1678 PART 5 Infectious Diseases
classified as acute and subacute, with courses of ≤1 month and 1–3 months,
respectively. More than 80% of cases of invasive aspergillosis involve
the lungs, and most are community acquired. The most common clinical features are no symptoms at all, fever, cough (sometimes productive), nondescript chest discomfort, trivial hemoptysis, and shortness
of breath. Although the fever often responds to glucocorticoids, the
disease progresses. In ventilated patients, screening for Aspergillus
antigen on tracheobronchial lavage fluid is necessary for diagnosis
as radiology is not distinctive. The keys to early diagnosis in at-risk
patients are a high index of suspicion, screening for circulating antigen
(in leukemia), and urgent CT of the thorax. Invasive aspergillosis is one
of the most common diagnostic errors revealed at autopsy.
Invasive Sinusitis The sinuses are involved in 5–10% of cases of
invasive aspergillosis, especially affecting patients with leukemia and
recipients of hematopoietic stem cell transplants. In addition to fever,
the most common features are nasal or facial discomfort, blocked nose,
and nasal discharge (sometimes bloody). Endoscopic examination of
the nose reveals pale, dusky or necrotic-looking tissue in any location.
CT or MRI of the sinuses is essential but does not distinguish invasive
Aspergillus sinusitis from preexisting allergic or bacterial sinusitis early
in the disease process.
Tracheobronchitis Occasionally, only the airways are infected by
Aspergillus. The resulting manifestations seen on bronchoscopy range
from acute or chronic bronchitis to ulcerative or pseudomembranous
tracheobronchitis. These entities are particularly common among lung
transplant recipients and patients on artificial ventilation. Obstruction
with mucous plugs may occur and is called obstructing bronchial
aspergillosis in immunocompromised patients and mucous impaction
in other patients, such as those with ABPA.
Aspergillus Bronchitis Recurrent chest infections that only partially improve with antibiotic treatment and are associated with significant breathlessness or coughing up of thick sputum plugs are typical
features of Aspergillus bronchitis. Patients are not significantly immunocompromised and usually have bronchiectasis or cystic fibrosis.
Occasional patients present with respiratory failure because of airway
obstruction with mucus. Concurrent bacterial bronchitis is common.
The diagnosis rests on recurrent detection of Aspergillus in the airway
by microscopy, culture, or polymerase chain reaction (PCR). Aspergillus
IgG is usually detectable.
Disseminated Aspergillosis In the most severely immunocompromised patients, Aspergillus disseminates from the lungs to multiple
organs—most often to the brain but also to the skin, thyroid, bone,
kidney, liver, gastrointestinal tract, eye (endophthalmitis), and heart
valve. Aside from cutaneous lesions, the most common features are
gradual clinical deterioration over 1–3 days, with low-grade fever and
features of mild sepsis, and nonspecific abnormalities in laboratory
tests. In most cases, at least one localization becomes apparent before
death. Blood cultures are almost always negative.
Cerebral Aspergillosis Hematogenous dissemination to the brain
is a devastating complication of invasive aspergillosis. Single or multiple lesions may develop. In acute disease, hemorrhagic infarction is
most typical, and cerebral abscess is common. Rarer manifestations
include meningitis, mycotic aneurysm, and cerebral granuloma (mimicking a brain tumor). Local spread from cranial sinuses also occurs.
Postoperative infection develops rarely and is exacerbated by glucocorticoids, which are often given after neurosurgery. The presentation can
be either acute or subacute, with mood changes, focal signs, seizures,
and decline in mental status. MRI is the most useful immediate investigation; unenhanced CT of the brain is usually nonspecific, and contrast
is often contraindicated because of poor renal function. Cerebral aspergillosis is disproportionately common in those on ibrutinib.
Endocarditis Most cases of Aspergillus endocarditis are prostheticvalve infections resulting from contamination during surgery. Nativevalve disease is reported, especially as a feature of disseminated infection
and in persons using illicit IV drugs. Culture-negative endocarditis
with large vegetations is the most common presentation; embolectomy
occasionally reveals the diagnosis.
Cutaneous Aspergillosis Dissemination of Aspergillus occasionally results in cutaneous features, usually an erythematous or purplish
nontender area that progresses to a necrotic eschar. Direct invasion
of the skin occurs in neutropenic patients at the site of IV catheter
insertion and in burn patients. Surgical, burn, and trauma wounds may
become infected with Aspergillus (especially A. flavus).
Chronic Pulmonary Aspergillosis The hallmark of chronic cavitary pulmonary aspergillosis (Fig. 217-1) is one or more pulmonary
cavities expanding over a period of months or years in association with
pulmonary symptoms and systemic manifestations such as fatigue and
weight loss. Often mistaken initially for tuberculosis, >90% of chronic
cavitary pulmonary aspergillosis cases occur in patients with prior
pulmonary disease (e.g., tuberculosis, atypical mycobacterial infection,
sarcoidosis, rheumatoid lung disease, pneumothorax, bullae) or lung
surgery. The onset is insidious, and systemic features (weight loss,
fatigue) may be more prominent than pulmonary symptoms. An irregular internal cavity surface and thickened cavity walls are typical and
indicative of disease activity. Irregular material, fluid level, and a wellformed fungal ball are seen in a minority of cavities. Multiple cavities are
more common than a single cavity, and most cavities are in the upper
lobes. Pleural thickening and pericavitary infiltrates are typical and most
obvious if a positron emission tomography scan has been done as part of
the workup. Chronic cavitary pulmonary aspergillosis is usually caused
by A. fumigatus, but A. niger has been implicated, particularly in diabetic
patients, as have other species, rarely. IgG antibodies to Aspergillus are
detectable in ~90% of patients with chronic cavitary pulmonary aspergillosis. Some patients have concurrent infections—even without a fungal
ball—with atypical mycobacteria and/or other bacterial pathogens. The
most significant complication is life-threatening hemoptysis, which may
be the presenting manifestation. If untreated, chronic cavitary pulmonary aspergillosis typically progresses (sometimes relatively rapidly) to
TABLE 217-2 Major Manifestations of Aspergillosis
ORGAN
TYPE OF DISEASE
INVASIVE (ACUTE AND SUBACUTE) CHRONIC SAPROPHYTIC ALLERGIC
Lung Angioinvasive (in neutropenia),
nonangioinvasive, granulomatous
Chronic cavitary, chronic fibrosing,
bronchitis, Aspergillus nodule
Aspergilloma (single),
airway colonization
Allergic bronchopulmonary, severe asthma with
fungal sensitization, extrinsic allergic alveolitis
Sinus Acute invasive Chronic invasive, chronic
granulomatous
Maxillary fungal ball Allergic fungal sinusitis, eosinophilic fungal
rhinosinusitis
Brain Abscess, hemorrhagic infarction,
meningitis
Granulomatous, meningitis None None
Skin Acute disseminated, locally invasive
(trauma, burns, IV access)
External otitis, onychomycosis None None
Heart Endocarditis (native or prosthetic),
pericarditis
None None None
Eye Keratitis, endophthalmitis None None None described
1679CHAPTER 217 Aspergillosis
unilateral or upper-lobe fibrosis. This end-stage entity is termed chronic
fibrosing pulmonary aspergillosis (destroyed lung).
Aspergilloma Aspergilloma (fungal ball) is a late manifestation of chronic cavitary pulmonary aspergillosis, but some patients
are asymptomatic. The inside of a pulmonary cavity allows fungal
growth that peels off, forming the layers of the fungal ball. Signs and
symptoms associated with single (simple) aspergillomas are minor,
including cough (sometimes productive), hemoptysis, wheezing, and
mild fatigue. More significant signs and symptoms are associated with
chronic cavitary pulmonary aspergillosis and should be treated as such.
About 10% of fungal balls resolve spontaneously (by being coughed
up), but the cavity may still be infected and the patient symptomatic.
Aspergillus Nodule A recently recognized form of chronic pulmonary aspergillosis is the Aspergillus nodule, which may resemble early
lung carcinoma and may cavitate. Nodules may be single or multiple
and 5–50 mm in diameter. Larger mass lesions are rarely seen. Nodules
are usually avid on positron emission tomography. IgG antibodies to
Aspergillus are detectable in ~65% of patients with an Aspergillus nodule.
Chronic Aspergillus Sinusitis Three entities are subsumed under
this broad designation: fungal ball of the sinus, chronic invasive
sinusitis, and chronic granulomatous sinusitis. Fungal ball of the
sinus is limited to the maxillary sinus (except in rare cases involving
the sphenoid sinus) in which the sinus cavity is filled with a fungal
ball. Maxillary disease is associated with prior upper-jaw root canal
work and chronic (bacterial) sinusitis. About 90% of CT scans show
focal hyperattenuation related to concretions; on MRI scans, the
T2-weighted signal is decreased, whereas it is increased in bacterial
sinusitis. Removal of the fungal ball is curative. No tissue invasion is
demonstrable histologically or radiologically.
In contrast, chronic invasive sinusitis is a slowly destructive process that most commonly affects the ethmoid and sphenoid sinuses.
Patients are usually but not always immunocompromised to some
degree (e.g., as a result of diabetes or HIV infection). Imaging of the
cranial sinuses shows opacification of one or more sinuses, local bone
destruction, and invasion of local structures. The differential diagnosis
is wide, including other infections. Apart from a history of chronic
nasal discharge and blockage, loss of the sense of smell, and persistent
headache, the usual presenting features are related to local involvement
of critical structures. The orbital apex syndrome (blindness and proptosis) is characteristic. Facial swelling, cavernous sinus thrombosis,
C
C
C
C
C
FIGURE 217-1 CT scan image of the chest in a patient with long-standing bilateral
chronic cavitary pulmonary aspergillosis. This patient had a history of several
bilateral pneumothoraces and had required bilateral pleurodesis in 1990. CT then
demonstrated multiple bullae, and sputum cultures grew A. fumigatus. The patient
had initially weakly and later strongly positive serum IgG Aspergillus antibody tests.
This scan (2003) shows a mixture of thick- and thin-walled cavities in both lungs
(each marked with C), with a probable fungal ball (black arrow) protruding into
the large cavity on the patient’s right side (R). There is also considerable pleural
thickening bilaterally.
carotid artery occlusion, pituitary fossa, and brain and skull-base invasion are complications.
Chronic granulomatous sinusitis due to Aspergillus is most commonly seen in the Middle East and India and is often caused by
A. flavus. It typically presents late, with facial swelling and unilateral
proptosis. The prominent granulomatous reaction histologically distinguishes this disease from chronic invasive sinusitis, in which tissue
necrosis with a low-grade mixed-cell infiltrate is typical. IgG antibodies
to A. flavus are usually detectable.
Allergic Bronchopulmonary Aspergillosis In almost all cases,
ABPA represents a hypersensitivity reaction to A. fumigatus; rare cases
are due to other aspergilli and other fungi. ABPA occurs in ~2.5% of
patients with asthma who are referred to secondary care, although it
may be less common in the United States and more common in those
from the Indian subcontinent. In cystic fibrosis, up to 15% of teenagers
are affected. Episodes of bronchial obstruction with mucous plugs
leading to coughing fits, “pneumonia,” consolidation, and breathlessness are typical. Many patients report coughing up thick sputum casts,
often brown in color. Eosinophilia commonly develops before systemic
glucocorticoids are given. The cardinal diagnostic test is detection of
Aspergillus-specific IgE (or a positive skin-prick test in response to A.
fumigatus extract) together with an elevated serum level of total IgE
(usually >1000 IU/mL). The presence of hyperattenuated mucus in
airways is highly specific. Bronchiectasis is characteristic, and some
patients develop chronic cavitary pulmonary aspergillosis.
Severe Asthma with Fungal Sensitization (SAFS) Many
adults with severe asthma do not fulfill the criteria for ABPA and yet
are allergic to fungi. Although A. fumigatus is a common allergen,
numerous other fungi (e.g., Cladosporium and Alternaria species) are
implicated by skin-prick testing and/or specific IgE testing. Serum total
IgE concentrations are <1000 IU/mL, and bronchial-wall thickening is
common. ABPA and SAFS are collectively referred to as fungal asthma.
Allergic Fungal Rhinosinusitis Like the lungs, the sinuses
manifest allergic responses to Aspergillus and other fungi. The affected
patients present with chronic (i.e., perennial) sinusitis that is relatively
unresponsive to antibiotics. Many of these patients have nasal polyps,
and all have congested nasal mucosae and sinuses full of mucoid
material. The histologic hallmarks of allergic fungal sinusitis are local
eosinophilia and Charcot-Leyden crystals. Removal of abnormal
mucus and polyps, with local and occasionally systemic administration
of glucocorticoids, usually leads to resolution. Persistent or recurrent
signs and symptoms may require more extensive surgery (ethmoidectomy) and sometimes oral antifungal therapy. Recurrence is common,
often after another bacterial or viral infection.
Superficial Aspergillosis Aspergillus can cause keratitis onychomycosis and otitis externa. The former may be difficult to diagnose
early enough to save the patient’s sight. Natamycin (5%) eye drops are the
optimal therapy for fungal keratitis, often with surgery. Otitis externa usually resolves with debridement and local application of antifungal agents.
■ DIAGNOSIS
Several techniques are required to establish the diagnosis of any form
of aspergillosis with confidence (Table 217-1).
Acute Invasive Aspergillosis Patients with acute invasive aspergillosis have a relatively heavy load of fungus in the affected organ;
thus, antigen detection, PCR, microscopy, culture, and/or histopathology usually confirm the diagnosis. However, the pace of progression
leaves only a narrow window for making the diagnosis without losing
the patient, and some invasive procedures are not possible because of
coagulopathy, respiratory compromise, and other factors. Many cases
of invasive aspergillosis are missed clinically and are diagnosed only at
autopsy. Histologic examination of affected tissue reveals either infarction, with invasion of blood vessels by many fungal hyphae, or acute
necrosis, with limited inflammation and fewer hyphae. Aspergillus
hyphae are hyaline, narrow, and septate, with branching at 45°; no yeast
forms are present in infected tissue. Hyphae can be seen in cytology
1680 PART 5 Infectious Diseases
or microscopy preparations, which therefore provide a rapid means of
presumptive diagnosis.
One Aspergillus antigen test relies on detection of galactomannan
release from Aspergillus organisms during growth, the other a novel
protein antigen. Respiratory sample antigen detection is more sensitive
than serum and is critical in the intensive care unit patient in whom
radiology is nonspecific. Positive serum antigen results usually precede
clinical or radiologic features by several days. The sensitivity of antigen
detection is reduced by antifungal therapy.
A positive culture supports the diagnosis, given that multiple other
(rarer) fungi can mimic Aspergillus species histologically, but only
10–30% of patients with invasive aspergillosis have a positive culture.
Bacterial agar is less sensitive than fungal media for culture; thus, if
physicians do not request fungal culture, the diagnosis may be missed.
High-volume fungal cultures enhance yield. A positive culture may
represent noninvasive forms of aspergillosis or airway colonization.
Both antigen detection and real-time PCR are faster and much more
sensitive than culture of respiratory samples and blood.
Definitive confirmation of a diagnosis of invasive aspergillosis
requires (1) a positive culture of a sample taken directly from an ordinarily sterile site (e.g., a brain abscess) or (2) positive results of both
histologic testing and culture (or molecular confirmation of Aspergillus
spp.) of a sample taken from an affected organ (e.g., sinuses or skin).
Most diagnoses of invasive aspergillosis are inferred from fewer data,
including the presence of the halo sign on a thoracic CT scan—a localized ground-glass appearance representing hemorrhagic infarction
surrounds a nodule or consolidation. Halo signs are present for ~7 days
early in the course of infection in neutropenic patients and are a good
prognostic feature, reflecting an early diagnosis. Nodules with halo
signs are a feature of COVID-19 and do not imply invasive aspergillosis
with supportive evidence. Other characteristic radiologic features of
invasive pulmonary aspergillosis include nodules and pleural-based
infarction or cavitation, but nonspecific consolidation is common
(Fig. 217-2).
Chronic Aspergillosis For chronic aspergillosis, Aspergillus antibody testing combined with characteristic imaging is sufficient for the
diagnosis. Biopsy of Aspergillus nodules reveals hyphae surrounded by
cells of chronic inflammation and sometimes granulomas. Antibody
titers fall slowly with successful therapy. Cultures are infrequently
positive but are important in checking for azole resistance. Real-time
PCR of sputum is often strongly positive. Some patients with chronic
pulmonary aspergillosis also have elevated titers of total serum IgE and
Aspergillus-specific IgE.
ABPA, SAFS, and Allergic Aspergillus Sinusitis ABPA and
SAFS are diagnosed serologically with elevated specific and total serum
IgE levels or with skin-prick tests. Allergic Aspergillus sinusitis is usually diagnosed histologically, accompanied by Aspergillus IgE antibody.
TREATMENT
Aspergillosis
Antifungal drugs active against Aspergillus include voriconazole,
itraconazole, posaconazole, isavuconazole, caspofungin, micafungin, and amphotericin B (AmB). Possible interactions with other
drugs must be considered before azoles are prescribed. In addition,
plasma azole concentrations vary substantially from one patient
to another, and many authorities recommend monitoring levels
to ensure that drug concentrations are adequate but not excessive,
especially with itraconazole and voriconazole. Initial IV administration is preferred for acute invasive aspergillosis and oral administration for all other diseases that require antifungal therapy. Current
recommendations are shown in Table 217-3.
Voriconazole, isavuconazole and posaconazole are the preferred
agents for invasive aspergillosis; caspofungin, micafungin, and lipidassociated AmB are second-line agents. AmB is not active against A.
terreus or A. nidulans; multi-azole resistance in A. fumigatus is present
in <5% of isolates but is increasing, especially in Southeast Asia; and
A. niger is resistant to itraconazole and isavuconazole. An infectious
disease consultation is advised for patients with invasive disease,
given the complexity of management. Immune reconstitution can
complicate recovery. The duration of therapy for invasive aspergillosis varies from ~3 months to several years, depending on the
patient’s immune status and response to therapy. Relapse occurs if the
response is suboptimal and immune reconstitution is not complete.
Voriconazole is currently the preferred oral agent for chronic
aspergillosis with itraconazole or posaconazole as substitutes when
failure, emergence of resistance, or adverse events occur. Because
chronic cavitary pulmonary aspergillosis responds slowly, therapy
for >6 months is necessary, and disease control may require years
of treatment, whereas the duration of treatment for other forms of
chronic and allergic aspergillosis requires case-by-case evaluation.
Glucocorticoids should be used in chronic cavitary pulmonary
aspergillosis only if covered by adequate antifungal therapy. Acute
exacerbations of ABPA respond well to voriconazole, itraconazole,
or a short course of glucocorticoids—long-term azole therapy usually helps minimize corticosteroid exposure and maintain remission. Antifungal response in Aspergillus bronchitis is gratifying, but
relapse after 4 months of therapy is common.
Resistance in A. fumigatus to one or more azoles, although
uncommon, is increasingly found globally. Resistance may be
derived from azole fungicide use for crops. In addition, resistance
arising from multiple mechanisms may develop during long-term
treatment, and a positive culture during antifungal therapy is an
indication for susceptibility testing.
A
B
FIGURE 217-2 Markedly different appearances of invasive aspergillosis on CT scan
of the thorax. A. Patient with myelodysplasia and moderate neutropenia showing
small right-sided nodules with minimal surrounding ground glass and a separate
area of ground glass only on the left laterally. B. Patient with multiple myeloma
undergoing intensive chemotherapy with corticosteroids showing bilateral areas
of consolidation and some nonspecific atelectasis with probable ground glass
surrounding the right-sided lesion. The anterior component of the left-sided lesion
is demarcated by the fissure.
1681CHAPTER 218 Mucormycosis
TABLE 217-3 Treatment of Aspergillosisa
INDICATION PRIMARY TREATMENT PRECAUTIONS SECONDARY TREATMENT COMMENTS
Invasive diseaseb Voriconazole,
isavuconazole,
posaconazole
Drug interactions
(especially with rifampin and
carbamazepine)c
AmB, caspofungin,
posaconazole, micafungin
As primary therapy, voriconazole, isavuconazole, and
posaconazole have a 20% higher response rate than
AmB. Therapeutic drug monitoring is recommended
for voriconazole.
Prophylaxis Posaconazole tablet,
itraconazole solution
SUBA-itraconazole
Vincristine, cyclophosphamide
interaction
Micafungin, aerosolized
AmB
Some centers monitor plasma levels of itraconazole
and posaconazole.
Single aspergilloma Surgical resection Multicavity disease: poor
outcome of surgery, medical
therapy preferable
Itraconazole, voriconazole,
intracavity AmB
Single large cavities with an aspergilloma are best
resected. Relapse reduced by pre- and peri-operative
antifungal therapy.
Chronic pulmonary
diseaseb
Voriconazole,
itraconazole
Poor absorption of itraconazole
capsules with proton pump
inhibitors or H2
blockers
Posaconazole, IV AmB,
IV micafungin
Resistance may emerge during treatment, especially
if plasma drug levels are subtherapeutic. Resistance
is less common with voriconazole.
ABPA/SAFS (“fungal
asthma”)
Itraconazole Some glucocorticoid
interactions, including with
inhaled formulations
Voriconazole,
posaconazole
Long-term therapy is helpful in most cases. No
evidence indicates whether therapy modifies
progression to bronchiectasis/fibrosis.
a
For information on duration of therapy and drug resistance in certain Aspergillus species, see text. b
An infectious disease consultation is appropriate for these patients. c
Online drug-interaction resource: www.aspergillus.org.uk/content/antifungal-drug-interactions.
Note: After loading doses, the oral dose is usually 200 mg bid for voriconazole and itraconazole, 100 mg bid for SUBA-itraconazole, 300 mg qd for posaconazole tablets, and
200 mg qd for isavuconazole. The IV dose of voriconazole for adults is 6 mg/kg twice at 12-h intervals (loading doses) followed by 4 mg/kg q12h; a larger dose is required
for children and teenagers; a lower dose may be safer for persons >70 years of age. Plasma monitoring is helpful in optimizing the dosage. The IV dose of isavuconazole
is 200 mg tid for 2 days (loading dose) followed by 200 mg qd. Caspofungin is given as a single loading dose of 70 mg and then at 50 mg/d; some authorities use 70 mg/d for
patients weighing >80 kg, and lower doses are required with hepatic dysfunction. Micafungin is given as 50 mg/d for prophylaxis and as at least 150 mg/d for treatment; this
drug has not yet been approved by the U.S. Food and Drug Administration (FDA) for this indication. AmB deoxycholate is given at a daily dose of 1 mg/kg if tolerated. Several
strategies are available for minimizing renal dysfunction. Lipid-associated AmB is given at 3 mg/kg (AmBisome) or 5 mg/kg (Abelcet). Different regimens are available for
aerosolized AmB, but none is FDA approved. Other considerations that may alter dose selection or route include age; concomitant medications; renal, hepatic, or intestinal
dysfunction; and drug tolerability.
Abbreviations: ABPA, allergic bronchopulmonary aspergillosis; AmB, amphotericin B; SAFS, severe asthma with fungal sensitization.
Mucormycosis represents a group of life-threatening infections caused
by fungi of the order Mucorales of the subphylum Mucoromycotina.
Mucormycosis is highly invasive and relentlessly progressive, resulting
in higher rates of morbidity and mortality than many other infections.
The mortality rates from mucormycosis have declined in recent years
as a result of early initiation of more effective antifungal therapies.
However, mortality remains high overall, often driven by progression
of the underlying predisposing condition.
218 Mucormycosis
Brad Spellberg, Ashraf S. Ibrahim
Surgical treatment is important in several forms of aspergillosis,
including fungal ball of the sinus and single aspergillomas, in which
surgery is curative; invasive aspergillosis involving bone, heart
valve, sinuses, and proximal areas of the lung (to avoid catastrophic
hemoptysis); brain abscess; keratitis; and endophthalmitis. In allergic
fungal sinusitis, removal of abnormal mucus and polyps, with local
and occasionally systemic glucocorticoid treatment, usually leads to
resolution. Persistent or recurrent signs and symptoms may require
more extensive surgery (ethmoidectomy) and possibly antifungal
therapy. Surgery is problematic in chronic cavitary pulmonary
aspergillosis, usually resulting in serious complications. Bronchial
artery embolization is preferred for problematic hemoptysis.
■ PROPHYLAXIS
In situations in which moderate or high risk is predicted (e.g., after
induction therapy for acute myeloid leukemia), the need for antifungal prophylaxis for superficial and systemic candidiasis and for
invasive aspergillosis is generally accepted. Fluconazole is commonly
used in these situations but has no activity against Aspergillus species.
Itraconazole solution of SUBA-itraconazole capsules provide enough
bioavailability for modest efficacy, the latter with fewer adverse events.
Posaconazole tablets are more effective in reducing infection rates and
the need for empirical antifungal therapy. Some data support the use of
IV micafungin in those with azole contraindications. No prophylactic
regimen is completely successful.
■ OUTCOME
Invasive aspergillosis is curable if immune reconstitution occurs,
whereas allergic and chronic forms are not. The mortality rate for
invasive aspergillosis is 30–70% if the infection is treated but is 100% if
the diagnosis is missed. Cerebral aspergillosis, Aspergillus endocarditis,
and bilateral extensive invasive pulmonary aspergillosis have very poor
outcomes, as does invasive infection in persons with late-stage AIDS or
relapsed uncontrolled leukemia.
The mortality rate for chronic cavitary pulmonary aspergillosis is
~40% over 5 years and 50–60% over 10 years if the patient is actively
treated with antifungal agents. After 12 months with no antifungal
therapy, 70% of patients have deteriorated, and 10–35% have died.
Therapy fails in ~30% of recipients of antifungal therapy and still more
often if azole resistance is present.
Both ABPA and SAFS patients respond to antifungal therapy; ~60%
respond to itraconazole and ~80% to voriconazole and posaconazole
(if tolerated). Inhaled amphotericin B is effective in and tolerated by
~15% of patients. If the severity of asthma declines, the inhaled glucocorticoid dose can be reduced, and oral glucocorticoids can be stopped.
Relapse after discontinuation is common but not universal.
■ FURTHER READING
Goh KJ et al: Sensitization to Aspergillus species is associated with frequent exacerbations in severe asthma. J Asthma Allergy 10:131-40, 2017.
Lamoth F et al: Incidence of invasive pulmonary aspergillosis among
critically ill COVID-19 patients. Clin Microbiol Infect 26:1706, 2020.
Muldoon EG et al: Aspergillus nodules; another presentation of
chronic pulmonary aspergillosis. BMC Pulm Med 16:123, 2016.
Schauwvlieghe AFAD et al: Invasive aspergillosis in patients admitted to the intensive care unit with severe influenza: A retrospective
cohort study. Lancet Respir Med 6:782, 2018.
Ullman AJ et al: Diagnosis and management of Aspergillus diseases:
Executive summary of the 2017 ESCMID-ECMM-ERS guideline.
Clin Microbiol Infect 24:e1ee38, 2018.
1682 PART 5 Infectious Diseases
■ EPIDEMIOLOGY
Mucormycosis typically occurs in patients with diabetes mellitus,
solid-organ transplantation or hematopoietic stem cell transplantation
(HSCT), prolonged neutropenia or corticosteroid use, or malignancy.
As mentioned, the majority of diabetic patients are not acidotic on
presentation with mucormycosis. Furthermore, patients often have no
previously recognized history of diabetes mellitus when they present
with mucormycosis. In these instances, presentation for mucormycosis
may result in the first clinical recognition of hyperglycemia, which
often has been unmasked by recent glucocorticoid use. Thus, a high
index of suspicion of mucormycosis must be maintained, even in the
absence of a known history of diabetes, if hyperglycemia is present. In
patients undergoing HSCT, mucormycosis develops at least as commonly during nonneutropenic as during neutropenic periods, probably because of glucocorticoid treatment of graft-versus-host disease.
Mucormycosis can occur as isolated cutaneous or subcutaneous infection in immunologically normal individuals after traumatic implantation of soil or vegetation (e.g., due to natural disasters, motor vehicle
accidents, or severe injuries in war zones) or in nosocomial settings via
direct access through intravenous catheters, subcutaneous injections,
or maceration of the skin by a moist dressing.
Patients receiving antifungal prophylaxis with either itraconazole or
voriconazole may be at increased risk of mucormycosis. These patients
typically present with disseminated mucormycosis, the most lethal
form of disease. Breakthrough mucormycosis also has been described
in patients receiving posaconazole, isavuconazole, or echinocandin
prophylaxis.
Mucormycosis has also emerged as an important superinfection in
COVID-19 patients, with patients in India being particularly heavily affected. Even before COVID-19, India was hyper-endemic for
mucormycosis, with population-based case rates that were up to 70
times higher than the worldwide rate. Whether or not COVID-19 itself
somehow predisposes to mucormycosis is not clear. Both in India and
the rest of the world, the vast majority of excess cases of mucormycosis during the COVID-19 pandemic have likely been attributable to a
combination of diabetes mellitus and corticosteroid use. In India, onethird of mucormycosis cases during the COVID-19 pandemic were in
patients not infected with COVID-19, underscoring the high baseline
rate there. Furthermore, the large majority of mucormycosis cases in
COVID-19 patients in India and the rest of the world have been of
the rhino-orbital-cerebral variety, and pulmonary infection has been
rare, consistent with diabetes and corticosteroids predisposing to these
cases.
■ CLINICAL MANIFESTATIONS
Mucormycosis presents as one of five well-defined clinical syndromes:
rhino-orbital-cerebral, pulmonary, cutaneous, gastrointestinal, and
disseminated disease. However, infection of any body site can occur.
Patients with specific defects in host defense tend to develop specific
syndromes. For example, patients with diabetes mellitus and/or DKA
typically develop the rhino-orbital-cerebral form and much more
rarely develop pulmonary or disseminated disease. In contrast, pulmonary mucormycosis occurs most commonly in leukemic patients who
are receiving chemotherapy and in patients undergoing HSCT.
Rhino-Orbital-Cerebral Disease Rhino-orbital-cerebral mucormycosis continues to be the most common form of the disease worldwide. Most cases occur in patients with diabetes, although such cases
are also described in the transplantation setting, often along with
glucocorticoid-induced diabetes mellitus. The initial symptoms of
rhino-orbital-cerebral mucormycosis are nonspecific and include eye or
facial pain and facial numbness followed by the onset of conjunctival suffusion and swelling, and blurry vision. In contrast to the acute, bright red,
periocular skin manifestations typical of acute bacterial orbital cellulitis,
periorbital skin in patients with rhino-orbital-cerebral mucormycosis
may take on a more dusky, subacute appearance. Fever may be absent in
up to half of cases. White blood cell counts are typically elevated as long
as the patient has functioning bone marrow. If untreated, infection usually
spreads from the ethmoid sinus to the orbit, resulting in compromise of
TABLE 218-1 Taxonomy of Fungi Causing Mucormycosis
(Subphylum Mucoromycotina, Order Mucorales)
FAMILY GENUS (SPECIES LISTED FOR SOME)
Mucoraceae Rhizopus oryzae
Rhizopus delemar
Rhizopus microsporus
Rhizomucor
Mucor
Actinomucor
Lichtheimiaceae Lichtheimia (formerly Mycocladus, formerly Absidia)
Cunninghamellaceae Cunninghamella
Thamnidiaceae Cokeromyces
Mortierellaceae Mortierella
Saksenaceae Saksenaea
Apophysomyces
Syncephalastraceae Syncephalastrum
■ ETIOLOGY
The fungal order Mucorales consists of seven families that are known
to cause mucormycosis (Table 218-1). Rhizopus oryzae and R. delemar
(both in the family Mucoraceae) are by far the most common causes
of mucormycosis in the Western Hemisphere. Less frequently isolated
species of the Mucoraceae that cause a similar spectrum of infections
include Rhizopus microsporus, Rhizomucor pusillus, Lichtheimia corymbifera (formerly Absidia corymbifera), Apophysomyces elegans, and
Mucor species. Increasing numbers of cases of mucormycosis due to
infection by mold in the family Cunninghamellaceae have also been
reported, particularly in highly immunocompromised patients. Other
Mucorales can be the major cause of disease in certain geographic areas
(e.g., A. elegans in India and Mucor irregularis in China) or in outbreaks following natural disasters (e.g., Apophysomyces trapeziformis
outbreak following the 2011 tornado in Joplin, Missouri). Only rare
case reports have demonstrated the ability of fungi in the remaining
families of the Mucorales to cause mucormycosis.
■ PATHOGENESIS
The Mucorales are ubiquitous environmental fungi to which humans
are constantly exposed. These fungi cause infection primarily in
patients with uncontrolled diabetes, defects in phagocytic function
(e.g., neutropenia or glucocorticoid treatment), and/or elevated levels
of free iron, which supports fungal growth in serum and tissues. In the
past, iron-overloaded patients with end-stage renal failure who were
treated with deferoxamine had a high risk of developing rapidly fatal
disseminated mucormycosis; deferoxamine is an iron chelator for the
human host, but it serves as a fungal siderophore, directly delivering
iron to the Mucorales. Furthermore, patients with diabetic ketoacidosis (DKA) are at high risk of developing rhinocerebral mucormycosis.
The acidosis causes dissociation of iron from sequestering proteins,
resulting in enhanced fungal survival and virulence. The ketoacid
β-hydroxybutyrate also increases expression of host and fungal receptors that result in fungal adherence and penetration into tissues.
Nevertheless, the majority of diabetic patients who present with
mucormycosis are not acidotic, and, even absent acidosis, hyperglycemia directly contributes to the risk of mucormycosis by at least four
likely mechanisms: (1) hyperglycation of iron-sequestering proteins,
disrupting normal iron sequestration; (2) upregulation of a mammalian
cell receptor (GRP78) that binds to Mucorales, enabling tissue penetration (due to both a direct effect of hyperglycemia and increasing levels
of free iron); (3) induction of poorly characterized defects in phagocytic
function; and (4) enhanced expression of CotH, a Mucorales-specific
protein that mediates host cell invasion by binding to GRP78 (due
to hyperglycemia and the resulting free iron). More recently, the
mucoricin toxin—with structural and functional similarities to ricin—
was found to be responsible for host cell death and tissue necrosis. The
toxin is a key virulence factor of Mucorales fungi and is a promising
therapeutic target.
1683CHAPTER 218 Mucormycosis
A B
FIGURE 218-1 Histopathology sections of Rhizopus delemar in infected brain. A. Broad, ribbon-like,
nonseptate hyphae in the parenchyma (arrows) and a thrombosed blood vessel with extensive intravascular
hyphae (arrowhead) (hematoxylin and eosin). B. Extensive, broad, ribbon-like hyphae invading the
parenchyma (Gomori methenamine silver).
extraocular muscle function and proptosis, typically with chemosis. From
the orbit, the fungus can spread contiguously or hematogenously to the
frontal lobe of the brain and/or via venous drainage to the cavernous
sinus. Onset of signs and symptoms in the contralateral eye, with resulting
bilateral proptosis, chemosis, vision loss, and ophthalmoplegia, is ominous, suggesting the development of cavernous sinus thrombosis.
Upon visual inspection, infected tissue often has a normal appearance
during the earliest stages of fungal spread, which can make diagnosis
difficult; blind biopsies of normal-appearing sinus tissue are warranted
when suspicion for mucormycosis is high. Tissue then progresses
through an erythematous phase, with or without edema, before the
onset of a violaceous appearance and finally the development of a black
necrotic eschar. Infection can sometimes extend from the sinuses into the
mouth and produce painful necrotic ulcerations of the hard palate, but
this is a late finding that suggests extensive, well-established infection.
One common misperception about mucormycosis is that it is always
rapidly progressive. In fact, the rate of progression is extremely variable
and is possibly dependent on the immune status of the patient, the
infectious inoculum, and the causative Mucorales species, some of
which are more virulent and/or have faster growth rates than others.
Patients may go from initial symptoms to death in days; alternatively, it
can take months or even a year or more for lethal progression to occur.
Pulmonary Disease Pulmonary mucormycosis is the second most
common manifestation. Symptoms include dyspnea, cough, and chest
pain; fever is often but not invariably present. Angioinvasion results in
necrosis, cavitation, and/or hemoptysis. Lobar consolidation, isolated
masses, nodular disease, cavities, or wedge-shaped infarcts may be seen
on chest radiography. High-resolution chest CT is the best method for
determining the extent of pulmonary mucormycosis and may demonstrate evidence of infection before it is seen on chest x-ray. In the
setting of cancer, where mucormycosis may be difficult to differentiate
from aspergillosis, the presence of ≥10 pulmonary nodules, pleural
effusion, or concomitant sinusitis makes mucormycosis more likely. It
is important to distinguish mucormycosis from aspergillosis because
treatments for these infections may differ. Indeed, voriconazole—the
first-line treatment for aspergillosis—exacerbates mucormycosis in
mouse and fly models of infection. Isavuconazole and posaconazole
were noninferior to voriconazole for the treatment of aspergillosis in
randomized controlled trials, and also have activity against Mucorales.
Hence if there is doubt about whether infection is caused by a septated
mold (e.g., Aspergillus) or a Mucorales, inclusion of isavuconazole or
posaconazole in a treatment regimen is a reasonable consideration.
Consideration must also be given to the possibility of dual infection
with both a septated mold and Mucorales; dual infection is not infrequently encountered in highly compromised patients.
Cutaneous Disease Cutaneous mucormycosis may result from
external implantation of the fungus or from hematogenous dissemination. External implantation–related infection has been described in the
setting of soil exposure from trauma (e.g., in a motor vehicle accident,
a natural disaster, or combat-related injuries), penetrating injury with plant material (e.g., a thorn),
injections of medications (e.g., insulin), catheter
insertion, contamination of surgical dressings, and
use of tape to secure endotracheal tubes. Cutaneous disease can be highly invasive, penetrating into
muscle, fascia, and even bone. Necrotizing fasciitis
caused by mucormycosis carries a mortality rate
approaching 80%. Necrotic cutaneous lesions in
the setting of hematogenous dissemination also are
associated with an extremely high mortality rate.
However, with prompt, aggressive surgical debridement, isolated cutaneous mucormycosis has a
favorable prognosis and a low mortality rate.
Gastrointestinal Disease In the past, gastrointestinal mucormycosis occurred primarily in premature neonates in association with disseminated
disease and necrotizing enterocolitis. However,
there has been a marked increase in case reports describing adults
with neutropenia, glucocorticoid use, or other immunocompromising
conditions. In addition, gastrointestinal disease has been reported as
a nosocomial process following administration of medications mixed
with contaminated wooden applicator sticks. Nonspecific abdominal
pain and distention associated with nausea and vomiting are the most
common symptoms. Gastrointestinal bleeding is common, and fungating masses may be seen in the stomach at endoscopy. The disease may
progress to visceral perforation, with extremely high mortality rates.
Disseminated and Miscellaneous Forms of Disease Hematogenously disseminated mucormycosis may originate from any primary site of infection. The most common site of dissemination is the
brain, but metastatic lesions may also be found in any other organ.
Mortality rates for widely disseminated mucormycosis exceed 90%;
however, these high rates are likely to be due in part to the underlying
predisposing condition leading to the infection and the inability to
surgically remove the infected foci.
Mucormycosis may affect any body site, including bones, mediastinum, trachea, kidneys, peritoneum (in association with dialysis), scalp
(causing a kerion), and even isolated infection of teeth.
■ DIAGNOSIS
A high index of suspicion is required for diagnosis of mucormycosis.
Unfortunately, autopsy series have shown that up to half of cases are
diagnosed only postmortem. Because the Mucorales are environmental
isolates, definitive diagnosis requires a positive culture from a sterile
site (e.g., a needle aspirate, a tissue biopsy specimen, or pleural fluid) or
histopathologic evidence of invasive mucormycosis. A probable diagnosis of mucormycosis can be established by culture from a nonsterile
site (e.g., sputum or bronchoalveolar lavage) or the detection of Mucorales on the surface of histopathology samples (without visualization
of evidence of invasion) when a patient has appropriate risk factors
as well as clinical and radiographic evidence of disease. In such cases,
given the urgency of administering therapy early, the patient should be
treated while confirmation of the diagnosis is awaited.
Biopsy with histopathologic examination remains the most sensitive
and specific modality for definitive diagnosis (Fig. 218-1). Biopsy
reveals characteristic wide (≥6- to 30-μm), thick-walled, ribbon-like,
aseptate hyphal elements that branch at right angles. Other fungi,
including Aspergillus, Fusarium, and Scedosporium species, have septa,
are thinner, and branch at acute angles. However, artificial septa may
result from folding of tissue during processing (which may also alter
the appearance of the angle of branching), which can make Mucorales
appear to have septa. Thus, the width and the ribbon-like form of the
fungus are the most reliable features distinguishing mucormycosis
from other pathogenic molds. The Mucorales are visualized most
effectively with periodic acid–Schiff or hematoxylin and eosin; in
contrast to many other fungi, methenamine silver may not result in
optimal staining. While histopathology can identify the Mucorales,
1684 PART 5 Infectious Diseases
species can be identified only by culture. Several studies showed that
polymerase chain reaction (PCR) of Mucorales-specific targets is useful in diagnosing mucormycosis. However, the U.S. Food and Drug
Administration (FDA) has not approved any of these PCR-based assays
for this purpose.
Unfortunately, cultures are positive in fewer than half of cases of
mucormycosis. Nevertheless, the Mucorales are not fastidious organisms and tend to grow quickly (i.e., within 48–96 h) on culture media.
The likely explanation for the low sensitivity of culture is that the
Mucorales form long filamentous structures that are killed by tissue
homogenization—the standard method for preparing tissue cultures
in the clinical microbiology laboratory. Thus, the laboratory should be
advised when a diagnosis of mucormycosis is suspected, and the tissue
should be cut into sections and placed in the center of culture dishes
rather than homogenized. Because there is also substantial variability
among isolates in optimal growth temperature, growth at both room
temperature and 37°C is advisable.
Imaging techniques often yield subtle findings that underestimate
the extent of disease. For example, the most common finding on CT or
MRI of the head or sinuses of a patient with rhino-orbital mucormycosis is sinusitis that is indistinguishable from bacterial sinusitis.
While sinusitis is almost always seen on CT scans in patients with the
rhino-orbital-cerebral disease, erosion through the sinus bones and
into the orbit is rarely seen on CT even when it is clinically present.
MRI is more sensitive (~80%) for detecting orbital and central nervous
system (CNS) disease than is CT. High-risk patients should always
undergo endoscopy and/or surgical exploration, with biopsy of the
areas of suspected infection. If mucormycosis is suspected, initial
empirical therapy with a polyene antifungal agent should be initiated
while the diagnosis is being confirmed.
■ DIFFERENTIAL DIAGNOSIS
Other mold infections, including aspergillosis, scedosporiosis, fusariosis, and infections caused by the dematiaceous fungi (brownpigmented soil organisms), can cause clinical syndromes identical
to mucormycosis. Histopathologic examination usually allows distinction of the Mucorales from these other organisms, and a positive
culture permits definitive species identification. As stated above, it
is important to distinguish the Mucorales from these other fungi, as
the preferred antifungal treatments differ (i.e., polyenes for the Mucorales vs expanded-spectrum triazoles for most septate molds). The
entomophthoromycoses caused by Basidiobolus and Conidiobolus also
can cause identical clinical syndromes. These fungi cannot be readily
distinguished from the Mucorales by histopathology but can be reliably distinguished by culture. Fortunately, entomophthoromycoses are
uncommon in developed countries and can be treated with polyenes; it
is not urgent to distinguish them from mucormycosis.
In a patient with sinusitis and proptosis, orbital cellulitis and cavernous sinus thrombosis caused by bacterial pathogens (most commonly
Staphylococcus aureus, but also streptococcal and gram-negative species) must be excluded. Klebsiella rhinoscleromatis is a rare cause of
an indolent facial rhinoscleroma syndrome that may appear similar
to mucormycosis. Finally, the Tolosa-Hunt syndrome causes painful
ophthalmoplegia, ptosis, headache, and cavernous sinus inflammation; biopsies and clinical follow-up may be needed to distinguish the
Tolosa-Hunt syndrome from mucormycosis by the lack of progression
of the former entity.
TREATMENT
Mucormycosis
GENERAL PRINCIPLES
Optimizing the chances for successful treatment of mucormycosis
requires four steps: (1) early initiation of therapy; (2) surgical debridement, when possible; (3) rapid reversal of underlying predisposing risk factors, if possible; and (4) proceeding to treat underlying
malignancy, if present, without waiting to complete antifungal
therapy first.
Early initiation of antifungal therapy requires maintaining a high
index of suspicion for at-risk patients. Multiple studies have found
that earlier initiation of polyene-based therapy improves survival
of patients with mucormycosis. Because the disease can present
subtly at first and confirmation of the diagnosis can take days,
therapy often must be started empirically before the diagnosis is
established. When there is a reasonable suspicion of mucormycosis,
clinicians should not hesitate to initiate therapy with a lipid polyene
as soon as possible since the toxicity of lipid polyenes (unlike that
of amphotericin B [AmB] deoxycholate) is rarely substantial after
one or two doses.
Blood vessel thrombosis and resulting tissue necrosis during
mucormycosis can result in poor penetration of antifungal agents
to the site of infection. Therefore, debridement of all necrotic
tissues can help eradicate the disease. Surgery has been found (by
logistic regression and in multiple case series) to be an independent
variable for favorable outcome in patients with mucormycosis.
However, these data are confounded by the fact that sicker patients
are often unable to tolerate surgical procedures. Thus, a moderated
approach where tissue is debrided when and to the extent it is
safe to do so is advisable. Limited data from a retrospective study
support the use of intraoperative frozen sections to delineate the
margins of infected tissues, with sparing of tissues lacking evidence
of infection.
Rapidly reversing hyperglycemia, acidosis, or iron overload and
lowering corticosteroid doses are important to improving cure.
Indeed, a recent study confirmed that resolution of acidosis in mice
with DKA via the administration of sodium bicarbonate (used in
the mice in lieu of insulin) improved survival. Administration of
glucocorticoids predisposes animals to death from mucormycosis
in experimental models. Similarly, iron administration to patients
with active mucormycosis should be avoided as iron exacerbates
infection in experimental models. Blood transfusion typically
results in some liberation of free iron due to hemolysis, so a conservative approach to red blood cell transfusions is advisable.
One of the most common errors made in management of
mucormycosis is the belief that mucormycosis must be eradicated
before an underlying malignancy can be treated. This belief can
result in halting or delaying treatment for the underlying disease
(e.g., chemotherapy or transplantation) until the mucormycosis
is cured. Three fallacies belie this concern. First, mucormycosis
will not be definitively eradicated until near-normal immunity is
restored; the antifungals provide a holding action and are unlikely
to be curative until the underlying disease is treated. Second, modern antifungals can halt progression of mucormycosis temporarily,
enabling aggressive chemotherapy or transplantation to be administered to cure the underlying disease. Finally, the primary driver
of death in such patients is typically progression of the underlying
disease due to failure to treat it appropriately.
Initially, some consideration can be given to moderating the level
of aggressiveness of the chemotherapy and resulting duration and
depth of neutropenia. The aggressiveness of immune suppression
and antifungal therapy can then be adjusted during the course of
treatment in response to changes in clinical status. Chemotherapy
should be given sufficiently aggressively to attempt cure of the
underlying disease. These patients are extremely complex, and
multidisciplinary, team-based care is advisable.
ANTIFUNGAL THERAPY
Primary therapy for mucormycosis should be based on a polyene
antifungal agent (Table 218-2), except perhaps in mild localized
infection (e.g., isolated suprafascial cutaneous infection) that has
been eradicated surgically in an immunocompetent patient. Lipid
formulations of AmB are significantly less nephrotoxic than AmB
deoxycholate, can be administered at higher doses, and are probably
more effective for this purpose. Liposomal amphotericin B (LAmB)
is preferred to amphotericin B lipid complex (ABLC) for management of brain infection on the basis of retrospective survival data
and superior brain penetration; there is no clear efficacy advantage
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