Original Article

Acquired Vitelliform Macular Degeneration:
Characteristics and Challenges of Managing Subretinal

Fluid
Joseph Juliano, MD; Sagar Patel, MD; Hossein Ameri, MD, PhD, FRCSI, MRCOphth

USC Roski Eye Institute, Keck Medicine of University of Southern California, Los Angeles, CA, USA

ORCID:
Joseph Juliano: http://orcid.org/0000-0003-2527-0667
Hossein Ameri: http://orcid.org/0000-0002-5270-2800

Abstract
Purpose: To highlight diagnostic challenges in patients with acquired vitelliform macular
degeneration (AVMD) with subretinal fluid (SRF) and to examine the characteristics of image
findings in patients with AVMD.
Methods: In this retrospective review, the electronic medical record of 22 eyes of 16 patients
with AVMD was studied. The rates of SRF, drusen, pigment epithelial detachment (PED), and
patient clinical information such as age, length of follow-up, and best-corrected visual acuity
(BCVA) were assessed.
Results: The mean age at diagnosis with AVMD was 72 years with a mean follow-up time of 29
months. Median BCVA 20/33 at presentation and 20/33 at final follow-up. Drusen was found
in 13 of 22 eyes (59.1%), PEDs in 4 of 22 eyes (18.2%), and SRF in 10 of 22 eyes (45.5%) at
some point during their follow-up. Of the 10 eyes with SRF, 70% were center involving, and
recurrence occurred in 40%, all in the same location as the initial presentation of SRF. Three
eyes received an anti-vascular endothelial growth factor injection for SRF. In 66% of cases
receiving an injection, the fluid later relapsed and remitted without further injections during
the course of follow-up.
Conclusion: AVMD occurs in the same demographic as age-related macular degeneration
(AMD) and has many common features. SRF in AVMD tends to be center involving and recurs
usually in the same location as its origin. The use of anti-VEGF injections did not seem to
improve SRF in contrast to the SRF seen in wet AMD. Proper differentiation of AVMD may
prevent unnecessary long-term treatment with intravitreal anti-VEGF injections.

Keywords: Age-related Macular Degeneration; Vitelliform Macular Degeneration; Vitelliform Maculopathy

J Ophthalmic Vis Res 2021; 16 (4): 582–591

INTRODUCTION

Vitelliform lesions encompass a wide clinical
spectrum of macular pathology. In addition

Correspondence to:

Hossein Ameri, MD, PhD, FRCSI, MRCOphth. USC Roski
Eye Institute, 1450 San Pablo St, Los Angeles, CA 90033,
USA.
E-mail: ameri@med.usc.edu
Received: 31-08-2021 Accepted: 22-03-2021

Access this article online

Website: https://knepublishing.com/index.php/JOVR

DOI: 10.18502/jovr.v16i4.9748

to juvenile Best disease and adult onset
foveomacular vitelliform dystrophy, which are
associated with hereditary inheritance, there
are acquired vitelliform lesions often present in
the elderly. These degenerative lesions are not

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How to cite this article: Juliano J, Patel S, Ameri H. Acquired Vitelliform
Macular Degeneration: Characteristics and Challenges of Managing
Subretinal Fluid. J Ophthalmic Vis Res 2021;16:582–591.

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Acquired Vitelliform Macular Degeneration; Juliano et al

well characterized, and sometimes have been
grouped with adult onset foveomacular vitelliform
dystrophy.[1–3] In this study, we focus on acquired
vitelliform lesions and use the term acquired
vitelliform macular degeneration (AVMD) to focus
on the spectrum of cases without a family
history of the disease. Pseudovitelliform and
vitelliform are terms used interchangeably to
describe lesions seen in AVMD.[4] While not a
classic vitelliform lesion like in Best disease, in
this study we will use the term vitelliform lesion
to refer to the characteristic lesion appearance
on fundus exam in AVMD, which is a yellow,
elevated lesion usually associated with pigmentary
features.[5]

Lesions in AVMD appear in the same
demographic as dry age-related macular
degeneration (AMD)[6] and are often associated
with drusen;[7] while in AVMD the lipofuscin
accumulation is within the subretinal space,[5] in
AMD it accumulates below the retinal pigment
epithelium (RPE) and still these two entities can still
be easily confused. Furthermore, subretinal fluid
(SRF) can be present in AVMD[8, 9] which, when
in the context of drusen, might be concerning for
conversion of dry to wet AMD; or, interestingly
some cases of dry AMD can have SRF without
evidence of choroidal neovascularization (CNV).[10]
Thus, in these difficult circumstances, clinicians
are presented with the question: Has dry AMD
converted to wet AMD, or is this SRF in the
context of a vitelliform lesion? In Best disease,
an abnormal electrooculogram (EOG) has been
used as a reliable diagnostic tool,[11] however,
EOG is typically normal in AVMD.[12] Practical
considerations make it challenging to employ such
diagnostic modalities in a busy clinic, and while
imaging modalities have been employed to aid
in the diagnosis such as the use of fluorescein
angiogram (FA), fundus autofluorescence (FAF),
or optical coherence tomography angiography
(OCTA), they cannot always definitively distinguish
AVMD from wet AMD. Information regarding the
prevalence, natural course of AVMD associated
with SRF and its management in the literature is
limited. Here, we review a set of cases of patients
with AVMD with particular focus on patients that
develop concurrent SRF in the context of AVMD.
In this study, we describe the characteristics
of SRF in AVMD, the response of SRF with
intravitreal injections, and suggest a general
diagnostic algorithm that can be used in the clinic

in order to distinguish AVMD with SRF from wet
AMD.

METHODS

Study Population

This study is an IRB-approved retrospective
study of patients diagnosed with AVMD at
a single institution over a period from 2015
to 2020. Informed consent was not required
for this study. This study was conducted in
accordance with the Declaration of Helsinki.
The collection and evaluation of all protected
patient health information was performed in a
Health Insurance Portability and Accountability
Act (HIPAA)-compliant manner. The study was
approved by the institutional review board of the
University of Southern California Health Sciences.

Clinical assessment

Patients were diagnosed with AVMD after meeting
characteristic clinical features by combination of
optical coherence tomography (OCT) and fundus
exam findings. Fundus exam features included
the presence of focal yellowish macular lesions
and RPE changes in absence of dense pigment
clumps. Characteristic OCT changes included
nonhomogenous hyper reflectivity at the level
of RPE that could not be classified as pigment
epithelial detachment (PED) or drusen. None of the
patients had a family history of the disease. All
clinic visit notes were reviewed for each patient
and data were obtained on age, gender, eye
laterality, previous medical and ocular history, date
of diagnosis, visual acuity, and type of intravitreal
injection. Imaging features consisted of collecting
information from clinical fundoscopic exam, fundus
photos, OCT, OCTA, and FAF and FA if present.
Visual acuity data were converted to LogMAR and
all numerical data were reported as median or
mean with standard deviation.

RESULTS

Clinical Characteristics

The study included a total of 22 eyes of 16
patients with AVMD. The median LogMAR BCVA at
presentation was 0.22 (20/33), and at the last final

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Acquired Vitelliform Macular Degeneration; Juliano et al

follow-up 0.22 (20/33). Five patients had diagnoses
of AVMD in both eyes, eight had AVMD in the
right eye, and four had AVMD in the left eye. The
mean age at diagnosis was 71.6 ± 10.1 years (mean
± SD, range: 45.8–90.4 years). There were seven
female and nine male patients in the study. Across
all patients, the mean follow-up time was 28.5 ±
17.6 months (mean ± SD, range: 0–51.3 months).
Three patients had a history of diabetes mellitus
type 2 (DM2), but only one eye had evidence
of diabetic retinopathy and was diagnosed as
mild non-proliferative diabetic retinopathy without
macular edema. Three patients had central serous
chorioretinopathy (CSCR) on the differential, and
17 eyes had a prior history of dry AMD of which
1 eye had a history of wet AMD in the non-AVMD
eye. Nine (9/14, 64%) patients were symptomatic
with either blurry vision or metamorphopsia at
diagnosis.

Three patients received an injection prior to
diagnostic confirmation of AVMD. Among these
individuals, the mean follow-up time was 44.5
± 4.3 months. The BVCA of these patients at
presentation was 0.13 ± 0.23 LogMAR (20/26) and
at the final follow-up 0.19 ± 0.25 LogMAR (20/30).
At one month prior to injection, the BCVA was
0.19 ± 0.2 LogMAR (20/30) and by one month
post-injection the BCVA was 0.22 ± 0.16 LogMAR
(20/33).

Imaging Characteristics

Of the 22 eyes, 10 (45%) had a diagnosis of AVMD
with concurrent SRF. One eye had SRF without
a diagnosis of AVMD but had a diagnosis of wet
AMD in that eye (see Patient 7 clinical course).
There were four eyes with PEDs at diagnoses. No
eyes with AVMD had the presence of IRF with
SRF. Drusen was found in 13 eyes (59.1%) clinically,
and in 15 eyes (68.2%) on OCT. Drusen was found
bilaterally in nine patients on OCT. In 10 eyes with
SRF, all but one eye had drusen, and three of these
eyes were considered to be possibly consistent
with CSCR but the diagnosis was not supported by
FA. Among the patients with SRF, the total follow-
up time was 35.2 ± 13.3 months. The average VA
at presentation was 0.16 ± 0.13 LogMAR (20/28)
and 0.19 ± 0.15 LogMAR (20/30) at final follow-up.
In six eyes (6/10, 60%), the SRF was present on
the first visit. SRF was bilateral in one patient. The
average time to occurrence of the first SRF was
3.6 ± 5.6 (0–16) months and the average time it

took for the disappearance of the first occurrence
of SRF was 7.6 ± 5.6 months (0.9–14.2) months.
In two eyes, the SRF did not disappear. Of these
two eyes, in one eye the SRF was approximately
the same size during the course of their follow-up
over the period of one year, and in the other eye,
it decreased in size but never fully resolved. While
9 of the 10 eyes showed decrease in the SRF over
the course of their follow-up, 4 of these eyes had
recurrence of the SRF, and the recurrence occurred
in the same location as the initial location of SRF in
all cases. Also, in three of the four eyes with PED,
the presence of SRF was noted. The most common
location for SRF was sub-foveal at the vitelliform
lesion in 70% of eyes.

Three eyes were given an intravitreal injection
for the presence of SRF. None had a history of
diabetes. In one eye, the SRF resolved after one
month without further recurrence over the course
of follow-up over three years. In one eye, the
SRF resolved within one month, but then later
appeared in the same location a year later and
resolved one month later without injection due
to patient preference. In the third case, the SRF
exhibited no response to the injection and resolved
on its own over the course of one year to later
relapse and remit an additional year later without
further injection. Here we describe some AVMD
cases in further detail to highlight the diagnostic
and therapeutic challenges associated with this
condition.

Case 1: Patient No. 7

A 76-year-old female presented to clinic for blurry
vision in the left eye. She had a prior history
of wet AMD with disciform scar in the right eye.
Her vision on presentation was 20/300 in the
right eye, and 20/50 in the left eye. She reported
metamorphopsia and an abnormal Amsler grid in
the right eye. The anterior segment exam was
notable for 2+ nuclear sclerosis in both eyes.
Funduscopic examination demonstrated a macular
disciform scar, and a peripheral choroidal nevus
in the right eye. The left eye was notable for
drusen in the macula. On OCT, the right eye
demonstrated chronic changes from wet AMD
notable for subretinal hyperreflective material,
SRF, intraretinal fluid, and distorted foveal contour
[Figure 1A]. In the left eye, there was a small pocket
of SRF, with adjacent hyperreflective materials
at the level of RPE, drusen, and ERM [Figure

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Acquired Vitelliform Macular Degeneration; Juliano et al

1B]. Given the clinical picture and history of wet
AMD in the right eye, the patient was treated
with an intravitreal injection of ranibizumab with
a presumptive diagnosis of wet AMD in the left
eye.

One week later, BCVA was unchanged at 20/60
and OCT showed little to no change suggesting the
diagnosis of AVMD consistent with OCT findings
[Figure 1C]. Soon after, she received cataract
extraction with intraocular lens implantation and
her vision improved to 20/30. Over the course
of follow-up, the vitelliform lesion stayed largely
stable with relapsing and remitting SRF without
further injection. Four years later, during one
follow-up visit there was new SRF in the left eye
which was more SRF than seen at presentation
[Figure 1D]. FA was performed which showed
stippled staining and leakage [Figure 1E]. Given a
suspicion of wet AMD, the patient was offered a
repeat trial of anti-VEGF injection, but she elected
to be observed. By the next follow-up in one
month, the SRF had resolved on its own [Figure
1F]. At the time of last follow-up, five years after
presentation, the patient continued to have no
evidence of SRF on OCT and the hyperreflective
materials and foveal drusen resolved in the left eye
[Figure 1G]. Her visual acuity at final follow-up was
20/500 in the right eye and 20/30 in the left eye.
Throughout the course of her follow-up, despite
the relapsing and remitting SRF in the left eye,
she was asymptomatic and without abnormalities
in her Amsler grid at each follow-up in the left
eye.

Case 2: Patient No. 12

A 67-year-old female presented for establishing
care. She had a history of dry AMD in the
right eye and a presumed recent diagnosis of
wet AMD in the left eye for which she had
received a total of three monthly bevacizumab
injections. Her last injection was three months prior
to presentation [Figure 2A]. At presentation, the
patient had a VA of 20/30 and 20/25 with normal
intraocular pressure. She was asymptomatic in the
left eye with a normal Amsler grid. An evaluation
of past medical records and prior OCT and
OCTA images did not show features of CNV,
therefore the prior diagnosis of wet AMD was
put in question. The patient was followed with
serial OCTs without change until eight months
later when the OCT showed appearance of small

pocket of SRF with an adjacent shallow PED
in the left eye [Figure 2B]. The OCT changes
did not support presence of wet AMD; however,
given her presumed history of wet AMD, the
patient was offered a trial injection of anti-VEGF
or observation. The patient opted to observe and
the SRF resolved spontaneously a month later
[Figure 2C]. Two years after presentation, the
patient had a recurrence of SRF and appearance
of hyperreflective materials [Figure 2D]. After
this recurrence of SRF, the SRF was somewhat
persistent but was significantly reduced in size
as the hyperreflective material began to coalesce
and condense at last follow-up three years after
presentation [Figure 2E]. At the time of last follow-
up, the vision was 20/25 in both eyes. Throughout
the course of her follow-up, she denied complaints
of metamorphopsia and had a normal Amsler
grid.

Case 3: Patient No. 11

A 79-year-old female presented to retina clinic for
evaluation of AMD in both eyes. VA at the time of
diagnosis was 20/40 in the right eye and 20/50 in
the left eye. She had symptomatic complaints of
“mild fuzzy vision” in both eyes over the past year
with some subjective complaints of wavy lines in
both eyes. The Amsler grid was abnormal focally
at one spot temporally on each eye. IOP and
the anterior exam was unremarkable. Her fundus
exam showed dry AMD in both eyes, a choroidal
nevus in the left eye and a vitelliform lesion in
the right eye just nasal to the fovea [Figure 3A].
Over the course of two-year follow-up, the patient
developed significant progression of the vitelliform
lesion in the right eye and trace SRF within the
lesion [Figure 3B]. Based on the characteristic
appearance of AVMD in this patient, she was
observed without injection. At the day of last follow-
up, three years after her first presentation, she
had a stable small SRF and a vitelliform lesion
[Figure 3C] that was observed without injection.
Her vision on final follow-up was 20/50 in the
right eye and 20/40 in the left eye. Over the
course of her follow-up, she reported occasional
metamorphopsia in the right eye with a consistently
abnormal Amsler grid; while in the left eye it
appeared to be normal for the course of her follow-
up after her first abnormal Amsler grid on initial
presentation.

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Table 1. Clinical and imaging characteristics at diagnosis and last visit

Patient
number –
Eye involved

Age at
Dx/Sex VA at Dx Last VA Concurrent retinal pathology

FUT
(mo)

SRF
D

SRF
L PED

Drusen
fundus

Drusen
OCT

1 – OD
1 – OS 79/M

20/40
20/60

20/40
20/60

Dry AMD
Dry AMD 46

–
–

–
–

+
–

+
+

+
+

2 – OD 45/F 20/20 20/20 – 3 – – – – –

3 – OS 57/F 20/30 20/30 Asteroid hyalosis 51 + – + – –

4 – OD
4 – OS 76/F

20/40
20/100

20/40
20/100

Dry AMD
Dry AMD 0

–
–

–
–

–
–

+
–

–
–

5 – OD 66/M 20/30 20/30 – 0 – – – – –

6 – OD
6 – OS 68/F

20/25
20/30

20/25
20/30

Dry AMD
Dry AMD 41

+
–

–
–

–
–

–
+

+
+

7 – OS 76/F 20/60 20/30 Dry AMD 47 + – – + +

8 – OD 76/F 20/30 20/30 Dry AMD, ERM 32 + – – – +

9 – OD 63/F 20/20 20/20 Dry AMD 40 + – + + +

10 – OD 67/M 20/40 20/70 Dry AMD 34 + – – + +

11 – OD
11 – OS 80/F

20/40
20/50

20/50
20/40

Dry AMD
Choroidal nevus OS, Dry AMD 33

+
–

+
–

–
–

+
+

+
+

12 – OS 65/F 20/25 20/25 Dry AMD 47 – – + + +

13 – OD 90/M 20/40 20/30 Dry AMD 20 – + – + +

14 – OD
14 – OS 62/M

20/20
20/20

20/20
20/20 HTN retinopathy 38

–
–

–
–

–
–

–
–

–
–

15 – OD 83/F 20/25 20/25 Dry AMD, Mild NPDR, No DME 24 – – – – +

16 – OD
16 – OS 73/M

20/40
20/20

20/40
20/20

Dry AMD, CSCR
Dry AMD, CSCR 8

–
–

–
+

–
–

+
+

+
+

Dx, diagnosis; M, male; F, female; VA, visual acuity; FUT, follow-up time; mo, months; SRF, subretinal fluid; D, diagnosis; L, last
visit; PED, pigment epithelial detachment; OCT, optical coherence tomography; OD, oculus dexter; OS, oculus sinister; AMD,
age-related macular dystrophy; Hx, history; POAG, primary open angle glaucoma; ERM, epiretinal membrane

Case 4: Patient No. 3

A 57-year-old male presented for retinal evaluation
and establishing care. One and a half years prior
to presentation, he had received an unknown
injection in the left eye by a different provider.
Presenting visual acuity was 20/20 in the right
eye and 20/30 in the left eye. IOP and anterior
exam was unremarkable. The patient complained
of symptomatic distortion in the left eye and
had an abnormal Amsler grid. On funduscopic
examination, the patient had RPE mottling in the
right eye and a vitelliform lesion in the left eye
[Figure 4A]. While the patient appeared to have SRF
in the left eye that could be consistent with CSR
or vitelliform, by FA it appeared the pattern was
less characteristic for CSR or CNV [Figure 4B]. On
OCT, the right eye was unremarkable but the left

eye demonstrated AVMD with the presence of SRF
[Figure 4C]. Given the characteristic appearance for
vitelliform lesion, the lesion was observed without
injection. Over a period of two years without
injection, the vitelliform lesion coalesced, and the
SRF resolved spontaneously [Figure 4D]. By follow-
up at five years from the initial presentation,
the vitelliform lesion had collapsed [Figure 4E].
Throughout the course of the follow-up, the patient
reported improvement of vision in the left eye with
a final visual acuity of 20/30 (and 20/30 in the right
eye) but continued complaints of metamorphopsia
and abnormal Amsler grid in the left eye.

DISCUSSION

There is a considerable diagnostic challenge with
AVMD. Given the older average age, presence

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Figure 1. Patient number 7 clinical course. (A) OCT of the right eye demonstrating end-stage wet AMD with CNV, subretinal
hyperreflective material notable for fibrosis, fluid and distorted retinal contour. (B) OCT of the left eye at presentation was notable
for a vitelliform lesion with associated subretinal fluid. (C) One week after treatment with ranibizumab demonstrating persistent
subretinal fluid and vitelliform lesion. (D) Four years later, new SRF appeared in the left eye adjacent to the persistent vitelliform
lesion, but at that time there was no evidence of CNV by FA (E). (F) One month later, the SRF disappeared without any injections.
(G) One year later, the vitelliform lesion regressed completely.

of drusen in a large percentage of patients with
AVMD, distinction from dry AMD is challenging.
While modern multimodal imaging remains
helpful, there is not a single diagnostic test or
imaging modality that can provide a definitive
diagnosis. Worse yet, at times subretinal fluid
(SRF) accompanies AVMD lesions which presents
a diagnostic dilemma to the clinician: Does this
represent progression from dry to wet AMD, or
simply SRF associated with AVMD? In this study
we focused on acquired vitelliform lesions that
presented diagnostic challenges as a result of the
association of SRF with these vitelliform lesions.

The characteristic lesion appearance of AVMD
on ophthalmic exam is a yellow, elevated lesion
approximately 1/3 to 1 disc diameter in size[13] with
the presence of nonhomogenous hyperreflectivity
that accumulates within the subretinal space, in
contrast to the appearance of PED or drusen
which accumulate below the level of the RPE.
These lesions appear similar to the vitelliform

lesions found in Best disease but unlike hereditary
vitelliform diseases, acquired diseases appear in
a much older demographic, typically around 70
years of life.[7] The yellow appearance is a result
of a particular amount of accumulated loose
lipofuscin and photoreceptor debris.[5] SRF in this
entity is considered to be a result of mechanical
displacement between the outer retinal layers
and the RPE[10] inhibiting the RPE from pumping
out the liquified lipofuscin debris. Alternatively, it
may represent incompetent RPE unable to move
fluid into the choriocapillaris. Visual acuity tends
to typically remain good at presentation despite
the vitelliform lesion at the fovea. In one study
of 17 eyes, among eight patients with AVMD,
the median VA acuity was 20/40 at presentation,
and by final follow-up 71% retained vision within
one to two lines of their initial visual acuity.[7]
These characteristic features were similar to our
study. The mean age of our patient population
on diagnosis was 72 years and the median

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Figure 2. Patient number 12 clinical course. (A) OCT on presentation, three months after a previous injection of bevacizumab for
presumed diagnosis of wet AMD by an outside provider. (B) Eight months after no treatment for the SRF, patient presents with
new-onset SRF adjacent to a small PED. The patient was offered an injection but elected to observe; one month later, the SRF
spontaneously resolved (C). (D) New-onset SRF which continued to relapse and remit over the course of her follow-up, but three
years after her initial presentation (E) the vitelliform lesion condensed as well as the SRF.

Figure 3. Clinical course for patient number 11. (A) Vitelliform lesion on presentation in the right eye. (B) Two years later, progression
and enlargement of the vitelliform lesion with the presence of trace subretinal fluid. (C) Observed without injection over the course
of three years and demonstrates stability of the vitelliform lesion and SRF.

visual acuity in our study at both diagnosis and
final follow-up was approximately 20/29 over an
average follow-up interval of approximately 2.4
years. Although we suspect that the average visual
acuity was similar to presentation because during
the course of their follow-up patients underwent
cataract extraction.

The appearance of these lesions, particularly
in the context of dry AMD, can be concerning
for progression to CNV, and ancillary imaging
such as OCT and FA can be particularly useful.
Other studies have noticed a presence of drusen
anywhere between 33 and 60% of patients
concurrently diagnosed with AVMD.[2, 14, 15]
Our patients similarly had concurrent macular

degeneration which made the diagnosis
challenging. Of the 22 eyes, 17 (77%) had
concurrent diagnosis of dry AMD in addition
to a diagnosis of AVMD. Additionally, 68.2% had
drusen notable on OCT. The vitelliform lesion
itself may have pigment which can be helpful in
differentiating from CNV. In vitelliform lesions, the
pigment is located centrally and surrounded by a
hypopigmented halo. The vitelliform lesions tend
to be less vascular and demonstrate decreased
density of blood vessels at the superficial, deep
capillary plexus and choriocapillaris[16] thought
to be a result of accumulation of the vitelliform
material that physically displaces the capillary
network. In our study, we used OCTA in some

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Figure 4. Clinical course of patient 3. (A) Vitelliform lesion in the left eye. (B) FA showing staining and leakage of the vitelliform
lesion without evidence of CNV. (C) Vitelliform lesion in the left eye with associated SRF. Given the appearance of VM, the patient
was observed without injection. Two years later (D), the vitelliform lesion coalesced and the SRF resolved spontaneously. (E) Five
years after from presentation, the vitelliform lesion spontaneously collapsed.

cases with SRF but failed to detect any CNV.
Additionally, no eyes with AVMD were found
to have concurrent SRF and IRF which further
decreased the likelihood of fluid caused by
CNV.

We relied predominately on funduscopic
exam and OCT to assess and diagnose AVMD.
Characteristically, the lesion is located in
the subretinal space between the RPE and
neurosensory retina[17] which is where our lesions
were predominately located as seen in the patient
images throughout this study. We found the
existence of PED in four eyes in our study (18%),
and SRF in 10 of 22 eyes (46%) which was a
bit higher than other studies identifying PEDs

in approximately 7–8% of eyes;[8, 9] and another
study demonstrating 21.1% of eyes had evidence
of SRF associated with the acquired vitelliform
lesions.[8] In this study, the majority of eyes with
SRF also had drusen. Notably, among all eyes
but one (a patient with wet AMD), there was no
SRF in the fellow eye unless a vitelliform lesion
was present which suggests that the SRF was
likely due to vitelliform material accretion and
was unlikely to have developed due to other
conditions such as diabetes or undiagnosed
inflammatory/infectious diseases. We showed
that the SRF tended to be located sub-foveally
adjacent to the area of the vitelliform lesion, and
when the fluid recurred as found in 40% of patients

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Acquired Vitelliform Macular Degeneration; Juliano et al

with SRF, it was located in the same location as on
presentation.

The impact of anti-VEGF in these lesions remain
unclear and current literature offers no consensus
on their benefit in this disease entity. In one case
report, only one injection of bevacizumab was
done and over time, the SRF decreased,[18] while in
another case report, there was little improvement
with these lesions.[19] As a result of the diagnostic
confusion regarding AVMD, patients often receive
many anti-VEGF agents prior to finally being
diagnosed with AVMD. In one study, six patients
were initially diagnosed to have occult CNV from
AMD and were not diagnosed with AVMD until after
finishing a series of three injections of ranibizumab
with little response on OCT.[20] In our series, we
report the results of three patients who were
given anti-VEGF injections (two with bevacizumab,
one with ranibizumab) because AVMD could not
be differentiated from wet AMD. In this study,
we predominately used the response of anti-
VEGF to gauge whether the SRF accumulation
was a result of progression to wet AMD or the
coexistence of SRF with AVMD. There was no
clear response to anti-VEGF injections, and most
often the SRF resolved spontaneously without the
use of injections. Among those that did have an
injection, in one eye the SRF resolved, but in
the other two it either exhibited no response,
or relapsed and remitted even without further
use of injections as illustrated by Cases 1 and
2.

We suggest that while the use of anti-VEGF
may not be useful to treat these patients, a
treatment trial can be useful in difficult situations
where there is a suspicion of AVMD in the setting
of new onset SRF. Current diagnostic modalities
such as genetic testing are often impractical for
the patient presenting in clinic with SRF. FA and
OCTA can be useful to characterize the presence
of CNV, however, they may still have difficulty
detecting occult CNV. In our study, there was
leakage on FA even in the absence of CNV.
In these uncertain diagnostic situations, a clear
discussion with the patient can help delineate
appropriate management options. There are two
options that can be presented: one is to monitor
closely and start treatment when the SRF continues
to increase and the patient becomes symptomatic.
The other option is to give the patient an anti-VEGF
injection and bring the patient back in one to two
weeks to determine the response. If the SRF has

either been unchanged or only minimally changed,
the patient can be presumptively diagnosed with
AVMD and monitored closely. If the fluid does
resolve after the first injection, it is possible
that this patient has CNV. As illustrated by
case 2, however, SRF may spontaneously resolve
on its own without injection, so if an injection
is given and the fluid resolves, it may be a
result of the natural history of relapsing and
remitting SRF in AVMD rather than the effect of
the injection itself. Thus, periods of anti-VEGF
holidays may be helpful to distinguish between
AVMD and AMD. Recurrence or worsening of
fluid would be suggestive of AMD, whereas
resolution or stability of fluid would be suggestive
of AVMD.

In summary, the diagnosis of AVMD can be
challenging given its heterogenous appearance.
When SRF develops, these cases provide a
diagnostic dilemma to the clinician who may
suspect possible progression to wet AMD. We
suggest close observation or a trial of anti-VEGF
for the SRF and re-evaluation in one to two
weeks. If there is no response to an injection, then
consider observing the SRF rather than providing
repeated monthly treatments. Further work is
needed to properly differentiate the heterogenous
appearance of these disease processes and the
response to anti-VEGF agents in order to avoid
unnecessary treatment.

Financial Support and Sponsorship

The authors received no financial support for the
research, authorship, and/or publication of this
article.

Conflicts of Interest

The authors declare no potential conflicts of
interest with respect to the research, authorship,
and/or publication of this article.

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