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{{Article
|Authors=Vedant.Sathye,Peter.A.Karth
|Authors=Peter.A.Karth, Vedant.Sathye
|Category=Techniques
|Additional contributors=ClarisaMarie.Bloemhof
|Assigned editor=Jennifer.I.Lim.CMT
|Category=Retina/Vitreous
|Reviewer=Vinay.A.Shah.SEC
|Assigned editor=Sun.Y.Lee
|Date reviewed=September 22, 2017
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|Date reviewed=August 13, 2024
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Ophthalmoscopy is a routine exam done by ophthalmologists to examine the inside of the back of the eye, also known as the fundus or posterior segment. Although there are several types of ophthalmoscopy, we will focus on Binocular Indirect Ophthalmoscopy or BIO, for short, in this article.  BIO is one of the ways used to view the retina, with a wide field of the retina and stereoscopic view.  BIO also allows dynamic observation of the retina by moving the BIO device, lens, and applying scleral depression. The process is “indirect” because the fundus is viewed through a hand held condensing lens.  
{{Infobox disease
| Name = Ophthalmoscopy
| DiseasesDB =
| ICD9 =
| ICD10 =
| OMIM =
| MeshID = D009887
| MedlinePlus = 003881
}}
 
= Diagnostic Intervention  =
 
== Description/Overview ==
Ophthalmoscopy is a routine exam done by ophthalmologists to examine the inside of the back of the eye, also known as the fundus or the posterior segment. Ophthalmoscopy can be broken up into two types, direct and indirect. Direct ophthalmoscopy provides an upright, unreversed image of around 15 times magnification, while indirect ophthalmoscopy produces a reversed, inverted image magnified 2 to 5 times. <ref>ophthalmoscope. In: ''Miller-Keane Encyclopedia and Dictionary of Medicine, Nursing, and Allied Health, Seventh Edition.'' The Free Dictionary Website. Accessed June 10, 2023. https://medical-dictionary.thefreedictionary.com/ophthalmoscope. </ref> Indirect ophthalmoscopy can then be further divided into monocular indirect ophthalmoscopy (MIO) and binocular indirect ophthalmoscopy (BIO).
 
Although there are several types of ophthalmoscopy, this article will focus on BIO. Unlike MIO where only one view of the interior eye is offered, BIO offers a three-dimensional rendition of the interior eye since it projects three elements.<ref>Inspecting the difference between direct vs indirect ophthalmoscopes. Keeler. January 5, 2022. Accessed June 10, 2023. https://www.keelerusa.com/blog/post/inspecting-difference-direct-vs-indirect-ophthalmoscopes. </ref> Thus, BIO offers a wide field, stereoscopic view of the retina. BIO also allows dynamic observation of the retina by moving the BIO device, lens, and applying scleral depression.  
[[File:AA0 52689.jpg|thumb|'''Figure 1.''' A binocular indirect ophthalmoscope and a condensing lens. Image courtesy of JoAnn A. Giaconi, MD.<ref>Giaconi JA. American Academy of Ophthalmology. Indirect ophthalmoscope. Accessed June 10, 2023. https://www.aao.org/education/image/indirect-ophthalmoscope-6. </ref>]]


== History  ==
== History  ==


The earliest ideas about ophthalmoscopy dates back to 1846 when Dr. William Cumming, a front runner in the field of ophthalmology, wrote that “every eye could be made luminous if the axis from a source of illumination directed towards a person's eye and the line of vision of the observer were coincident”. Five years later, in 1851, Hermann von Helmholtz designed the first direct ophthalmoscope for medical use. A year later Christian Ruete made modifications to Helmholtz’s design by implementing a concave focusing mirror, and thereby introduced indirect ophthalmoscopy to allow for a stereoscopic and wider view of the fundus. Dr. Steven Schepens improved on the original design in 1945 by adding a second lens for the other eye. This allowed him to see an inverted and reversed view of the fundus, with a relatively large field of vision.  
The earliest ideas about ophthalmoscopy dates back to 1846 when Dr. William Cumming, a front runner in the field of ophthalmology, wrote that “every eye could be made luminous if the axis from a source of illumination directed towards a person's eye and the line of vision of the observer were coincident.”<ref>Cumming W. On a luminous appearance of the human eye, and its application to the detection of disease of the retina and posterior part of the eye. ''Journal of the Royal Society of Medicine''. 1846;MCT-29(1):283-296. doi:10.1177/095952874602900118</ref> Five years later, in 1851, Hermann von Helmholtz designed the first direct ophthalmoscope for medical use.<ref>Kalayoglu MV. Helmholtz, Schepens, and Now: The Evolution of the Modern Binocular Indirect Ophthalmoscope. Ophthalmology Web. February 16, 2005. Accessed June 10, 2023. https://www.ophthalmologyweb.com/Tech-Spotlights/26431-Helmholtz-Schepens-and-Now-The-Evolution-of-the-Modern-Binocular-Indirect-Ophthalmoscope/. </ref> A year later, Christian Ruete made modifications to Helmholtz’s design by implementing a concave focusing mirror, and thereby introduced indirect ophthalmoscopy to allow for a stereoscopic and wider view of the fundus.<ref>Keeler CR. The Ophthalmoscope in the Lifetime of Hermann von Helmholtz. ''Archives of Ophthalmology''. 2002;120(2):194. doi:10.1001/archopht.120.2.194</ref> Dr. Charles Louis Schepens (1912-2006) improved on the original design in 1945 by adding a second lens for the other eye (binocular indirect ophthalmoscope). This allowed him to see an inverted and reversed view of the fundus, with a relatively large field of vision.  


== Mechanics and Optics  ==
== Mechanics and Optics  ==
Line 17: Line 34:
=== Device ===
=== Device ===


<nowiki> </nowiki>The BIO device consists of a headband, binocular lens with mirrors, and a light source (see diagram). The examiner  wears the device by positioning the headband around his or her head so that the binocular lenses sit directly in front of their eyes. Mirrors in the device split the light reflecting back toward the examiner so the image may be presented to each of the examiner’s eyes. The light is between the doctor's eyes just above the bridge of their nose.   
The BIO device consists of a headband, binocular lens with mirrors, and a light source (Figure 1).<ref>ophthalmoscope. In: ''Millodot: Dictionary of Optometry and Visual Science, 7th edition.'' The Free Dictionary Website. Accessed June 10, 2023. https://medical-dictionary.thefreedictionary.com/ophthalmoscope. </ref> The examiner wears the device by positioning the headband around his or her head so that the binocular lenses sit directly in front of their eyes.<ref name=":0">Agarwal P. Looking Deep into Retina: Indirect Ophthalmoscopy and Fundus Drawing. Slideshare. Accessed June 10, 2023. https://www.slideshare.net/prachira/looking-deep-into-retina-indirect-ophthalmoscopy-and-fundus-drawing. </ref> Mirrors in the device split the light reflecting back toward the examiner so the image may be presented to each of the examiner’s eyes. The light is between the doctor's eyes just above the bridge of their nose.      
[[File:AA0 56198.jpg|thumb|'''Figure 2.''' A) In indirect ophthalmoscopy, the observer’s pupil (O) and patient’s pupil (P) are conjugate to avoid “wasting” light. B) If the condensing lens is too close to the patient’s eye, the peripheral retina will not be illuminated. C) If the condensing lens is too far from the patient’s eye, light from the patient’s peripheral retina will not reach the observer’s eye. Developed by Neal H. Atebara, MD. Redrawn by C. H. Wooley.<ref>Atebara NH, Wooley CH. American Academy of Ophthalmology. Indirect ophthalmoscope. Accessed June 10, 2023.https://www.aao.org/education/image/indirect-ophthalmoscopy. </ref>]]
[[File:Direct vs. Indirect Ophthalmoscope View.png|left|thumb|'''Figure 3.''' Image A shows an upright, unreversed image of a right eye fundus, while image B shows the inverted, reversed image that an examiner performing BIO on a right eye will observe.


=== Hand-held Condensing Lenses ===


<nowiki> </nowiki>During use, a hand held “condensing lens” is held by the examiner, a few inches above the patient’s eye.  The purpose of this lens is to “gather” the light rays coming out of the patient’s eyes which are divergent due to the power of the cornea.  This lens presents a real horizontally and vertically inverted image in front of the hand held condensing lens.  The power of the condensing  lens determines three things: viewing distance, magnification, and field of view. Typical lenses used have a range of:+14D to +30D (D=diopter).  As the lens dioptric power increases magnification decreases and field of vision increases. Low power(i.e. +14D to +18D) lenses offer strong magnification but a relatively smaller field of view, and below about +20D, the lens needs to be held further from the patient's eye, which may be difficult for some examiners. There are many different types of lenses that doctors also use. Aspheric lenses are general multi purpose lenses that are used when not looking for anything in specific.  
Created with BioRender.com]]


=== Hand-Held Condensing Lenses ===
During BIO, a hand held “condensing lens” is held by the examiner, a few inches above the patient’s eye.<ref>Cordero I. Understanding and caring for an indirect ophthalmoscope. ''Community Eye Health''. 2016;29(95):57.</ref> The purpose of this lens is to “gather” the light rays coming out of the patient’s eyes which are divergent due to the power of the cornea (Figure 2). This lens presents a real horizontally and vertically inverted image in front of the hand held condensing lens on the side towards the examiner (Figure 3).
The power of the condensing lens determines three things: viewing distance, magnification, and field of view. <ref name=":0" /> Typical lenses used have a range of: +14D to +30D (D=diopter). As the lens dioptric power increases, magnification decreases and field of vision increases. Low power (i.e. +14D to +18D) lenses offer strong magnification, but a relatively smaller field of view, and below about +20D, the lens needs to be held further from the patient's eye, which may be difficult for some examiners. The magnification of a specific BIO lens is crudely determined by 60/the power of lens.<ref>ophthalmoscope. In: ''Millodot: Dictionary of Optometry and Visual Science, 7th edition.'' The Free Dictionary Website. Accessed June 10, 2023. https://medical-dictionary.thefreedictionary.com/ophthalmoscope. </ref> Thus, a +20D lens would have a magnification of 60/20=3X. +20D lens is the most commonly used lens for BIO in adults.<ref>Cordero I. Understanding and caring for an indirect ophthalmoscope. ''Community Eye Health''. 2016;29(95):57.</ref> For examination of small children (such as patients with [[Retinopathy_of_Prematurity|retinopathy of prematurity]]) and those with small pupils, a more high-powered lens is preferred. 
=== Filters ===
=== Filters ===
BIO devices may include filters that examiners can employ for different views of the retina.<ref>Schmit-Eilenberger V. Colour Filters When Using an Indirect Ophthalmoscope. HEINE. Accessed June 10, 2023. https://www.heine.com/en_US/medical-specialties/ophthalmology/application-and-diagnostic-tips/diagnostics-with-the-indirect-ophthalmoscope/colour-filters-indirect-ophthalmoscope. </ref>
*No filter, or white light, allows the fundus to be viewed in its natural hue and saturation. This is generally used at the start of an examination to get an overview.
* A yellow filter offers comfort to both the examiner and patient alike because of the decreased intensity of light entering the patient's eye. It may also have a protective effect due to reduced UV exposure. Examiners often use this filter for photophobic patients.


BIO devices  may include filters. A yellow filter offers protection to the user because of the decreased intensity of light entering the patient's eye and may even offer protection to the patient’s retina or provide comfort to the patient. Red-Free filters can be used to view blood, membranes, and highlights whitish portions of the retina, if present.. Cobalt Blue filters can be used to more clearly view the eye after a fluorescein angiography.
* Because the retina has a predominantly red hue when the fundus is examined with white light, red-free filters allow for clearer contrast between structures and the surrounding tissue. Examiners often use this filter to better view blood, vessels, retinal nerve fiber layer defects, and more. They are also used to distinguish between retinal and choroidal nevi, since choroidal lesions seem to disappear with a red-free filter.
[[File:Peripheral vision.jpg|right|frameless]]


== Technique to Perform BIO  ==
* Blue filters are used by examiners to better view pathologies that exist in front of the membrana limitans interna and the anterior retinal layers, as these layers reflect blue light. They can also be used to more clearly view the eye after a [[Fluorescein_Angiography|fluorescein angiography]], and may be used to do fluorescein angioscopy - BIO of the peripheral retina with a blue filter to identify peripheral neovascularization after the patient has been administered sodium fluorescein intravenously.
# Adjustment of the ophthalmoscope
= Procedure =
# Adjust headband crown 
[[File:Indirect Ophthalmoscopy 101.png|link=link=Special:FilePath/Indirect_Ophthalmoscopy_101.webp|alt=|thumb|'''Figure 4.''' In this image, the patient is correctly positioned in supine for BIO. The examiner is gently stabilizing the lens against the patient’s head approximately 2 inches from the eye and performing scleral depression. Image courtesy of Christopher Nathaniel Roybal, MD, PhD.<ref>Roybal CN. Indirect Ophthalmoscopy 101. American Academy of Ophthalmology. February 25, 2023. Accessed June 15, 2023. https://www.aao.org/young-ophthalmologists/yo-info/article/indirect-ophthalmoscopy-101. </ref>]]
# Adjust the pupillary distance
<youtube>Zg0eUd3aCFI</youtube>
# Check illumination intensity. Usually start with lower illumination and slowly increase illumination as needed and as tolerated by the patient.  Check for a proper elevation/position. Check can be done by extending arm or by looking at a wall.
# Apply filter if desired  
# Positioning the patient - Patient should be in a supine position
# Patient should be looking directly up, initially (primary position) 
# Examiner should initially stand to the side of the patient, leaning over the patient
# Insert handheld lens approximately 2 inches away from patient's eye, moving it closer or farther away to focus and refine the view
# Examiner swivels his view around to view different parts of the retina, by tilting the head and walking around the patient
# The doctor instructs the patient to look at various extremes of their vision


[[File:BIO.jpg|frameless]]
== Technique to Perform BIO<ref>10. Kalayoglu MV. Helmholtz, Schepens, and Now: The Evolution of the Modern Binocular Indirect Ophthalmoscope. Ophthalmology Web. February 16, 2005. Accessed June 15, 2023. https://www.ophthalmologyweb.com/Tech-Spotlights/26431-Helmholtz-Schepens-and-Now-The-Evolution-of-the-Modern-Binocular-Indirect-Ophthalmoscope/. </ref> ==
# Ensure the patient is well dilated.
# Position the patient flat and supine with space around the head for the examiner to move freely around.
# Choose the appropriate condensing lens to use for the specific patient, exam, and examiner skill level.
# Securely fasten the BIO device to the examiner’s head.
# Adjust the pupillary distance and height of the beam so the examiner can see a full beam with each eye.
# Check spot size and illumination intensity. For well dilated patients, use the largest spot size. For smaller pupils and intraocular gas, use a smaller spot size. Start with lower illumination and slowly increase light intensity as needed and as tolerated by the patient.
# Apply a filter if desired or needed for the specific patient and exam.
# Hold the lens right-side up to minimize distortion and approximately 2 inches from the patient’s eye. If possible, stabilize your hand gently against the patient’s head. Move the lens in and out from the patient’s eye to focus and refine the view.
# To start, the patient should be looking directly up and the examiner should stand to the side of the patient, leaning over. The examiner views different parts of the retina by tilting their head and walking around the patient.
# The examiner instructs the patient to look at various extremes of their vision until all 360 degrees of the peripheral retina have been examined. To see the superior retina, instruct the patient to look up. To see the inferior retina, instruct the patient to look down.
# Perform scleral depression if this technique is needed during the exam to better view the peripheral retina.
# The macula is examined last, as the light is bright and patient cooperation for BIO may reduce drastically if the macula is examined at the start.


== Additional Aspects  ==
== Additional Aspects  ==
Line 47: Line 77:
=== Dilation ===
=== Dilation ===


<nowiki> </nowiki>The examiner looks through the pupil to view the posterior segment of the eye.. However, the undilated pupil restricts the view field of view dramatically. Doctors will generally decide to administer dilating drops. Mydriatics are dropped into the eye. Mydriatics come in two forms: parasympathetic antagonists such as Tropicamide, or sympathetic agonists such as Phenylephrine. Parasympathetic antagonists are used to paralyze the iris sphincter muscle while sympathetic agonists are used to stimulate the iris dilator muscle. Through this enlarged pupil the examiner is able to view the periphery of the retina.
The examiner looks through the pupil to view the posterior segment of the eye. However, the undilated pupil restricts the field of view dramatically. Further, the bright light of BIO usually makes the pupil very small. <ref>Boyd K. What are dilating eye drops? American Academy of Ophthalmology. October 27, 2022. Accessed June 10, 2023. https://www.aao.org/eye-health/drugs/dilating-eyedrops. </ref> Examiners will generally decide to administer dilating drops into the eyes, also known as mydriatics. Mydriatics come in two forms: parasympathetic antagonists such as tropicamide 0.5%, or sympathetic agonists such as phenylephrine 2.5% or 10%.<ref>Fundoscopic Exam (Ophthalmoscopy). Stanford Medicine 25. Accessed June 10, 2023. https://stanfordmedicine25.stanford.edu/the25/fundoscopic.html. </ref>  Parasympathetic antagonists are used to paralyze the iris sphincter muscle while sympathetic agonists are used to stimulate the iris dilator muscle. Through this enlarged or dilated pupil, the examiner is able to view the center and periphery of the retina.


=== Scleral Depression ===
=== Scleral Depression ===


A technique commonly used with BIO is scleral depression. This complements the dynamic viewing of the retina and vitreous.  The forward and inward curvature of the globe in the anterior portion of the eye obscures and prevents far peripheral viewing Therefore, scleral depression (or special contact lenses such at Goldman 3-Mirror contact lens) is needed to indent the scleral and bring the peripheral retina into view.. To depress the sclera, a scleral depressor is placed against the sclera (either on the globe or on the eyelid overlying the globe) and gentle firm pressure is applied.  This pushes the sclera and the retina into the examiner’s field of view during the BIO exam.  
A technique commonly used with BIO is scleral depression.<ref name=":0" /> This complements the dynamic viewing of the retina and vitreous. The forward and inward curvature of the globe in the anterior portion of the eye obscures and prevents far peripheral viewing. Therefore, scleral depression is needed to indent the sclera and bring the peripheral retina into view. To depress the sclera, a scleral depressor is placed against the sclera (either on the globe or on the eyelid overlying the globe) and gentle firm pressure is applied. To the examiner, the scleral depressor creates an elevation or "bump" at the point of depression. By looking at the "bump," the examiner can view more of the fundus periphery. Scleral depression is a helpful way of examining patients who are at risk of peripheral retinal anomalies such as tears or detachments. When patients have high risk symptoms such as flashes and floaters, scleral depression is highly recommended to allow complete viewing of the retina.
 
Examples of available scleral depressors include:
* Schepens scleral depressor (with thimble) - [https://www.accuspire.com/schepens-scleral-depressor-with-thimble-medium/ Image Link]
* OConnor scleral depressor (usually used intraoperatively) - [http://webeye.ophth.uiowa.edu/eyeforum/tutorials/instruments/vitrectomy/Miscellaneous/OConnor_Scleral_Depressor_Marker.jpg Image Link]
* Schocket double ended scleral depressor - [https://www.accuspire.com/schocket-scleral-depressor-double-end-s4-1231/ Image Link]
* Josephberg Besser scleral depressor - [https://www.accuspire.com/josephberg-besser-scleral-depressor-short-s4-1236s/ Image Link]
* Flynn Scleral depressor - [https://www.accuspire.com/flynn-scleral-depressor/ Image Link]
 
= Additional Resources =


To the examiner, the scleral depressor creates an elevation at the point of depression (“bump”). By looking into the depression the doctor can view more of the peripherals of the fundus. Scleral depression is also a helpful way of examining patients who complain of flashes and floaters or patients who are at risk of peripheral retinal anomalies such as tears or detachments.  When patients have high risk symptoms, scleral depression is highly recommended to allow complete viewing of the retina
* Randolph JD. 3 Tips for Indirect Ophthalmoscopy. American Academy of Ophthalmology. February 23, 2023. Accessed June 10, 2023. https://www.aao.org/young-ophthalmologists/yo-info/article/3-tips-for-indirect-ophthalmoscopy.


= References  =
= References  =
# "Fundoscopic / Ophthalmoscopic Exam." Fundoscopic (Ophthalmoscopic) Exam. Stanford Medicine, n.d. Web. 09 July 2016.
<references />
# "Red Reflex Examination in Neonates, Infants, and Children." Pediatrics 122.6 (2008): 1401-404. AAP Publications. American Academy of Pediatrics, 2008. Web. 11 July 2016.
# Trobe, Jonathan. "The Eyes Have It: Optic Fundus Signs." The Eyes Have It: Optic Fundus Signs. University of Michigan, 2009. Web. 11 July 2016.
# Lusby, Franklin W. "Ophthalmoscopy: MedlinePlus Medical Encyclopedia."Ophthalmoscopy: MedlinePlus Medical Encyclopedia. US National Library of Medicine, 23 Feb. 2015. Web. 12 July 2016.
# Agarwal, Prachir. "Looking Deep into Retina : Indirect Ophthalmoscopy and Fundus Drawing." Looking Deep into Retina : Indirect Ophthalmoscopy and Fundus Drawing. Slideshare, 25 Aug. 2013. Web. 21 July 2016.
# "Helmholtz, Schepens, and Now: The Evolution of the Modern Binocular Indirect Ophthalmoscope." Ophthalmology Web. Ophthalmology Web, 16 Feb. 2005. Web. 14 July 2016.
# "Commonly Used Dilating Drops (mydriatic Medications)." - PG CFA / Knowledgebase. KBPublisher, 8 Mar. 2008. Web. 21 July 2016.
# Binocular indirect ophthalmoscope. The light source mounted above and between the examiner's eyes illuminates the condenser, which images the source at the periphery of the patient's pupil. The illumination does not overlap the observation beam. The condenser lens is handheld; it forms an inverted aerial image of the retina. Digital image. The Free Dictionary. N.p., n.d. Web. 16 Sept. 2016.

Latest revision as of 21:01, August 13, 2024

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Article initiated by:
Peter A.Karth, MD, Vedant Sathye
All contributors:
Clarisa Marie BloemhofVinay A. Shah M.D.Leo A. Kim, MD, PhDSun Young (Sunny) Lee, MD, PhDKoushik Tripathy, MD (AIIMS)Diana V. Do, MDNeelakshi Bhagat, MD, FACSJennifer I Lim MDPeter A.Karth, MD
Assigned editor:
Sun Young (Sunny) Lee, MD, PhD
Review:
Assigned status Update Pending
 by Sun Young (Sunny) Lee, MD, PhD on August 13, 2024.


Ophthalmoscopy
MedlinePlus
003881
MeSH
D009887


Diagnostic Intervention

Description/Overview

Ophthalmoscopy is a routine exam done by ophthalmologists to examine the inside of the back of the eye, also known as the fundus or the posterior segment. Ophthalmoscopy can be broken up into two types, direct and indirect. Direct ophthalmoscopy provides an upright, unreversed image of around 15 times magnification, while indirect ophthalmoscopy produces a reversed, inverted image magnified 2 to 5 times. [1] Indirect ophthalmoscopy can then be further divided into monocular indirect ophthalmoscopy (MIO) and binocular indirect ophthalmoscopy (BIO).

Although there are several types of ophthalmoscopy, this article will focus on BIO. Unlike MIO where only one view of the interior eye is offered, BIO offers a three-dimensional rendition of the interior eye since it projects three elements.[2] Thus, BIO offers a wide field, stereoscopic view of the retina. BIO also allows dynamic observation of the retina by moving the BIO device, lens, and applying scleral depression.

Figure 1. A binocular indirect ophthalmoscope and a condensing lens. Image courtesy of JoAnn A. Giaconi, MD.[3]

History

The earliest ideas about ophthalmoscopy dates back to 1846 when Dr. William Cumming, a front runner in the field of ophthalmology, wrote that “every eye could be made luminous if the axis from a source of illumination directed towards a person's eye and the line of vision of the observer were coincident.”[4] Five years later, in 1851, Hermann von Helmholtz designed the first direct ophthalmoscope for medical use.[5] A year later, Christian Ruete made modifications to Helmholtz’s design by implementing a concave focusing mirror, and thereby introduced indirect ophthalmoscopy to allow for a stereoscopic and wider view of the fundus.[6] Dr. Charles Louis Schepens (1912-2006) improved on the original design in 1945 by adding a second lens for the other eye (binocular indirect ophthalmoscope). This allowed him to see an inverted and reversed view of the fundus, with a relatively large field of vision.

Mechanics and Optics

Device

The BIO device consists of a headband, binocular lens with mirrors, and a light source (Figure 1).[7] The examiner wears the device by positioning the headband around his or her head so that the binocular lenses sit directly in front of their eyes.[8] Mirrors in the device split the light reflecting back toward the examiner so the image may be presented to each of the examiner’s eyes. The light is between the doctor's eyes just above the bridge of their nose.  

Figure 2. A) In indirect ophthalmoscopy, the observer’s pupil (O) and patient’s pupil (P) are conjugate to avoid “wasting” light. B) If the condensing lens is too close to the patient’s eye, the peripheral retina will not be illuminated. C) If the condensing lens is too far from the patient’s eye, light from the patient’s peripheral retina will not reach the observer’s eye. Developed by Neal H. Atebara, MD. Redrawn by C. H. Wooley.[9]
Figure 3. Image A shows an upright, unreversed image of a right eye fundus, while image B shows the inverted, reversed image that an examiner performing BIO on a right eye will observe. Created with BioRender.com

Hand-Held Condensing Lenses

During BIO, a hand held “condensing lens” is held by the examiner, a few inches above the patient’s eye.[10] The purpose of this lens is to “gather” the light rays coming out of the patient’s eyes which are divergent due to the power of the cornea (Figure 2). This lens presents a real horizontally and vertically inverted image in front of the hand held condensing lens on the side towards the examiner (Figure 3).

The power of the condensing lens determines three things: viewing distance, magnification, and field of view. [8] Typical lenses used have a range of: +14D to +30D (D=diopter). As the lens dioptric power increases, magnification decreases and field of vision increases. Low power (i.e. +14D to +18D) lenses offer strong magnification, but a relatively smaller field of view, and below about +20D, the lens needs to be held further from the patient's eye, which may be difficult for some examiners. The magnification of a specific BIO lens is crudely determined by 60/the power of lens.[11] Thus, a +20D lens would have a magnification of 60/20=3X. +20D lens is the most commonly used lens for BIO in adults.[12] For examination of small children (such as patients with retinopathy of prematurity) and those with small pupils, a more high-powered lens is preferred.

Filters

BIO devices may include filters that examiners can employ for different views of the retina.[13]

  • No filter, or white light, allows the fundus to be viewed in its natural hue and saturation. This is generally used at the start of an examination to get an overview.
  • A yellow filter offers comfort to both the examiner and patient alike because of the decreased intensity of light entering the patient's eye. It may also have a protective effect due to reduced UV exposure. Examiners often use this filter for photophobic patients.
  • Because the retina has a predominantly red hue when the fundus is examined with white light, red-free filters allow for clearer contrast between structures and the surrounding tissue. Examiners often use this filter to better view blood, vessels, retinal nerve fiber layer defects, and more. They are also used to distinguish between retinal and choroidal nevi, since choroidal lesions seem to disappear with a red-free filter.
  • Blue filters are used by examiners to better view pathologies that exist in front of the membrana limitans interna and the anterior retinal layers, as these layers reflect blue light. They can also be used to more clearly view the eye after a fluorescein angiography, and may be used to do fluorescein angioscopy - BIO of the peripheral retina with a blue filter to identify peripheral neovascularization after the patient has been administered sodium fluorescein intravenously.

Procedure

Figure 4. In this image, the patient is correctly positioned in supine for BIO. The examiner is gently stabilizing the lens against the patient’s head approximately 2 inches from the eye and performing scleral depression. Image courtesy of Christopher Nathaniel Roybal, MD, PhD.[14]

Technique to Perform BIO[15]

  1. Ensure the patient is well dilated.
  2. Position the patient flat and supine with space around the head for the examiner to move freely around.
  3. Choose the appropriate condensing lens to use for the specific patient, exam, and examiner skill level.
  4. Securely fasten the BIO device to the examiner’s head.
  5. Adjust the pupillary distance and height of the beam so the examiner can see a full beam with each eye.
  6. Check spot size and illumination intensity. For well dilated patients, use the largest spot size. For smaller pupils and intraocular gas, use a smaller spot size. Start with lower illumination and slowly increase light intensity as needed and as tolerated by the patient.
  7. Apply a filter if desired or needed for the specific patient and exam.
  8. Hold the lens right-side up to minimize distortion and approximately 2 inches from the patient’s eye. If possible, stabilize your hand gently against the patient’s head. Move the lens in and out from the patient’s eye to focus and refine the view.
  9. To start, the patient should be looking directly up and the examiner should stand to the side of the patient, leaning over. The examiner views different parts of the retina by tilting their head and walking around the patient.
  10. The examiner instructs the patient to look at various extremes of their vision until all 360 degrees of the peripheral retina have been examined. To see the superior retina, instruct the patient to look up. To see the inferior retina, instruct the patient to look down.
  11. Perform scleral depression if this technique is needed during the exam to better view the peripheral retina.
  12. The macula is examined last, as the light is bright and patient cooperation for BIO may reduce drastically if the macula is examined at the start.

Additional Aspects

Dilation

The examiner looks through the pupil to view the posterior segment of the eye. However, the undilated pupil restricts the field of view dramatically. Further, the bright light of BIO usually makes the pupil very small. [16] Examiners will generally decide to administer dilating drops into the eyes, also known as mydriatics. Mydriatics come in two forms: parasympathetic antagonists such as tropicamide 0.5%, or sympathetic agonists such as phenylephrine 2.5% or 10%.[17] Parasympathetic antagonists are used to paralyze the iris sphincter muscle while sympathetic agonists are used to stimulate the iris dilator muscle. Through this enlarged or dilated pupil, the examiner is able to view the center and periphery of the retina.

Scleral Depression

A technique commonly used with BIO is scleral depression.[8] This complements the dynamic viewing of the retina and vitreous. The forward and inward curvature of the globe in the anterior portion of the eye obscures and prevents far peripheral viewing. Therefore, scleral depression is needed to indent the sclera and bring the peripheral retina into view. To depress the sclera, a scleral depressor is placed against the sclera (either on the globe or on the eyelid overlying the globe) and gentle firm pressure is applied. To the examiner, the scleral depressor creates an elevation or "bump" at the point of depression. By looking at the "bump," the examiner can view more of the fundus periphery. Scleral depression is a helpful way of examining patients who are at risk of peripheral retinal anomalies such as tears or detachments. When patients have high risk symptoms such as flashes and floaters, scleral depression is highly recommended to allow complete viewing of the retina.

Examples of available scleral depressors include:

  • Schepens scleral depressor (with thimble) - Image Link
  • OConnor scleral depressor (usually used intraoperatively) - Image Link
  • Schocket double ended scleral depressor - Image Link
  • Josephberg Besser scleral depressor - Image Link
  • Flynn Scleral depressor - Image Link

Additional Resources

References

  1. ophthalmoscope. In: Miller-Keane Encyclopedia and Dictionary of Medicine, Nursing, and Allied Health, Seventh Edition. The Free Dictionary Website. Accessed June 10, 2023. https://medical-dictionary.thefreedictionary.com/ophthalmoscope.
  2. Inspecting the difference between direct vs indirect ophthalmoscopes. Keeler. January 5, 2022. Accessed June 10, 2023. https://www.keelerusa.com/blog/post/inspecting-difference-direct-vs-indirect-ophthalmoscopes.
  3. Giaconi JA. American Academy of Ophthalmology. Indirect ophthalmoscope. Accessed June 10, 2023. https://www.aao.org/education/image/indirect-ophthalmoscope-6.
  4. Cumming W. On a luminous appearance of the human eye, and its application to the detection of disease of the retina and posterior part of the eye. Journal of the Royal Society of Medicine. 1846;MCT-29(1):283-296. doi:10.1177/095952874602900118
  5. Kalayoglu MV. Helmholtz, Schepens, and Now: The Evolution of the Modern Binocular Indirect Ophthalmoscope. Ophthalmology Web. February 16, 2005. Accessed June 10, 2023. https://www.ophthalmologyweb.com/Tech-Spotlights/26431-Helmholtz-Schepens-and-Now-The-Evolution-of-the-Modern-Binocular-Indirect-Ophthalmoscope/.
  6. Keeler CR. The Ophthalmoscope in the Lifetime of Hermann von Helmholtz. Archives of Ophthalmology. 2002;120(2):194. doi:10.1001/archopht.120.2.194
  7. ophthalmoscope. In: Millodot: Dictionary of Optometry and Visual Science, 7th edition. The Free Dictionary Website. Accessed June 10, 2023. https://medical-dictionary.thefreedictionary.com/ophthalmoscope.
  8. Jump up to: 8.0 8.1 8.2 Agarwal P. Looking Deep into Retina: Indirect Ophthalmoscopy and Fundus Drawing. Slideshare. Accessed June 10, 2023. https://www.slideshare.net/prachira/looking-deep-into-retina-indirect-ophthalmoscopy-and-fundus-drawing.
  9. Atebara NH, Wooley CH. American Academy of Ophthalmology. Indirect ophthalmoscope. Accessed June 10, 2023.https://www.aao.org/education/image/indirect-ophthalmoscopy.
  10. Cordero I. Understanding and caring for an indirect ophthalmoscope. Community Eye Health. 2016;29(95):57.
  11. ophthalmoscope. In: Millodot: Dictionary of Optometry and Visual Science, 7th edition. The Free Dictionary Website. Accessed June 10, 2023. https://medical-dictionary.thefreedictionary.com/ophthalmoscope.
  12. Cordero I. Understanding and caring for an indirect ophthalmoscope. Community Eye Health. 2016;29(95):57.
  13. Schmit-Eilenberger V. Colour Filters When Using an Indirect Ophthalmoscope. HEINE. Accessed June 10, 2023. https://www.heine.com/en_US/medical-specialties/ophthalmology/application-and-diagnostic-tips/diagnostics-with-the-indirect-ophthalmoscope/colour-filters-indirect-ophthalmoscope.
  14. Roybal CN. Indirect Ophthalmoscopy 101. American Academy of Ophthalmology. February 25, 2023. Accessed June 15, 2023. https://www.aao.org/young-ophthalmologists/yo-info/article/indirect-ophthalmoscopy-101.
  15. 10. Kalayoglu MV. Helmholtz, Schepens, and Now: The Evolution of the Modern Binocular Indirect Ophthalmoscope. Ophthalmology Web. February 16, 2005. Accessed June 15, 2023. https://www.ophthalmologyweb.com/Tech-Spotlights/26431-Helmholtz-Schepens-and-Now-The-Evolution-of-the-Modern-Binocular-Indirect-Ophthalmoscope/.
  16. Boyd K. What are dilating eye drops? American Academy of Ophthalmology. October 27, 2022. Accessed June 10, 2023. https://www.aao.org/eye-health/drugs/dilating-eyedrops.
  17. Fundoscopic Exam (Ophthalmoscopy). Stanford Medicine 25. Accessed June 10, 2023. https://stanfordmedicine25.stanford.edu/the25/fundoscopic.html.
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