Perspective

Challenges and Pitfalls in the Management of
Rhino-Orbital Mucormycosis in Ophthalmology: A

Highlighted Problem in the COVID-19 Era

Farzad Pakdel1, MD; Amin Zand2, MD; Ali Sharifi2, MD; Masih Asadi3, MD; Kaveh Abri Aghdam3, MD, PhD

1Department of Oculo-Facial Plastic Surgery, Department of Ophthalmology, Farabi Hospital, Tehran University of Medical
Sciences, Tehran, Iran

2Department of Ophthalmology, Shafa Hospital, Kerman University of Medical Sciences, Kerman, Iran
3Eye Research Center, Eye Department, The Five Senses Health Institute, School of Medicine, Iran University of Medical

Sciences, Tehran, Iran

ORCID:
Farzad Pakdel: https://orcid.org/0000-0001-7392-6056

Kaveh Abri Aghdam: https://orcid.org/0000-0001-7568-6455

Abstract

Secondary infections in hospitalized and ill patients with coronavirus disease
2019 (COVID-19) are common. One of these life-threatening infectious diseases
is rhino-orbital mucormycosis, which made an outbreak recently. This outbreak
was mainly caused by the administration of high-dose corticosteroids in
patients with COVID-19, especially those with diabetes mellitus. The increased
incidence of rhino-orbital mucormycosis in the COVID-19 era presents different
challenges for healthcare providers including ophthalmologists who are directly
involved in disease management. We summarized the main challenges and
recommendations for ophthalmologists on the management of rhino-orbital
mucormycosis.

J Ophthalmic Vis Res 2022; 17 (3): 424–431

INTRODUCTION

The coronavirus disease 2019 (COVID-19)
pandemic has created different challenges for
healthcare systems including the occurrence
of secondary infections in affected patients. In

Correspondence to:

Kaveh Abri Aghdam, MD, PhD. Eye Research Center, Eye
Department, The Five Senses Health Institute, Rassoul
Akram Hospital, Sattarkhan-Niaiesh St. 1449614535,
Tehran, Iran.
E-mail: kaveh.abri@gmail.com
Received: 15-03-2022 Accepted: 16-04-2022

Access this article online

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

DOI: 10.18502/jovr.v17i3.11582

hospitalized and severely ill patients suffering with
COVID-19, secondary infections are more common.
Studies have shown that the incidence of fungal
infections including candidiasis, aspergillosis,
and mucormycosis is cumulatively 10-times
more in these patients.[1–3] Recently, rhino-orbital
mucormycosis impacted a substantial population
in several countries. Some studies estimated

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How to cite this article: Pakdel F, Zand A, Sharifi A, Asadi M, Abri
Aghdam K. Challenges and Pitfalls in the Management of Rhino-
Orbital Mucormycosis in Ophthalmology: A Highlighted Problem in
the COVID-19 Era. J Ophthalmic Vis Res 2022;17:424–431.

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Challenges of Mucormycosis in Ophthalmology; Pakdel et al

the pooled prevalence of COVID-19-associated
mucormycosis much higher than the highest
recorded background of mucormycosis (7/1000
vs 0.14/1000 cases). Most of the cases were
diagnosed several days to a few weeks after
admission for COVID-19.[1–4] Mucormycosis is
a form of Zygomycosis caused by the Mucorales
species of the phylum Zygomycota.[5] It is much
more common in immunocompromised humans,
especially in patients with diabetes mellitus (DM),
leukemia, or lymphoma.[6] The main contributing
factors for this deadly disease in the COVID-19 era
are the presence of pre-existing immunodeficiency
conditions, mainly DM, hematologic, and
solid malignancies, the consumption of
immunosuppressive and immunomodulatory
agents, and the administration of intravenous
corticosteroids. Systemic corticosteroids including
methylprednisolone and dexamethasone are
commonly administered to COVID-19 patients to
reduce lung injury and respiratory failure. Following
a rapid rise in the incidence of the COVID-19 delta
variant in 2021 on an overwhelmed healthcare
system, it was observed that a remarkable number
of patients received unattended prescriptions of
drugs including systemic corticosteroids at home.
In addition, unnecessary treatment as well as
overtreatment using these agents was seen even in
those under professional care.[1–4] We overviewed
different aspects of the challenges and pitfalls in
the management of rhino-orbital mucormycosis
from the ophthalmology perspective.

Which Ophthalmic Findings Are Important
and Helpful for Making the Diagnosis and
Evaluating the Treatment Response in
Follow-up Visits?

There are no definite criteria for the diagnosis and
management of mucormycosis. Based on reported
clinical and paraclinical features of COVID-19-
associated mucormycosis and the available
guidelines for mucormycosis, the following clinical
features should alert the physician for justified
intensive interventions:[2, 6–8]

Sudden decrease of vision in any patient with a
recent COVID-19 diagnosis;

Recent peri-orbital swelling in any patient with a
recent COVID-19 diagnosis;

Orbital or facial pain or headache in any patient
with a recent COVID-19 diagnosis;

Blood mixed with nasal discharge;
Drooping of the eyelid, proptosis of the globe, or

ophthalmoplegia;
Multiple and unrelated palsies of the cranial

nerves;
Black, necrotic tissues in nasal turbinates that

are easily mistaken for crusted blood.
In all patients with mucormycosis, whether the

orbit is involved or not in the imaging studies,
initial and serial comprehensive ophthalmic
evaluations include checking the following: visual
acuity: relative afferent pupillary defect (RAPD);
extraocular motilities; eyelid exam for any subtle
changes (e.g., swelling, erythema, or ptosis); globe
malpositioning such as proptosis; any ocular
surface disorders (e.g., corneal epithelial defects
or conjunctival chemosis); eye globe firmness and
intraocular pressure (IOP); and a funduscopy exam
(for evaluation of optic nerve head, retinal vessels,
and retinal status), which are all necessary to be
performed by ophthalmologists. We have seen
patients with mucormycosis and active proliferative
diabetic retinopathy or glaucoma where these
sight-threatening ophthalmic situations were
missed, because either none or inadequate
ophthalmology examinations were done during
the disease management.

Other symptoms and signs that must be
checked are periorbital, cheek, alveolar, or dental
pain which may radiate to the ear, neck, and
head. Hypoesthesia/anesthesia over the cheek
is a relatively uncommon sign in patients with
rhino-orbital mucormycosis and represents the
involvement of the infraorbital nerve. Investigation
of the hard and soft palate and gingiva mucosa
for any necrotic tissue is also helpful for diagnosis.
Patients must be visited frequently during the
treatment period to assess their response to the
treatments and make immediate decisions for
further interventions.

What Are the Imaging Findings of Rhino-
Orbital Mucormycosis?

There are no specific signs of rhino-orbital
mucormycosis in the computed tomography
(CT) scans and magnetic resonance imaging
(MRI) of the paranasal sinuses (PNS) and orbit.
Mucosal thickening with mild and heterogeneous
enhancement in post-contrast PNS CT scans could
be seen. Another feature that may be revealed

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Challenges of Mucormycosis in Ophthalmology; Pakdel et al

by the imaging is the orbital abscess and its soft
tissue thickening. Orbital bony destruction is not
common. Isodense lesions relative to muscle/brain
and isointense lesions relative to the brain in T1-
weighted images are seen on the CT scan and MR
images of most patients, respectively, however,
the signal intensity in T2-weighted images is
variable.[9]

The combination of CT scans and MRIs helps
the physician to make a more accurate diagnosis
and evaluation of the extension of involvement.
In patients with signs of intracranial or skull
base involvement in imaging (e.g., involvement
of pterygopalatine fossa or cavernous sinus),
immediate interventions including administration
of high doses of an antifungal drug, salvage
combination therapy, and surgical debridement
should be considered.[2]

Be Aware of Masquerading Diseases!

Abscess formation, tumors (benign or malignant),
and other infectious diseases like bacterial or
other fungal sinusitis may mimic symptoms and
signs of rhino-orbital mucormycosis. Therefore,
complete investigation including CT scans and
MRIs of the PNS, orbital cavities, and brain, as well
as performing a nasal endoscopy are imperative
in patients suspicious of having rhino-orbital
mucormycosis. Some reports have also shown
concomitant mucormycosis with other fungal
species including aspergillosis and candidiasis,
especially in immunocompromised patients.[10, 11]
These situations need combined anti-fungal drugs
administration to treat the diseases.

Is Empirical Therapy Recommended?

Although all suspected cases of rhino-orbital
mucormycosis need to be confirmed by
positive culture and histopathological changes,
any delay in the disease management may be
associated with irreparable morbidities. On the
other hand, medical treatment with antifungal
drugs may have serious and even fatal side
effects in some patients with certain underlying
diseases. In addition, administration of empirical
antifungal treatments for suspected patients may
have considerable cost to them, especially in low-
income countries.[12, 13] Therefore, the decision for
empirical therapy remains an important challenge

for clinicians; multidisciplinary team working for
proper diagnosis of disease in suspected cases
is also recommended, emphatically. Logically,
in suspected cases with disseminated and life-
threatening diseases (including cases with signs
of intracranial involvement), treatment must be
initiated as soon as possible along with the control
of other underlying diseases.

How to Initiate Treatment?

Treatment of rhino-orbital mucormycosis is a
combination of surgical debridement of the
involved tissues and medical therapy with
antifungal drugs. In addition, risk assessment is an
important issue in the control of the disease.[8]
Consultation with an internist is necessary
to control serum glucose levels and diabetic
ketoacidosis (DKA). Blood glucose monitoring is a
logical step during the treatment.

The drug of choice for initiation of treatment
is intravenous amphotericin B. It is a polyene
antifungal drug that binds with ergosterol on the
fungal cell membranes, forming pores in them and
leading to cell death. The drug has two main
forms, deoxycholate (conventional) and liposomal.
The liposomal form of the drug is superior to
the deoxycholate form, because its toxic effects
on organs (including the kidney) are fewer, and
its efficacy and penetration into the blood–brain
barrier and distribution throughout the central
nervous system is also more than that of the
deoxycholate form.[14]

This drug has frequent and significantly
adverse effects that need careful monitoring
by multiple disciplines including infectious
diseases specialists, internists, nephrologists,
hematologists, and clinical pharmacologists.
Amphotericin B can cause urinary potassium
wasting and hypokalemia. So, the drug must
be administered slowly with vital signs and
cardiac monitoring. Other renal complications
of the drug are urinary magnesium wasting
and hypomagnesemia, metabolic acidosis, and
polyuria due to nephrogenic diabetes insipidus.[14]

Due to these adverse effects, serial visits by
internists and regular checking of blood pressure,
serum potassium (K) and magnesium (Mg), atrial
blood gas (ABG), regular renal function laboratory
tests including blood urea nitrogen (BUN) and
serum creatinine (Cr) are recommended.

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The correct dosage preparation of the drug
is important in preventing lethal consequences
of a drug overdose. The recommended dosage
of liposomal amphotericin B for the treatment of
rhino-orbital mucormycosis is varied – between 3.0
and 5.0 mg/Kg/day. This dose can be increased
to 10 mg/Kg/day for patients with intracranial
involvement. The recommended dosage for
the deoxycholate (conventional) form is 0.5–1.0
mg/Kg/day.[14] So, the dosage of the deoxycholate
form is about one-fifth of the liposomal form.
This significant difference is very important
and needs to be taken into account during
the preparation of the deoxycholate form to
prevent the lethal consequences of ingesting an
inaccurate dosage. Some reports of cardiac arrest
and mortality following amphotericin B overdoses
have been reported.[15] Cardiac toxicity is a rare but
potentially lethal adverse effect of amphotericin
B administration. Ventricular arrhythmias and
bradycardia have been reported not only in
acute overdose but even with correct dosage
with slow rates of drug infusion.[16, 17] Previous
studies showed the drug itself could be cardiotoxic
and these complications were reported even in
patients with a normal concentration of potassium
and magnesium.[18]

The drug could be embryotoxic if administered
during pregnancy. The drug is classified as a
pregnancy category B by the United States Food
and Drug Administration (FDA).[19] An experimental
study showed that 0.5 mg/kg of amphotericin
B and 2 mg/kg of its methyl derivative can be
embryotoxic in rats.[20] So, in pregnant and lactating
women with rhino-orbital involvement, treatment
initiation with amphotericin B must be done
with excessive caution using as low as possible
doses. Therefore, planning for the administration
of alternative antifungal drugs that have fewer
adverse effects must be considered in particular
cases.

When Are Combined Antifungal Treatments
Suggested?

Few studies have shown that combination therapy
with triazoles and polyenes in patients with
disseminated mucormycosis (e.g., intracranial
involvement), especially in neutropenic or DKA
patients can be beneficial.[21] The suggested drugs
to be added to amphotericin B therapy are:

Caspofungin: Combination therapy with
caspofungin was associated with significantly
improved survival for patients with DKA and rhino-
orbito-cerebral mucormycosis.[22] The evidence for
use in humans is still weak.

Micafungin: Combination therapy with
micafungin improved survival in neutropenic and
DKA mice with disseminated mucormycosis.[23]
The evidence for use in humans is still weak.

Posaconazole: Combination therapy with oral
posaconazole in febrile neutropenic patients with
disseminated infection can significantly improve
the survival rate.[24]

Isavuconazole: It has shown activity
against mucormycosis with efficacy similar to
amphotericin B. Isavuconazole can be used
in combination with amphotericin B for the
treatment of rhino-orbital mucormycosis.[25] In
addition, posaconazole or isavuconazole can be
administrated as salvage therapy for patients who
do not respond to or cannot tolerate amphotericin
B.[8]

How Long Is the Duration of Treatment?

After the achievement of acceptable clinical
responses to the administration of intravenous
liposomal amphotericin B, which usually takes
more than three to six weeks, patients can be
switched to oral posaconazole or isavuconazole as
step-down therapy.[6] Treatment must be continued
until the resolution of the clinical and radiographic
signs of the active disease. It is important to control
the underlying causes of the immunosuppression
conditions, before treatment cessation.

When Is Surgical Debridement Necessary?

Necrotic and infected areas in the nasal cavity
and PNS should be extensively debrided. Necrotic
areas in the orbit and brain may also be debrided
limitedly when appropriate. Ophthalmology and
otolaryngology consultations are necessary in all
suspicious cases of rhino-orbital mucormycosis.
Early surgical interventions in PNS (e.g., functional
endoscopic sinus surgery: FESS) is one of the
essential steps in establishing the diagnosis (by
finding necrotic tissues and making specimens
for the potassium hydroxide [KOH] wet mount
and mycology staining and cultures) and also
limiting the disease progression by debridement

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of necrotic tissues from PNS cavities in early
phases. Repetition of PNS mucosa debridement is
necessary in progressive and severe cases.[26]

Is Regular Irrigation of the Nasal Cavity and
PNS with Amphotericin B Recommended?

Some studies showed that nasal irrigation with 100
or 200 μg/mL of amphotericin B did not create a
greater benefit than using normal saline solution
after PNS debridement surgery.[27, 28] According
to the results of an in vitro study, irrigation of
growth media plates embedded with 10 species
of fungi commonly found in the nasal cavity,
with 20 mL of amphotericin B at concentrations
of 200 or 300 μg/mL (twice per day for six
weeks), prevented fungal growth successfully.[29]
Therefore, the possible benefits of this route
of amphotericin B administration are limited and
adjuvant regular irrigation of the nasal cavity and
PNS with the drug is controversial.

When Are Topical Medications for the Ocular
Surface Problems Necessary?

In patients with orbital mucormycosis, ocular
surface complications including dry eye, corneal
epithelial erosions and defects, and conjunctival
chemosis must be managed carefully with topical
lubricants, emollients, and antibiotics.

When Is the Retrobulbar Injection of
Amphotericin B Indicated?

Retrobulbar injection of amphotericin B may
facilitate improvement of orbital mucormycosis,
in combination with systemic antifungal
drugs, and reduce the rate of aggressive
interventions including orbital tissues debridement
or exenteration. Retrobulbar injections of
amphotericin B are recommended in patients
with signs of optic nerve compression including
progressive decrease in visual acuity and positive
RAPD. In addition, this route of drug administration
is recommended when other symptoms and signs
of orbital involvement including pain, proptosis,
globe firmness, limitation of extraocular motility
or conjunctival chemosis, and ocular surface
exposure have progressed despite complete
systemic medical and surgical interventions.[30]
This route of drug delivery is reported to be

effective in the improvement of cerebritis
in patients with intracranial involvement.[31]
Retrobulbar injection of the drug is a suitable
treatment option for cases in which orbital surgical
intervention is not possible, especially for patients
admitted to an intensive care unit (ICU). In the
COVID-19 era, a high portion of cases were ICU-
admitted and were not candidates for surgical
intervention (including FESS and orbital surgery).
Therefore, this route of administration is a good
and superior choice for that group of patients.
Reports showed that well-timed decisions for
this type of drug administration is important to
achieve acceptable results. The recommended
dosage for the retrobulbar injection is 3.3–3.5
mg/1 ml of liposomal (preferred) amphotericin
B. There is no protocol for the frequency of the
drug injections, but some reports recommended
injections at least three times during the course
of three days, continuously.[32] However, this route
of drug administration has some limitations. First,
retrobulbar injections are a risky intervention that
may cause globe perforation by the syringe
needle, retrobulbar hemorrhage, and even
inadvertent drug administration to the brain
stem. Second, amphotericin B is neurotoxic, and
this toxicity is much higher in the conventional
form of the drug as compared to the liposomal
form.[32, 33] Therefore, even with the administration
of a correct dosage of liposomal amphotericin
B, the possibility of the occurrence of toxic optic
neuropathy should be considered. Third, in some
reports, the retrobulbar injection of the drug
caused orbital compartment syndrome.[34] Fourth,
local injection of amphotericin B (especially the
deoxycholate form) may induce inflammation
by causing soft-tissues edema, especially
after the first injection.[14] However, this side
effect is usually transient and self-limited. Fifth,
amphotericin B has a high molecular weight and
drug distribution in orbital connective and fatty
tissues is slow and limited.[32] As a consequence,
multiple injections are necessary and logical.
The previously mentioned adverse effects limit the
frequencies of the drug administration to the orbital
cavity via the retrobulbar route. The senior author
(FP) has gained experience with the administration
of a higher frequency of injections at different
levels of dosages. It should be mentioned that the
retrobulbar injection of amphotericin B is rapidly
becoming a standard practice.

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What Is the role of Conservative Orbital
Debridement and Adjuvant Local
Amphotericin B Irrigation?

In a retrospective study by Seiff et al, on seven
immunocompromised patients with rhino-orbital
mucormycosis and good visual acuity, surgical
debridement of necrotic tissue of the involved
PNS and orbits were done. Then, a catheter was
inserted and placed into the orbital cavities for
regular irrigation of them with amphotericin B
solution (with volume of 3–4 ml, and concentration
of 0.25–1.00 mg/ml, four times per day, for 5–14
days). They claimed this technique improved
the therapeutic outcomes. Joos et al reported
successful management of a patient with rhino-
orbital mucormycosis with the similar technique
(surgical debridement of necrotic tissues, and
then regular irrigation of the involved orbital cavity
with 5 ml [1 mg/ml] non-liposomal amphotericin
B, once a day for seven days).[35, 36] Nowadays,
this technique is not popular among oculoplastic
surgeons, because the benefits of this technique
in comparison to its potential risks are low.
Some of these potential risks are including
uneventful and iatrogenic harms to the orbital
components (e.g., nerves and extraocular
muscles), creating a route for the entrance of
other pathogens, and possible ocular toxicity by
the drug. Moreover, the sufficiency of the whole
necrotic tissue debridement process and the
adequate distribution of the drug into the orbital
cavity is under question.

When Is Orbital Exenteration Indicated?

One of the most challenging decisions in the
management of orbital mucormycosis is planning
for exenteration in those cases where the
nature of the disease is life-threatening. Here,
the main questions are whether exenteration
can reduce the mortality rate and whether the
benefits of exenteration are satisfactory enough
against its lifetime disabling effects. There is
no standard protocol for choosing to perform
orbital exenteration in patients with rhino-orbital
mucormycosis; it is mainly dependent on the
judgment of the physician. The most important
deciding factors for performing exenteration
in patients with orbital mucormycosis are the
presence of ophthalmoplegia and cranial nerves
palsy, proptosis, ocular tissues involvement,

progressive visual impairment or vision loss,
general necrosis of the orbital cavity and its
adnexa, major immunosuppressive conditions
including underlying diseases and neutropenia,
cerebral extension, prolonged disease despite
adequate medical and surgical interventions,
and unsatisfactory response to the initial
treatments.[37, 38]

Generally, in cases resistant to all medical and
surgical interventions with progressive signs and
symptoms of the disease, especially the probability
of intracranial involvement and fulminant
infection, some physicians recommended orbital
exenteration to decrease the mortality risk.
However, a review on indications of orbital
exenteration in patients with mucormycosis
revealed there are no standard guidelines for
making decision of exenteration in these patients.
They showed that just exenterated patients with
fever were more likely to survive compared with
non-exenterated febrile cases.[38]

Which Care Measures Are Necessary After
Orbital Exenteration?

After orbital exenteration, patients need frequent
socket examinations for the occurrence of any
infections including the recurrence of the fungal
infection. The socket should be inspected and
cleaned with diluted betadine solution for the
first three weeks until the surface is adequately
epithelialized. In some patients with superficial
recurrence of mucormycosis, regular irrigation
with an amphotericin B solution is recommended.
Sometimes, debridement of remnant necrotic
tissues of the orbital cavity is necessary.[39]

Many patients will be dissatisfied with the
cosmetic outcomes of the surgery. This condition
creates significant psycho-social challenges for
the patients. Therefore, a counseling plan for the
patients is necessary to rehabilitate their cosmesis.
Prosthetic reconstruction of orbital defects with
facial plastic surgeries is suggested.[40]

Which Variables Are More Important in
Patients’ Survival?

In a review by Hargrove et al,[38] the investigators
revealed that patients aged >46 years with frontal
sinus involvement and fever had less survival rates
in comparison to those without these conditions,

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Challenges of Mucormycosis in Ophthalmology; Pakdel et al

regardless of performing orbital exenteration
in patients with rhino-orbital mucormycosis. In
addition, they showed patients treated with
amphotericin B and those with diabetes were
more likely to survive compared with those without
these conditions.

What Has Been the Impact of the COVID-
19 Pandemic on the Prevalence of
Mucormycosis?

According to a meta-analysis by Hussain et al,[41]
the pooled prevalence of rhino-orbito-cerebral
mucormycosis among hospitalized COVID-19
patients was 7 cases per 1000 patients. This rate
was much higher in comparison to the prevalence
of the disease among comorbid populations
before the COVID-19 pandemic (0.14/1000).[42, 43]
In addition, the estimated global incidence rate of
mucormycosis varies between 0.005 and 1.7 per
million population.[44] Therefore, a very significant
surge in the disease’s prevalence occurred during
the COVID-19 era, and lead to an additional burnout
and workload among healthcare providers. In
conclusion, management of patients with rhino-
orbital mucormycosis is challenging. The first
step is making the accurate diagnosis of the
disease, and differentiate it from other possible
debilitating ocular comorbidities. After making
the diagnosis, well-timed management of the
disease is life-saving, and needs a multidisciplinary
teamwork including infectious diseases specialists,
otolaryngologists, ophthalmologists, and internists.
Due to unpredictable and mysterious progression
of the disease, patients should receive regular
follow-up visits to assess and timely revise the
treatment plan. By considering the important
adverse effects of amphotericin B on serum
electrolytes, heart, and kidney, regular monitoring
(by monitoring the vital signs, laboratory testing,
and electrocardiography) is necessary for these
patients. The current management protocols
of the disease needs review to make them
safer with more cost-effectiveness outcomes
(e.g., focusing on combined systemic antifungal
regimens and locally targeted administration of
the drug in addition to systemic medications). Also,
introducing guidelines for controlling the load of
intravenous steroids (including dexamethasone, or
methylprednisolone) administration in COVID-19
patients seems to be necessary.

Financial Support and Sponsorship

None.

Conflicts of Interest

None.

REFERENCES

1. Singh AK, Singh R, Joshi SR, Misra A. Mucormycosis
in COVID-19: A systematic review of cases reported
worldwide and in India. Diabetes Metab Syndr
2021;15:102146.

2. Pakdel F, Ahmadikia K, Salehi M, Tabari A, Jafari R,
Mehrparvar G, et al. Mucormycosis in patients with COVID-
19: A cross-sectional descriptive multicentre study from
Iran. Mycoses 2021;64:1238–1252.

3. Raiesi O, Hashemi SJ, Mohammadi Ardehali M, Ahmadikia
K, Getso MI, Pakdel F, et al. Molecular identification
and clinical features of fungal rhinosinusitis: A 3-
year experience with 108 patients. Microb Pathog
2021;158:105018.

4. Hoenigl M, Seidel D, Carvalho A, Rudramurthy SM,
Arastehfar A, Gangneux JP, et al. The emergence of
COVID-19 associated mucormycosis: Analysis of cases
from 18 countries [Internet]. SSRN Electron J [Preprint].
2021. Available from: https://doi.org/10.2139/ssrn.3844587.

5. Pak J, Tucci VT, Vincent AL, Sandin RL, Greene JN.
Mucormycosis in immunochallenged patients. J Emerg
Trauma Shock 2008;1:106–113.

6. Cornely OA, Arikan-Akdagli S, Dannaoui E, Groll AH,
Lagrou K, Chakrabarti A, et al. ESCMID and ECMM joint
clinical guidelines for the diagnosis and management of
mucormycosis 2013. Clin Microbiol Infect 2014;20:5–26.

7. Smith HW, Kirchner JA. Cerebral mucormycosis; A report
of three cases. AMA Arch Otolaryngol 1958;68:715–726.

8. Skiada A, Lass-Floerl C, Klimko N, Ibrahim A, Roilides E,
Petrikkos G. Challenges in the diagnosis and treatment of
mucormycosis. Med Mycol 2018;56:93–101.

9. Herrera DA, Dublin AB, Ormsby EL, Aminpour S, Howell
LP. Imaging findings of rhinocerebral mucormycosis. Skull
Base 2009;19:117–125.

10. Singh A, Mohanty A, Jha S, Gupta P, Kaistha N.
Concomitant mucormycosis with aspergillosis in patients
with uncontrolled diabetes mellitus: A case series. J Clin
Diagnostic Res 2021;15:DR01–DR03.

11. Nambiar M, Varma SR, Jaber M, Sreelatha SV, Thomas
B, Nair AS. Mycotic infections - Mucormycosis and oral
candidiasis associated with Covid-19: A significant and
challenging association. J Oral Microbiol 2021;13:1967699.

12. Hoenigl M, Seidel D, Carvalho A, Rudramurthy SM,
Arastehfar A, Gangneux JP, et al. The emergence of
COVID-19 associated mucormycosis: A review of cases
from 18 countries. Lancet Microbe 2022. Available from:
https://doi.org/10.1016/S2666-5247(21)00237-8

13. Darwish RM, AlMasri M, Al-Masri MM. Mucormycosis:
The hidden and forgotten disease. J Appl Microbiol
2022;132:4042–4057.

430 JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 3, July-September 2022



Challenges of Mucormycosis in Ophthalmology; Pakdel et al

14. Hamill RJ, Amphotericin B. Amphotericin B formulations:
A comparative review of efficacy and toxicity. Drugs
2013;73:919–934.

15. Burke D, Lal R, Finkel KW, Samuels J, Foringer JR.
Acute amphotericin B overdose. Ann Pharmacother
2006;40:2254–2259.

16. Soler JA, Ibañez L, Zuazu J, Julià A. Bradycardia after
rapid intravenous infusin of amphotericin B. Lancet
1993;341:372–373.

17. Aguado JM, Hidalgo M, Moya I, Alcazar JM, Jimenez MJ,
Noriega AR. Ventricular arrhythmias with conventional and
liposomal amphotericin. Lancet 1993;342:1239.

18. Laniado-Laborín R, Cabrales-Vargas MN. Amphotericin B:
Aide effects and toxicity. Rev Iberoam Micol 2009;26:223–
227.

19. Pilmis B, Jullien V, Sobel J, Lecuit M, Lortholary O, Charlier
C. Antifungal drugs during pregnancy: An updated review.
J Antimicrob Chemother 2015;70:14–22.

20. Moguchenok EA. [Study of embryotoxic and teratogenic
effects of amphotericin B and a methyl derivative of
amphotericin B in rats after their intravenous and intra-
amniotic administration]. Antibiot Khimioter 1992;37:25–
28.

21. Spellberg B, Ibrahim A, Roilides E, Lewis RE, Lortholary O,
Petrikkos G, et al. Combination therapy for mucormycosis:
Why, what, and how? Clin Infect Dis 2012;54:S73–S78.

22. Spellberg B, Fu Y, Edwards JE Jr, Ibrahim AS. Combination
therapy with amphotericin B lipid complex and
caspofungin acetate of disseminated zygomycosis in
diabetic ketoacidotic mice. Antimicrob Agents Chemother
2005;49:830–832.

23. Ibrahim AS, Gebremariam T, Fu Y, Edwards JE Jr,
Spellberg B. Combination echinocandin-polyene
treatment of murine mucormycosis. Antimicrob Agents
Chemother 2008;52:1556–1558.

24. Ullmann AJ, Cornely OA, Burchardt A, Hachem R,
Kontoyiannis DP, Töpelt K, et al. Pharmacokinetics, safety,
and efficacy of posaconazole in patients with persistent
febrile neutropenia or refractory invasive fungal infection.
Antimicrob Agents Chemother 2006;50:658–666.

25. Marty FM, Ostrosky-Zeichner L, Cornely OA, Mullane
KM, Perfect JR, Thompson GR 3rd, et al. Isavuconazole
treatment for mucormycosis: A single-arm open-label trial
and case–control analysis. Lancet Infect Dis 2016;16:828–
837.

26. Selarka L, Sharma S, Saini D, Sharma S, Batra A,
Waghmare VT, et al. Mucormycosis and COVID-19:
An epidemic within a pandemic in India. Mycoses
2021;64:1253–1260.

27. Jiang RS, Hsu SH, Liang KL, Amphotericin B. Amphotericin
B nasal irrigation as an adjuvant therapy after functional
endoscopic sinus surgery. Am J Rhinol Allergy
2015;29:435–440.

28. Jiang RS, Twu CW, Liang KL. Efficacy of nasal irrigation
with 200 μg/mL amphotericin B after functional

endoscopic sinus surgery: A randomized, placebo-
controlled, double-blind study. Int Forum Allergy Rhinol
2018;8:41–48.

29. Shirazi MA, Stankiewicz JA, Kammeyer P. Activity of nasal
amphotericin B irrigation against fungal organisms in vitro.
Am J Rhinol 2007;21:145–148.

30. Colon-Acevedo B, Kumar J, Richard MJ, Woodward JA.
The role of adjunctive therapies in the management of
invasive sino-orbital infection. Ophthal Plast Reconstr Surg
2015;31:401–405.

31. Safi M, Ang MJ, Patel P, Silkiss RZ. Rhino-orbital-
cerebral mucormycosis (ROCM) and associated cerebritis
treated with adjuvant retrobulbar amphotericin B. Am J
Ophthalmol Case Rep 2020;19:100771.

32. Hirabayashi KE, Kalin-Hajdu E, Brodie FL, Kersten
RC, Russell MS, Vagefi MR. Retrobulbar Injection of
amphotericin B for orbital mucormycosis. Ophthal Plast
Reconstr Surg 2017;33:e94–e97.

33. Harmsen S, McLaren AC, Pauken C, McLemore
R, Amphotericin B. Amphotericin B is cytotoxic at
locally delivered concentrations. Clin Orthop Relat Res
2011;469:3016–3021.

34. Brodie FL, Kalin-Hajdu E, Kuo DS, Hirabayashi KE, Vagefi
R, Kersten RC. Orbital compartment syndrome following
retrobulbar injection of amphotericin B for invasive fungal
disease. Am J Ophthalmol Case Rep 2016;1:8–10.

35. Seiff SR, Choo PH, Carter SR. Role of local amphotericin
B therapy for sino-orbital fungal infections. Ophthal Plast
Reconstr Surg 1999;15:28–31.

36. Joos ZP, Patel BC. Intraorbital irrigation of amphotericin
B in the treatment of rhino-orbital mucormycosis. Ophthal
Plast Reconstr Surg 2017;33:e13–e16.

37. Songu M, Unlu HH, Gunhan K, Ilker SS, Nese N. Orbital
exenteration: A dilemma in mucormycosis presented with
orbital apex syndrome. Am J Rhinol 2008;22:98–103.

38. Hargrove RN, Wesley RE, Klippenstein KA, Fleming
JC, Haik BG. Indications for orbital exenteration
in mucormycosis. Ophthal Plast Reconstr Surg
2006;22:286–2891.

39. Karadeniz Uğurlu Ş, Selim S, Kopar A, Songu M. Rhino-
orbital mucormycosis: Clinical findings and treatment
outcomes of four cases. Turk J Ophthalmol 2015;45:169–
174.

40. Jain S, Jain P. Rehabilitation of orbital cavity after
orbital exenteration using polymethyl methacrylate orbital
prosthesis. J Indian Prosthodont Soc 2016;16:100–104.

41. Hussain S, Riad A, Singh A, Klugarová J, Antony B,
Banna H, et al. Global prevalence of COVID-19-associated
mucormycosis (CAM): Living systematic review and meta-
analysis. J Fungi 2021;7:985.

42. Chander J, Kaur M, Singla N, Punia RP, Singhal SK, Attri AK,
et al. Mucormycosis: Battle with the Deadly Enemy over a
Five-Year Period in India. J Fungi 2018;4:46.

43. Petrikkos G, Skiada A, Lortholary O, Roilides E, Walsh TJ,
Kontoyiannis DP. Epidemiology and clinical manifestations
of mucormycosis. Clin Infect Dis 2012;54:S23–S34.

44. Prakash H, Chakrabarti A. Global epidemiology of
mucormycosis. J Fungi 2019;5:26.

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