surface and irregularities, comparable in size with the ultrasound wavelength in the soft tissues.
The temporal resolution in B-mode (grayscale), as determined by the actual frame refresh rate, could reach 10 ms depending on the image optimization used. M-mode temporal resolution can be substantially better if the 2D image remains “frozen” or is not displayed. In emergency settings, since the technique would be used to establish the presence or absence of PLR and therefore no measurements or M-mode recordings would be necessary, only the output of the ultrasound system would be recorded to document the results, if necessary. While the theoretical resolution at the frequencies used is 0.128 mm (12 MHz) or 0.154 mm (10 MHz), the actual accuracy is better with additional image optimization techniques available in these systems, such as high-definition zooming, image persistence, second harmonic imaging, and electronic focusing.
It has been shown that modern multipurpose ultrasound systems provide the capability of viewing and recording real-time grayscale images of the iris in coronal or near-coronal planes, with a clear, high-resolution view of the pupillary opening. Such imaging equipment, commonly found in a hospital’s emergency department, could be used in a fast and practical manner for many clinical scenarios in which visual access to the pupil is hindered or rendered impossible. The dynamic nature of ultrasound imaging offers the possibility to measure and monitor the pupillary diameter and determine the presence or absence of consensual PLR, an important neurological test. This technique can also be used to record the pupillary diameter versus time, thus allowing analysis of the fine detail of the iris constriction, oscillations (hippos), or relaxation for both real-time and post examination. For this purpose, the M-mode capability of the ultrasound system is used. Other probes with slimmer design and higher (up to 15 MHz) frequencies may be more practical and convenient. Testing and application of the suggested procedure in the clinical setting seems to be a promising and valuable tool.
We would like to thank Butler Graphics, Inc. (Detroit, MI, USA) for their help in completing the illustrations. Supported by the National Space Biomedical Research Institute thru NAG 9-58.
Conflict of interest statement
There is no conflict of interest related to the publication of this manuscript.
- Fledelius HC (1997) Ultrasound in ophthalmology. Ultrasound Med Biol 23:365–375Google Scholar
- Fisher YL (1989) Advances in contact ophthalmic ultrasonography: ocular trauma and intraocular foreign body patients. Dev Ophthalmol 18:69–74PubMedView ArticleGoogle Scholar
- Fisher YL (1975) The current status of ophthalmic B-scan ultrasonography. J Clin Ultrasound 3:219–223PubMedView ArticleGoogle Scholar
- Hassani SN, Bard RL (1978) Real time ophthalmic ultrasonography. Radiology 127:213–219PubMedView ArticleGoogle Scholar
- Frank KE, Purnell EW, Jennings WD (1978) Relative frequency of ultrasound diagnoses in patients referred for ophthalmic ultrasound. Ophthalmology 85:1212–1217PubMedView ArticleGoogle Scholar
- Deramo VA, Shah GK, Baumal CR et al (1999) Ultrasound biomicroscopy as a tool for detecting and localizing occult foreign bodies after ocular trauma. Ophthalmology 106:301–305PubMedView ArticleGoogle Scholar
- Nemeth J, Csakany B, Pregun T (1996–1997) Ultrasound biomicroscopic morphometry of the anterior eye segment before and after one drop of pilocarpine. Int Ophthalmol 20:39–42Google Scholar
- Ludwig K, Wegscheider E, Hoops JP et al (1999) In vivo imaging of the human zonular apparatus with high-resolution ultrasound biomicroscopy. Graefes Arch Clin Exp Ophthalmol 237:361–371PubMedView ArticleGoogle Scholar
- Liu W, Wu Q, Huang S et al (1997) Application of ultrasound biomicroscopy in diagnosis of anterior segment vitreoretinal disorders. Yan Ke Xue Bao 13:192–196PubMedGoogle Scholar
- Wang N, Lai M, Zhou W (1997) Quantitative real time measurement of iris configuration in human eyes. Yan Ke Xue Bao 13:29–34PubMedGoogle Scholar
- Nemeth J, Vegh M, Horoczi Z et al (1992) Examination of the orbit using a non-ophthalmologic ultrasound equipment. Orv Hetil 133:2563–2565PubMedGoogle Scholar
- Kardon R (1995) Pupillary light reflex. Curr Opin Ophthalmol 6:20–26PubMedView ArticleGoogle Scholar
- Schreiber MA, Aoki N, Scott BG et al (2002) Determinants of mortality in patients with severe blunt head injury. Arch Surg 137:285–290PubMedView ArticleGoogle Scholar
- The Brain Trauma Foundation. The American Association of Neurological Surgeons. The Joint Section on Neurotrauma and Critical Care (2000) Pupillary diameter and light reflex. J Neurotrauma 17:583–590View ArticleGoogle Scholar
- Ellis CJ (1981) The pupillary light reflex in normal subjects. Br J Ophthalmol 65:754–759PubMedPubMed CentralView ArticleGoogle Scholar
- Fankhauser F 2nd, Flammer J (1989) Puptrak 1.0: a new semiautomated system for pupillometry with the octopus perimeter: a preliminary report. Doc Ophthalmol 73:235–248Google Scholar
- Hasegawa S, Ishikawa S (1989) Age changes in pupillary light reflex. A demonstration by means of a pupillometer. Nippon Ganka Gakkai Zasshi 93:955–961PubMedGoogle Scholar
- Bahner D, Blaivas M, Cohen HL, Fox JC, Hoffenberg S, Kendall J, Langer J, McGahan JP, Sierzenski P, Tayal VS, American Institute of Ultrasound in Medicine (2008) AIUM practice guideline for the performance of the focused assessment with sonography for trauma (FAST) examination. J Ultrasound Med 27(2):313–318PubMedGoogle Scholar
- Dulchavsky SA, Schwarz KL, Kirkpatrick AW, Billica RD, Williams DR, Diebel LN, Campbell MR, Sargysan AE, Hamilton DR (2001) Prospective evaluation of thoracic ultrasound in the detection of pneumothorax. J Trauma 50(2):201–205PubMedView ArticleGoogle Scholar
- Blaivas M, Theodoro D, Sierzenski PR (2002) A study of bedside ocular ultrasonography in the emergency department. Acad Emerg Med 9(8):791–799PubMedView ArticleGoogle Scholar
- Bedi DG, Gombos DS, Ng CS, Singh S (2006) Sonography of the eye. Am J Roentgenol 187:1061–1072View ArticleGoogle Scholar
- Trejo LJ, Rand MN, Cicerone CM (1989) Consensual pupillary light reflex in the pigmented rat. Vision Res 29:303–307PubMedView ArticleGoogle Scholar
- Bourne PR, Smith SA, Smith SE (1979) Dynamics of the light reflex and the influence of age on the human pupil measured by television pupillometry. J Physiol 293:1PPubMedGoogle Scholar
- Smith SA, Ellis CJ, Smith SE (1979) Inequality of the direct and consensual light reflexes in normal subjects. Br J Ophthalmol 63:523–527PubMedPubMed CentralView ArticleGoogle Scholar