1651CHAPTER 210 Ebolavirus and Marburgvirus Infections
laboratory diagnosis is performed with patient samples inactivated in
mobile field “glove boxes” by on-site personnel trained in the safe use of
diagnostic assays adapted for field use in lower-containment settings.
Consequently, diagnostic samples should be collected and processed
with great caution and with the use of appropriate PPE and strict
barrier techniques. With adherence to established biosafety precautionary measures, samples should be sent in suitable transport media
to national or international WHO reference laboratories. Acute-phase
blood/serum is the preferred diagnostic specimen, because it usually
contains high titers of filovirions and filovirion-specific antibodies.
The current assay of choice for the diagnosis of filovirus infection
is reverse-transcription polymerase chain reaction (RT-PCR) targeting
one or more filovirus genes; a typical detection limit is 1000–5000
PFU/mL of serum, depending on the assay. Safe, rapid-turnaround,
and standardized in-field PCR-based approaches (e.g., the Cepheid
GeneXpert platform) are increasingly deployed during outbreaks.
Antigen-capture enzyme-linked immunosorbent assays (ELISAs) for
the detection of filovirus genomes and filovirion proteins are in development and may be useful as rapid point-of-care diagnostic tests in
the future. Direct IgM capture, direct IgG capture, or IgM-capture
ELISA is used for the detection of filovirion-targeting antibodies from
patients in the later stages of disease (i.e., those who have been able
to mount a detectable antibody response), including survivors. All of
these assays can be conducted on samples treated with guanidinium
isothiocyanate (for RT-PCR), cobalt-60 irradiation (for ELISA), or
other effective measures that render filoviruses noninfectious. Virus
isolation in cell culture and plaque assays for quantification or diagnostic confirmation are relatively easy but must be performed in maximalcontainment laboratories. If available, electron microscopic examination of inactivated samples or cultures can further support the diagnosis because filovirions have unique filamentous shapes (Fig. 210-2).
Formalin-fixed skin biopsy samples and possibly skin swabs can be
useful for safe postmortem diagnoses. In-field (or near in-field) rapid
genome sequencing was first deployed to inform classic epidemiology
in Western Africa during the 2013–2016 EVD outbreak and is likely
to become a mainstay of outbreak control and response, even in challenging settings.
TREATMENT
Filovirus Infections
Treatment of patients with suspected or confirmed filovirus infection should be administered by health care workers who are using
appropriate PPE and who have been well trained in the complex
care of the FVD patient under restrictions appropriate for infection
prevention and control (see “Control and Prevention,” below).
Treatment of FVD has historically been entirely supportive (and
even that therapy has been limited by resource constraints) as
the efficacy and safety of specific antiviral countermeasures had
not been rigorously studied outside of animal models of disease.
The 2013–2016 EVD outbreak in Western Africa highlighted the
need to conduct rigorous, feasible, and ethically acceptable clinical research in the outbreak setting. Building on challenges and
lessons learned in that setting, the first-of-its-kind Pamoja Tulinde
Maisha (PALM) randomized clinical trial was conducted during
the 2018–2020 EVD outbreak in the Democratic Republic of the
Congo and identified two therapeutics based on Ebola virus–
specific mAbs to improve survival rates. mAb114 (ansuvimab-zykl)
and REG-EB3 (atoltivimab, maftivimab, and odesivimab-ebgn)
were subsequently approved for the treatment of EVD in PCRconfirmed adults (including pregnant women) and children. Both
are administered via carefully monitored single dose infusions to be
initiated as soon as possible after diagnosis. In addition, the PALM
trial demonstrated the will and capacity to deliver more advanced
supportive and critical care accompanying specific therapeutics in
the outbreak setting. Although evidence is lacking, consensus treatment strategies include those generally recommended for severe
septicemia/sepsis/shock (Chap. 304) and should be applied with an
emphasis on standard approaches—i.e., monitoring and response to
respiratory dysfunction (e.g., oxygen), circulatory dysfunction (e.g.,
intravascular fluid repletion and vasopressor support), and CNS
dysfunction (e.g., ruling out of reversible causes, notably hypoglycemia)—as well as the detection and management of acute kidney
injury, hemorrhage, electrolyte derangements, and nutritional status and the prevention and treatment of secondary or co-infections.
Pain management and administration of antipyretics, antiemetics,
and antidiarrheal agents may be considered. Crucial strategies to
improve outcomes in the most severely ill FVD patients include
preventing organ dysfunction and providing safe and effective
temporary organ support (e.g., mechanical ventilation and renal
replacement) in order to expand the window for administration of
medical countermeasures and development of effective endogenous
immune responses.
■ COMPLICATIONS
Even in patients who have initial virologic or clinical improvement,
complications in the second or third weeks of illness may include
secondary infections, persistent renal dysfunction, neurologic compromise (e.g., Ebola-virus-related meningoencephalitis, cerebrovascular
events, seizures), cardiac dysfunction (e.g., myocarditis, pericarditis),
and venous thrombosis. Pregnancy and labor cause severe and frequently fatal complications in filovirus infections due to clotting factor
consumption, fetal loss, and/or severe blood loss during birth.
A number of sequelae have been self-reported or historically
described in survivors of FVD, including prolonged and sometimes
incapacitating arthralgia and myalgia, asthenia, alopecia, visual problems (including uveitis), hearing loss, memory loss and neurocognitive
dysfunction, mental health conditions (anxiety, depression, posttraumatic
stress disorder), and reproductive problems. Well-controlled observational studies of EVD survivors were first conducted in the aftermath of
the 2013–2016 West African EVD outbreak. Compared with their closecontact controls, Liberian EVD survivors had an increased incidence
of headache, arthralgia and myalgia, memory loss, fatigue, and urinary
frequency as well as abnormal results in abdominal, chest, neurologic,
musculoskeletal, and ocular exams. Of individual and public health
significance is the potential for persistence of filoviruses in immuneprivileged tissue compartments (and their associated fluids) in FVD
survivors, most commonly in the semen of male survivors (with the rare
but documented potential for sexual transmission and reignition of outbreaks) and rarely in the CNS (causing recrudescent meningoencephalitis), the eye (causing recrudescent uveitis), and the placenta (causing
transmission or placental insufficiency). True relapses that resemble
the course of primary FVD are extremely rare but have been described.
■ PROGNOSIS
Among the most severe of acute viral diseases in humans, FVD generally has a poor prognosis, although with much greater heterogeneity
than was historically assumed; i.e., the 90% case–fatality rate ascribed
for many decades to EVD has required revision. With an incomplete
evidence base, the outcome probably depends on factors that include the
particular filovirus causing the infection (Fig. 210-3), host factors (age,
immune status, unknown host genetic factors), virus exposure route and
dose, viral load, the presence and severity of organ dysfunction, and—
critically—the availability of filovirus-specific countermeasures and
requisite supportive care. Continued advances in the latter countermeasures and supportive care will likely result in improved survival
rates in EVD, but the long-term health and well-being of and survival
outcomes for FVD survivors are unknown. It is also uncertain how
increased access to filovirus-specific therapeutics and life-saving
support will impact filovirus persistence in survivors; short- and longterm surveillance will be necessary to avoid individual consequences
(e.g., relapse, recrudescent inflammatory syndromes) and public health
consequences (e.g., reignition of outbreak transmission chains in the
peri-outbreak or post-outbreak period).
Although remarkable progress has been made at the human EVD
bedside, the same cannot yet be said for disease caused by filoviruses
other than Ebola virus, either in acute disease or in convalescence.
1652 PART 5 Infectious Diseases
■ CONTROL AND PREVENTION
Prevention of filovirus exposure in nature is difficult because the
ecology of the viruses is not completely understood. To prevent marburgvirus infection, the most useful advice to people entering or living
in areas where Egyptian rousettes can be found is to avoid direct or
indirect contact with these animals. Prevention in nature is more difficult in the case of pathogenic ebolaviruses, largely because definite
reservoirs have not yet been pinpointed. EBOD outbreaks have been
associated not so much with bats as with hunting or consumption of
nonhuman primates. The mechanism of introduction of ebolaviruses
into nonhuman primate populations, if it occurs at all, is unclear. (Only
one ebolavirus, Taï Forest virus, has unequivocally been detected in
wild nonhuman primates.) Therefore, for now, to prevent ebolavirus
infection, the only advice that can be offered to travelers and locals
is to avoid contact with bushmeat, nonhuman primates, and bats. In
any setting, the early local involvement of medical anthropologists is
strongly advised to ensure proper communications and explanations
that are not perceived as threatening or patronizing.
Biomedical prevention strategies have historically been limited to
tried-and-true pillars of outbreak control, centering on the identification and isolation of cases, contact tracing, ensuring that health
care workers and other response personnel have appropriate training
and capacity in infection prevention and control, and preventing
high-risk transmission events. Measures aimed at preventing and
controlling infection, including relatively simple barrier nursing
techniques, vigilant use of appropriate PPE, quarantine, and contact
tracing, usually effectively terminate or at least contain FVD outbreaks. Isolation of infected people and their contacts and avoidance
of direct person-to-person contact without appropriate PPE usually
prevents further spread, as the virions are not transmitted through
droplets or aerosols under natural conditions. Typical protective gear
sufficient to prevent filovirus infections consists of disposable gloves,
gowns, and shoe covers and a face shield and/or goggles. If available,
N-95 or N-100 respirators may be used to further limit infection risk.
Positive-air-pressure respirators should be considered for high-risk
medical procedures, such as intubation or suctioning. Medical equipment used in the care of an infected patient, such as gloves or
syringes, should never be reused. Because filovirions are enveloped,
disinfection with detergents (e.g., 1% sodium deoxycholate, diethyl
ether, or phenolic compounds) is relatively straightforward. Bleach
solutions are recommended at 1:100 for surface disinfection and
1:10 for application to excreta or corpses. Whenever possible, potentially contaminated materials should be autoclaved, irradiated, or
destroyed.
Emerging from research conducted during the 2013–2016 EVD
outbreak in Western Africa, a vaccine based on a recombinant vesicular
stomatitis Indiana virus expressing Ebola virus glycoprotein (rVSVZEBOV/Ervebo) was the first filovirus vaccine approved for use in
the United States and the European Union. It is now widely deployed
in a reactive-ring vaccination strategy, targeting close contacts and
their contacts in EVD outbreak settings, and also used for vaccination
of health care workers. Development and evaluation of other vaccine
candidates continue toward complementary preventive approaches for
non-outbreak or peri-outbreak settings, with emphasis on the durability
of immune responses and increases in preventive breadth toward other
filoviruses.
Even in the absence of high-level evidence, expert consensus
informs the targeted use of Ebola-virus–specific vaccine or postexposure prophylaxis to prevent infection or disease in health care
workers considered to have had a high-risk Ebola virus exposure (e.g.,
after needlestick injury). For male survivors, abstinence from sexual
activity with a partner for at least 12 months after disappearance of
clinical signs is recommended, unless testing proves semen to be free
of filoviruses. (The use of condoms is generally recommended for all
sexual activities.) Reproductive tract and CNS tissues, including ocular
tissues and fluids from survivors, should be handled with appropriate precautions until demonstrated to be filovirus-free. The role of
filovirus-specific therapeutics in the prevention or treatment of filoviral persistence is unclear.
■ FURTHER READING
Cnops L et al: Essentials of filoviral load quantification. Lancet Infect
Dis 16:e134, 2016.
Dudas G et al: Virus genomes reveal factors that spread and sustained
the Ebola epidemic. Nature 544:309, 2017.
Hoenen T et al: Therapeutic strategies to target the Ebola virus life
cycle. Nat Rev Microbiol 17:593, 2019.
Jacob ST et al: Ebola virus disease. Nat Rev Dis Primers 6:13, 2020.
Kuhn JH et al: Filoviridae, in Fields Virology, Vol 1, 7th ed, PM
Howley et al (eds). Philadelphia, Wolters Kluwer/Lippincott Williams
& Wilkins, 2020, pp 449–503.
Matz KM et al: Ebola vaccine trials: Progress in vaccine safety and
immunogenicity. Expert Rev Vaccines 18:1229, 2019.
Mulangu S et al: A randomized, controlled trial of Ebola virus disease
therapeutics. N Engl J Med 381:2293, 2019.
Regules JA et al: A recombinant vesicular stomatitis virus Ebola vaccine. N Engl J Med 376:330, 2017.
Section 16 Fungal Infections
211
DEFINITION AND ETIOLOGY
In recent decades, human fungal infections have dramatically increased
worldwide as a result of the AIDS pandemic, the widespread use of
antibacterial agents, and the introduction of cytotoxic agents and
precision medicine biologics for the treatment of autoimmune and
neoplastic diseases and for use in patients undergoing solid organ
transplantation or hematopoietic stem cell transplantation. Moreover,
of great concern has been the recent rise in fungal infections caused
by drug-resistant species, such as azole- and/or echinocandin-resistant
Candida glabrata and Candida auris and azole-resistant Aspergillus
fumigatus. Among the ~5 million fungal species, only a few cause
human infections (Table 211-1).
Fungal infections are classified as mucocutaneous and deep organ
infections on the basis of anatomic location and as endemic and
opportunistic infections on the basis of epidemiology. Mucocutaneous
infections can cause serious morbidity but are rarely fatal. Deep organ
infections cause severe illness and often carry a high mortality rate. The
endemic mycoses are caused by fungi that are not part of the normal
human microbiota but are environmentally acquired. The opportunistic mycoses are caused by fungi (Candida, Aspergillus) that often are
components of the human microbiota and whose ubiquity in nature
renders them easily acquired by immunosuppressed hosts (Table 211-1).
Opportunistic fungi cause serious infections when impaired host
immune responses allow the organisms to transition from commensals to invasive pathogens. Endemic fungi typically cause self-limited
disease in immunocompetent hosts but severe illness in immunosuppressed patients.
Fungi are morphologically classified as yeast, mold, and dimorphic.
Yeasts are seen as round single cells or budding organisms. Molds grow
as filamentous forms called hyphae both at room temperature and in
tissue. Aspergillus, Mucorales, and dermatophytes that infect skin and
nails are mold fungi. Variations exist within this classification system.
For instance, when Candida infects tissue, both yeasts and filamentous forms (pseudohyphae) may be present (except in the cases of
Pathogenesis, Diagnosis,
and Treatment of
Fungal Infections
Michail S. Lionakis,
John E. Edwards Jr.
1653CHAPTER 211 Pathogenesis, Diagnosis, and Treatment of Fungal Infections
TABLE 211-1 Major Fungal Infections, Associated At-Risk Patient Populations, and Diagnostic Tests
INFECTION (MOST COMMON
FUNGAL GENERA AND SPECIES) CLINICAL SYNDROME(S) RISK FACTOR(S) DIAGNOSTIC TEST(S)
Mold (Filamentous) Fungi
Aspergillosis
(Aspergillus fumigatus, A. terreus,
A. flavus, A. niger, A. nidulansa
)
Pneumonia or disseminated
infection
ABPA
Keratitis
Neutropenia, glucocorticoids,
HSCT, post-influenza or
COVID-19, BTK inhibition
Atopic individuals
Direct inoculation
Culture of BAL fluid: low sensitivity, nonspecific (colonization,
contamination)
Histologic examination of tissueb
: acute-angle septate hyphae
Biomarkers: GM (BAL > serum); serum BDG (nonspecific)
Mucormycosis
(Rhizopus, Rhizomucor, Mucor,
Cunninghamella, and Lichtheimia
spp.)
Sinopulmonary infection
Rhinocerebral infection
Necrotizing skin infection
Neutropenia, HSCT
Diabetic ketoacidosis
Direct inoculation (e.g., tornado
victims)
Culture of BAL fluid or sinus tissue: very low sensitivity
Histologic examination of tissue: ribbon-like aseptate hyphae
Biomarkers: Negative
Fusariosis
(Fusarium solani, F. oxysporum)
Pneumonia or disseminated
infection
Keratitis
Neutropenia
Direct inoculation
Culture of tissue or blood: one of the few molds recovered
from blood
Histologic examination of tissue: acute-angle septate hyphae
Biomarkers: GM can be positive; BDG (nonspecific)
Scedosporiosis
(Scedosporium apiospermum)
Pneumonia or disseminated
infection
Neutropenia, glucocorticoids,
HSCT
Culture of BAL: low sensitivity, nonspecific (colonization,
contamination)
Histologic examination of tissue: acute-angle septate hyphae
Biomarkers: BDG can be positive
Phaeohyphomycosis
(Cladophialophora, Alternaria,
Phialophora, Rhinocladiella,
Exophiala, and Exserohilum spp.)
Sinopulmonary, CNS, or
disseminated infection
Skin infection
Allergic sinusitis
HSCT, neutropenia,
glucocorticoids, healthy
individuals (for CNS)
Direct inoculation
Atopic individuals
Culture of ordinarily sterile site
Histologic examination of tissue: cell walls may appear
dark brown or golden on H&E; Fontana-Masson may stain
fungal melanin
Dermatophytosis
(Trichophyton, Microsporum, and
Epidermophyton spp.)
Skin and nail infections Healthy individuals Culture or microscopic examination of scrapings or clippings:
chains of arthrospores (diagnostic)
Eumycetoma
(Madurella mycetomatis)
Skin and subcutaneous
infections
Healthy individuals Culture and macroscopic and histologic examination of grains
harvested from biopsy or aspiration
Yeast Fungi
Mucosal candidiasisc
(Candida albicans, C. glabrata)
Oropharyngeal or
esophageal candidiasis
Vulvovaginal candidiasis
AIDS, glucocorticoids
Antibiotic use
Culture of mucosal surfaces
Histologic examination of esophageal tissue or wet
preparation (10% KOH) of vaginal discharge: yeast and/or
pseudohyphae
Invasive candidiasisc
(C. albicans, C. glabrata,
C. parapsilosis, C. tropicalis, C. auris)
Candidemia
Disseminated infection
(spleen, liver, kidney, eye,
heart, CNS)
Critical illness (ICU)
Neutropenia, glucocorticoids
Culture of blood: low sensitivity
Histologic examination of tissue: yeast and/or pseudohyphae
Biomarkers/other tests: BDG (nonspecific); T2 magnetic
resonance in whole blood
Cryptococcosis
(Cryptococcus neoformans, C. gattii)
Pneumonia
Osteomyelitis
Meningoencephalitis
AIDS, glucocorticoids
Sarcoidosis
AIDS, AAbs to IFN-γ
or GM-CSF, BTK or JAK
inhibition
Culture of CSF, BAL fluid, blood
Microscopic examination of tissue or
CSF: encapsulated yeast (GMS, India ink, mucicarmine stain)
Biomarkers: Cryptococcus Ag (serum, CSF) is sensitive
and specific
Trichosporonosisd
(Trichosporon asahii, T. mucoides,
T. asteroides)
Superficial skin infection
(white piedra)
Disseminated infection
(skin, eye)
Healthy individuals
Neutropenia, glucocorticoids,
HSCT, SOT
Culture of tissue or blood
Histologic examination of tissue: yeasts, hyphae,
and arthroconidia
Biomarkers: BDG can be positive
Endemic Dimorphic Fungi
Histoplasmosis
(Histoplasma capsulatum, H. duboisii
[in Africa])
Self-limited pneumonia
Disseminated infection
(liver, bone, bone marrow)
Fibrosing mediastinitis
Healthy individuals
AIDS, SOT, glucocorticoids,
AAbs to IFN-γ, JAK or TNF-α
inhibition
Culture of blood or tissue: low sensitivity; weeks needed
for growth
Histologic examination of tissue: yeast with narrow-based
budding
Other tests: Histoplasma Ag (urine > serum > BAL); BDG can
be positive; serology (CF) can be useful in non-AIDS patients
Blastomycosis
(Blastomyces dermatitidis,
B. gilchristii)
Pneumonia
Disseminated infection
(skin, bone, mucosal
surfaces, genitourinary tract)
Healthy individuals
AIDS, glucocorticoids,
TNF-α inhibition
Culture of BAL or tissue: low sensitivity; weeks needed for
growth
Histologic examination of tissue: yeast with broad-based budding
Other tests: serology (CF, ID) has low sensitivity; Blastomyces Ag
test cross-reacts with other endemic fungi; GM can be positive
Coccidioidomycosis
(Coccidioides immitis, C. posadasii)
Self-limited pneumonia
Disseminated infection
(CNS, bone)
Healthy individuals
AIDS, glucocorticoids,
TNF-α inhibition
Culture is diagnostice
Histologic examination: spherules
Other tests: serology (CF, ID); Coccidioides Ag test can be
useful in CNS infection; BDG can be positive
(Continued)
1654 PART 5 Infectious Diseases
TABLE 211-1 Major Fungal Infections, Associated At-Risk Patient Populations, and Diagnostic Tests
INFECTION (MOST COMMON
FUNGAL GENERA AND SPECIES) CLINICAL SYNDROME(S) RISK FACTOR(S) DIAGNOSTIC TEST(S)
Paracoccidioidomycosis
(Paracoccidioides brasiliensis,
P. lutzii)
Pneumonia
Disseminated infection
(skin, bone, mucosal
surfaces)
Healthy individuals
AIDS, glucocorticoids
Culture of tissue: active disease; several weeks
needed for growth
Histologic examination of KOH preparations or tissue: yeast
with budding in steering-wheel pattern
Other tests: serology (ID, CF); Paracoccidioides Ag test
Sporotrichosis
(Sporothrix schenckii)
Lymphocutaneous infection
(ascending lymphangitis)
Disseminated infection
Direct inoculation
AIDS, glucocorticoids
Culture of tissue (diagnostic)
Histologic examination: cigar-shaped yeast, often with
surrounding asteroid body
Talaromycosis
(Talaromyces marneffei)
Pneumonia
Disseminated infection
(skin, bone, mucosal
surfaces)
Healthy individuals
AIDS, glucocorticoids,
AAbs to IFN-γ
Culture of tissue (diagnostic)
Histologic examination of tissue: yeasts with transverse septa
Biomarkers: GM is often positive
Adiaspiromycosis
(Emmonsia crescens, E. parva)
Pneumonia Occupational dust exposure Culture: nonculturable
Histologic examination: thick-walled adiaspore within
granuloma
Emergomycosis
(Emergomyces africanus,
E. pasteurianus)
Disseminated infection
(lungs, skin)
AIDS, SOT Culture of infected tissue
Histologic examination of tissue: yeast with narrowbased budding
Biomarkers: Histoplasma Ag can be positive
Chromoblastomycosis
(Fonsecaea pedrosoi,
F. monophora)
Skin and subcutaneous
tissue infections
Healthy individuals Culture of infected tissue
Histologic examination of scrapings (KOH) or tissue (GMS):
sclerotic bodies (pathognomonic)
Other Fungi
Pneumocystosisf
(Pneumocystis jirovecii)
Pneumonia
Disseminated infection (eye,
CNS, skin, gastrointestinal
tract)
AIDS, glucocorticoids,
BTK inhibition
AIDS
Culture: nonculturable
Histologic examination (gold standard): special (GMS, DiffQuik) or immunofluorescence stains
Biomarkers/other tests: BDG (nonspecific); BAL fluid PCR
(sensitive; can be positive in colonized individuals)
a
A. nidulans is seen almost exclusively in chronic granulomatous disease. b
GMS or PAS stains. c
Some Candida species form pseudohyphae. d
Trichosporon species are
yeast-like fungi that also generate septate hyphae and arthroconidia. e
Coccidioides is a laboratory hazard. It is important to notify the microbiology laboratory if this
infection is suspected. f
Pneumocystis is present in cyst and trophozoite forms.
Abbreviations: AAbs, autoantibodies; ABPA, allergic bronchopulmonary aspergillosis; Ag, antigen; BAL, bronchoalveolar lavage; BDG, β-D-glucan; BTK, Bruton’s tyrosine
kinase; CF, complement fixation; CNS, central nervous system; CSF, cerebrospinal fluid; GM, galactomannan; GM-CSF, granulocyte-macrophage colony-stimulating factor;
GMS, Gomori methenamine silver; H&E, hematoxylin and eosin; HSCT, hematopoietic stem cell transplantation; ICU, intensive care unit; ID, immunodiffusion; IFN-γ,
interferon γ; JAK, Janus kinase; KOH, potassium hydroxide; PAS, periodic acid–Schiff; PCR, polymerase chain reaction; SOT, solid organ transplantation; TNF-α, tumor
necrosis factor α.
C. glabrata and C. auris, which form only yeasts in tissue); in contrast,
Cryptococcus exists only in yeast form. Dimorphic is the term used to
describe fungi that grow as yeasts or large spherical structures in tissue
but as filamentous forms at room temperature in the environment
(Table 211-1).
Patients acquire deep organ infection by molds and endemic dimorphic fungi via inhalation. Skin dermatophytes are primarily environmentally acquired, but human-to-human transmission may also occur.
The commensal Candida invades deep tissues from sites of mucosal
colonization, usually in the gastrointestinal tract.
In this chapter, we outline general principles of immunology,
diagnosis, and treatment related to the most common human fungal
infections.
■ PATHOGENESIS
In the past decade, our understanding of fungal recognition pathways
and of tissue-specific innate and adaptive antifungal host defense mechanisms has markedly expanded. A major breakthrough has been the
discovery and functional characterization of the C-type lectin receptor/
spleen tyrosine kinase/caspase recruitment domain–containing protein 9
(CLR/SYK/CARD9) signaling pathway, which mediates fungal polysaccharide recognition and orchestrates proinflammatory mediator
production, leukocyte recruitment, inflammasome activation, and
Th17 cell differentiation upon fungal invasion. Human inherited
CARD9 deficiency causes severe mucocutaneous and invasive fungal
disease and is the only known primary immunodeficiency to feature
fungus-specific infection susceptibility without a predisposition to
other infections, autoimmunity, allergy, or cancer. Notably, CARD9-deficient patients develop infections by certain fungi in certain tissues,
including (1) chronic mucocutaneous candidiasis linked to defective
interleukin (IL) 17 responses; (2) infections of the central nervous
system (CNS) caused by Candida (but also by Aspergillus and phaeohyphomycetes) and linked to impaired microglial-neutrophilic responses;
and (3) deep dermatophytosis. Thus, the clinical use of SYK inhibitors
for autoimmunity and cancer may cause opportunistic fungal disease.
Human inherited deficiency of Toll-like receptor (TLR) signaling does
not lead to spontaneous fungal disease, yet polymorphisms in TLR
pathway molecules may increase the risk of fungal disease in critically
ill or immunosuppressed persons, and TLR stimulation may boost
protective CLR immunity, as has been shown with the TLR7 agonist
imiquimod in chromoblastomycosis.
The development of clinically relevant animal models of mycoses
and the phenotypic characterization of fungal infections that develop
in patients with primary immunodeficiencies and in recipients of
immune pathway–targeting biologics have led to the delineation of
fungus-, cell-, and tissue-specific requirements for antifungal host
defense (Fig. 211-1).
At the mucosal interface, IL-17-producing lymphoid cells play a
critical role in protection by driving epithelial cell production of antimicrobial peptides that restrict mucosal Candida invasion. Indeed,
AIDS patients are at risk for mucosal—but not invasive—candidiasis.
Concordantly, inherited deficiency of IL-17 signaling caused by mutations in IL17F, IL17RA, IL17RC, or TRAF3IP2 (encoding the IL-17
receptor adaptor ACT1) or pharmacologic inhibition of IL-17 signaling
(Continued)
1655CHAPTER 211 Pathogenesis, Diagnosis, and Treatment of Fungal Infections
IL6R
IL23R
CXCR2
CXCR2
NADPH
NADP+
O2
–
H2O2
SOD
e–
CXCL1
GM-CSF
IFN-λ
Aspergillus
conidia
Phagosome
Multilobed
nucleus
CXCL2
Blood
Lung
RORγT
γδ T cell
AAbs
AAbs
IL-22
IL-17RA IL-17RC IL-22R1 IL-10Rβ
IL-17F
IL-17A
IL-17A/IL-17F
ACT1
Epithelial cells
Macrophage
Th17 cell Neutrophil Th1 cell
Neutrophil
Nucleus
Nucleus
TYK2
TYK2
JAK2
JAK2
17RA IL-17RC IL-22R1 IL-10
ACT1
Ep c al itheliap thelial cells
Candida
yeast and
pseudohyphae
Nucleus
GM-CSF
IFN-γR1
IFNγ
IFNγ
JAK2
JAK1
JAK2
STAT4
STAT1
STAT1
STAT4
TYK2
IL12Rβ1 IL12Rβ2
AAbs
IFN-γR2 TNFα
IL-12
IL-12
Yeast
(Histoplasma,
Cryptococcus)
Phagosome
IFNγ
STAT3
STAT3
p22phox
gp91phox
p67phox p47phox
p40phox
FIGURE 211-1 Host defense against fungi. Left: Production of IL-17A, IL-17F, and IL-22 by Th17 cells, Tc17 cells, γ δ T cells, and innate lymphoid cells confers protection from
mucosal Candida invasion. STAT3 promotes Th17 differentiation via RORγt induction. IL-17A and IL-17F bind to IL-17RA and IL-17RC on epithelial cells and signal via ACT1
to produce antimicrobial peptides that inhibit fungal growth. IL-22 binds to its receptor on epithelial cells and activates STAT3 to mediate epithelial proliferation and repair.
Middle: Activation of CXCR2+
neutrophils recruited from blood in the Aspergillus-infected lung enables assembly of the five subunits of NADPH oxidase and superoxide
generation that promotes fungal killing. Production of reactive oxygen species by neutrophils is facilitated by recruited monocyte-derived and plasmacytoid dendritic cells
via type I and type III IFNs and GM-CSF. Right: The interaction of Th1 cells with macrophages is protective against intramacrophagic endemic dimorphic fungi, Pneumocystis,
and Cryptococcus. Upon fungal uptake, macrophages produce IL-12 that binds to its receptor on T cells and activates STAT4, with consequent release of IFN-γ. IFN-γ binds to
its receptor on macrophages and activates STAT1, thereby enabling fungal killing. TNF-α and GM-CSF are also critical for macrophage activation. AAbs, autoantibodies; IL,
interleukin; IFN, interferon; JAK, Janus kinase; GM-CSF, granulocyte-macrophage colony-stimulating factor; NADPH, nicotinamide adenine dinucleotide phosphate; RORγt;
RAR-related orphan receptor γ; SOD, superoxide dismutase; STAT, signal transducer and activator of transcription; TNF, tumor necrosis factor; TYK2, tyrosine kinase 2.
by biologics that target IL-12p40, IL-23p19, IL-17A, IL-17A/IL-17F, or
IL-17RA causes mucosal—but not invasive—candidiasis. Other conditions that underlie a predisposition to chronic mucocutaneous candidiasis include primary immunodeficiencies due to mutations in STAT3,
STAT1, DOCK8, JNK1, IRF8, RORC, and CARD9, all of which impair
Th17 cells, as well as autoimmune polyendocrinopathy–candidiasis–
ectodermal dystrophy (APECED) and thymoma, which feature autoantibodies to IL-17A, IL-17F, and IL-22. Of note, vaginal candidiasis
(unlike oropharyngeal and esophageal candidiasis) develops in the
setting of antibiotic treatment, not AIDS; this observation underscores
the role of the microbiota in fungal control at the vaginal—but not the
oral—mucosa.
On the other hand, neutrophils—but not lymphocytes—are critical
for control of invasive infections caused by Aspergillus (and other
inhaled molds) and Candida (Fig. 211-1). Indeed, patients with
chemotherapy-induced neutropenia and patients undergoing allogeneic hematopoietic stem cell transplantation are at risk for invasive
aspergillosis and candidiasis. Both oxidative and nonoxidative burst–
dependent effector mechanisms are operational within neutrophils
for fungal killing. Inherited deficiency in neutrophil superoxide
generation due to mutations in the five subunits of the nicotinamide
adenine dinucleotide phosphate (NADPH) oxidase complex causes
chronic granulomatous disease, a prototypic primary immunodeficiency that carries a lifetime risk for invasive aspergillosis of ~40–50%;
infrequently (i.e., in <5% of cases), chronic granulomatous disease
predisposes to invasive candidiasis. The unexpected development of
invasive mold infections in recipients of Bruton’s tyrosine kinase (BTK)
inhibitors has recently uncovered the critical role of BTK in promoting
myeloid phagocyte-dependent antifungal effector functions.
Moreover, host defenses against fungi that reside within macrophages, such as Cryptococcus, Pneumocystis, and endemic dimorphic
fungi, depend on the interplay of interferon γ (IFN-γ)–producing
lymphoid cells and IL-12-producing macrophages that enable intramacrophagic fungal killing (Fig. 211-1). Indeed, AIDS patients and
those receiving glucocorticoids, which affect lymphocytes and macrophages both quantitatively and qualitatively, are at risk for severe
infections by these fungi. Accordingly, inherited impairment of the
IL-12/IFN-γ signaling axis caused by mutations in IL12RB1, IFNGR1,
IFNGR2, STAT1, IRF8, or GATA2 underlies susceptibility to severe
infection by intramacrophagic fungi (and other intramacrophagic
pathogens, such as mycobacteria and salmonellae). In addition, the
IFN-γ-targeting monoclonal antibody emapalumab, JAK inhibitors
1656 PART 5 Infectious Diseases
that block IFN-γ-dependent cellular responses, and autoantibodies
to IFN-γ predispose to infection with intramacrophagic fungi, as do
biologics targeting tumor necrosis factor α (TNF-α) and autoantibodies to granulocyte-macrophage colony-stimulating factor (GM-CSF).
The latter predisposing factors reveal the central role of these two
Th1-associated cytokines—TNF-α and GM-CSF—in macrophage
activation.
Taken together, these observations show that the cellular and
molecular factors that drive protective antifungal immune responses
vary greatly with the anatomic site of the infection, the offending
fungus, and the patient population (Table 211-1). The growing body
of data on human immunologic responses to fungi holds promise in
informing precision medicine strategies for risk assessment, prophylaxis, immunotherapy, and vaccination of vulnerable patients.
■ DIAGNOSIS
The diagnostic modalities used for various fungal infections are
outlined in Table 211-1 and are detailed in the chapters on specific
mycoses that follow in this section. Definitive diagnosis of a fungal
infection requires histopathologic identification of the fungus invading
tissue with parallel culture of the fungus from the specimen. Certain
fungi have distinctive morphologic features that facilitate diagnosis
(Table 211-1). The stains most often used to identify fungi are periodic acid–Schiff and Gomori methenamine silver. Candida, unlike
other fungi, is visible on gram-stained tissue smears. Hematoxylin and
eosin stains define accompanying histologic features of fungal disease
(granuloma formation, angioinvasion, necrosis) but are insufficient to
reliably identify fungi in tissue. A positive India ink stain of cerebrospinal fluid (CSF) is diagnostic for cryptococcosis. Most laboratories use
calcofluor white staining coupled with fluorescence microscopy to
identify fungi in fluid specimens. A positive fungal culture of blood or
tissue may signify either a patient’s colonization or lab contamination
instead of true infection, with the most likely scenario depending on
the fungus and the anatomic site. In blood, Candida can be detected
with any of the widely used automated blood culture systems, but
the lysis-centrifugation technique increases the sensitivity of blood
cultures for both Candida and other less common fungi (e.g., Histoplasma). Matrix-assisted laser desorption/ionization time-of-flight
mass spectrometry (MALDI-TOF-MS) is now used extensively for
detection and speciation of fungi recovered from culture.
The several available fungal-antigen and serologic tests vary in sensitivity and specificity. The most reliable of these tests are the antibody
to Coccidioides, Histoplasma antigen, and cryptococcal polysaccharide
antigen. Serologic tests are also available for other endemic dimorphic
fungi (Table 211-1). The galactomannan test—especially in the bronchoalveolar lavage fluid—is useful for the diagnosis of aspergillosis;
however, false-negative results are common, particularly in patients
receiving antifungal prophylaxis, and false-positive results may occur
with other fungal infections. The β-glucan test has a high negative
predictive value for invasive candidiasis but lacks specificity. T2
magnetic resonance is now approved by the U.S. Food and Drug
Administration (FDA) for detection of Candida in blood. Several
polymerase chain reaction and nucleic acid hybridization assays exist
for fungal detection but are not standardized and are not widely used
in the clinic.
■ ANTIFUNGAL DRUGS
This section provides a brief overview of available agents for the treatment of fungal infections. Drug regimens and schedules are detailed
in the chapters on specific mycoses that follow in this section. Since
fungal organisms, like human cells, are eukaryotic, the identification
of drugs that selectively kill or inhibit fungi but that are not toxic to
human cells poses challenges. Indeed, far fewer antifungal than antibacterial agents have been introduced into clinical medicine.
Early initiation of appropriate antifungal therapy is a critical determinant of favorable outcome, as has been shown for candidemia,
aspergillosis, and mucormycosis. In addition, source control of the
infection is important—e.g., with removal of the central venous catheter in candidemia, drainage of abdominal abscesses in intraabdominal
candidiasis, and surgical debridement of sinus tissue in mucormycosis. Moreover, an essential factor in a favorable prognosis in
patients with opportunistic mycoses is the achievement of immune
reconstitution—e.g., with neutrophil recovery, tapering of glucocorticoids or other immunosuppressive drugs, or initiation of combination
antiretroviral therapy in AIDS.
■ AMPHOTERICIN B
The advent of amphotericin B (AmB) in the 1950s revolutionized the
treatment of deep-seated mycoses. Before the availability of AmB,
cryptococcal meningitis and other disseminated fungal infections were
nearly always fatal. AmB remains the broadest-spectrum antifungal
agent. Its fungicidal mechanism of action involves direct binding to
ergosterol and intercalation into the fungal cell membrane, which leads
to osmotic cell lysis. AmB remains the preferred antifungal agent for
the treatment of mucormycosis and fusariosis and for induction therapy for cryptococcal meningitis and disseminated infections caused
by endemic dimorphic fungi. However, AmB has several limitations,
including lack of an oral formulation and significant toxicity, primarily
renal and infusion-related (fever, chills, thrombosis). The introduction of lipid AmB formulations has ameliorated these toxicities, and
the lipid formulations have largely replaced the original deoxycholate
formulation in resource-rich settings. In developing countries, AmB
deoxycholate is still widely used because of the high cost of the lipid
formulations. The two lipid formulations commonly used in the clinic
are liposomal AmB and AmB lipid complex, which exhibit comparable
efficacy, toxicity, and tissue penetration profiles.
■ AZOLES
Azoles offer important advantages over AmB, such as the availability of
oral and IV formulations and a lack of renal toxicity. The mechanism of
action of azoles involves inhibition of lanosterol 14α-demethylase and
ergosterol synthesis in the fungal cell membrane, with a consequent
accumulation of toxic sterol intermediates and growth arrest. Unlike
AmB, azoles are considered fungistatic.
Fluconazole Fluconazole plays an important role in the treatment
of several fungal infections. Its major advantages are the availability of
oral and IV formulations, a long half-life, penetration into most body
fluids (ocular fluid, CSF, urine), and minimal toxicity. This drug rarely
causes liver toxicity; high doses may result in alopecia, dry mouth,
and a metallic taste. Notably, the administration of even low doses of
fluconazole to pregnant women for the treatment of vaginal candidiasis
was recently linked to miscarriage and stillbirth. Fluconazole has no
activity against molds and most endemic dimorphic fungi and is less
active than the newer azoles against C. glabrata and C. krusei.
Fluconazole is the preferred agent for the treatment of coccidioidal
meningitis, although relapses may occur despite therapy. Fluconazole
is also used as consolidation and maintenance therapy for cryptococcal
meningitis and for the treatment of mucosal candidiasis. It is used for
treating candidemia in patients who are not critically ill or immunosuppressed; in these patients, fluconazole was found to be as efficacious
as AmB. Because of increasing rates of azole-resistant Candida strains,
many clinicians opt to initiate therapy with an echinocandin, which is
replaced by fluconazole once a susceptible Candida species is recovered. Fluconazole is effective as prophylaxis in recipients of high-risk
liver and allogeneic bone marrow transplants, although many centers
now use posaconazole in neutropenic patients, given its added spectrum against molds. Fluconazole prophylaxis in leukemic patients, in
AIDS patients with low CD4+ T-cell counts, and in patients on surgical
intensive care units is controversial.
Itraconazole Itraconazole is available in oral (capsule, suspension)
and IV formulations and has broader antifungal activity—i.e., against
molds and endemic dimorphic fungi. Itraconazole is the drug of choice
for mild to moderate histoplasmosis and blastomycosis and has also
been used to treat chronic coccidioidomycosis, phaeohyphomycosis,
sporotrichosis, and mucocutaneous mycoses such as oropharyngeal candidiasis, tinea versicolor, tinea capitis, and onychomycosis.
Although it is approved by the FDA for use in febrile neutropenic
1657CHAPTER 211 Pathogenesis, Diagnosis, and Treatment of Fungal Infections
patients, most centers now use newer azoles in such patients. Disadvantages of itraconazole include its poor CSF penetration, the use of
cyclodextrin in its oral suspension and IV formulation, and its variable
level of absorption in the capsule form, which requires monitoring of
blood levels in patients receiving capsules for disseminated mycoses.
Itraconazole is a potent CYP3A4 inhibitor; this characteristic leads to
significant drug interactions. The drug causes hepatotoxicity and cardiac toxicity that may manifest as congestive heart failure.
Voriconazole Voriconazole is also available in oral and IV formulations, has far broader antifungal activity than fluconazole (including C. glabrata, C. krusei, Aspergillus, Scedosporium, and endemic
dimorphic fungi—but not Mucorales), and penetrates into most body
fluids (ocular fluid, CSF). It is the preferred agent for the treatment of
aspergillosis and also has been used to treat scedosporiosis and as stepdown (but not primary) therapy for coccidioidomycosis, blastomycosis, and histoplasmosis. Voriconazole is considerably more expensive
than fluconazole, and, as with itraconazole, its use is associated with
numerous interactions with drugs typically used in patients at risk for
fungal infections. Hepatotoxicity, visual disturbances, and skin rashes
(including photosensitivity) are relatively common, and long-term use
requires skin cancer surveillance. A unique toxicity of voriconazole
among azoles is fluorosis-associated periostitis. It is crucial to monitor
drug levels because (1) voriconazole is metabolized in the liver by
CYP2C9, CYP3A4, and CYP2C19; and (2) human genetic variation
in CYP2C19 activity exists and can lead to significant interpatient
variability in drug levels. Dosages should be reduced in patients with
hepatic, but not renal, failure; however, because the IV formulation is
prepared in cyclodextrin, it should be given with caution to patients
with severe renal failure.
Posaconazole Posaconazole has broader activity than voriconazole, including activity against Mucorales. Both oral (suspension,
tablet) and IV formulations are available. Posaconazole is approved by
the FDA for antifungal prophylaxis in neutropenic leukemic patients
and allogeneic hematopoietic stem cell transplant recipients as well as
for treatment of oropharyngeal candidiasis, including infections refractory to fluconazole or itraconazole. Posaconazole has been reported to
be effective salvage therapy for aspergillosis, mucormycosis, fusariosis,
cryptococcosis, histoplasmosis, and coccidioidomycosis, although
controlled clinical trials are lacking. The tablet formulation is not hampered by the suboptimal absorption that occurs with the suspension;
the tablet also results in higher and more reliable blood levels of the
drug. Posaconazole is less hepatotoxic than voriconazole and does not
cause the skin, visual, or bone toxicity that occurs with voriconazole.
However, the use of posaconazole is linked to significant P450-related
drug interactions.
Isavuconazole The newest azole, isavuconazole, is available in oral
and IV formulations and has broad antifungal activity similar to that of
posaconazole. Isavuconazole is approved by the FDA for treatment of
aspergillosis (on the basis of a randomized controlled trial that found
it noninferior to voriconazole) and mucormycosis (on the basis of an
open-label, noncomparative trial of 37 patients). Future experience
will definitively determine its place in the antifungal armamentarium.
Isavuconazole appears to be less hepatotoxic than voriconazole; it does
not cause skin or visual toxicity, and it causes fewer P450-associated
drug interactions than voriconazole.
■ ECHINOCANDINS
The echinocandins include the FDA-approved drugs caspofungin,
anidulafungin, and micafungin, which are available solely as an IV
formulation and inhibit β-1,3-glucan synthase, an enzyme that is
crucial for fungal cell-wall synthesis but is not a constituent of human
cells. The three echinocandins have comparable efficacy, toxicity, and
tissue penetration profiles; are fungicidal for Candida and fungistatic
for Aspergillus; and have no activity against other molds, Cryptococcus, or endemic dimorphic fungi. Their most common use to date
is in candidal infections. These drugs offer three major advantages:
minimal toxicity, minimal drug interactions, and activity against all
Candida species. The minimal inhibitory concentrations (MICs) of
echinocandins are higher against Candida parapsilosis than against
other Candida species, but the higher MICs do not translate into less
clinical efficacy against this species.
In controlled trials, caspofungin was as efficacious as AmB against
candidemia and invasive candidiasis and as efficacious as fluconazole
against candidal esophagitis. Caspofungin has also been efficacious
as salvage therapy for aspergillosis. Anidulafungin is approved by the
FDA as therapy for candidemia in nonneutropenic patients and for
Candida esophagitis, abdominal infection, and peritonitis. In controlled trials, anidulafungin was noninferior and possibly superior to
fluconazole against candidemia and invasive candidiasis and was as
efficacious as fluconazole against candidal esophagitis. Micafungin is
approved by the FDA for the treatment of candidal esophagitis and
candidemia and for antifungal prophylaxis in hematopoietic stem
cell transplantation. Moreover, micafungin yielded favorable results
when used for the treatment of invasive aspergillosis and candidiasis
in open-label trials.
■ FLUCYTOSINE (5-FLUOROCYTOSINE)
Flucytosine use has diminished as newer antifungal drugs have been
developed. Its mechanism of action involves intrafungal conversion
to 5-fluorouracil, which inhibits fungal DNA synthesis. The use of
flucytosine in combination with AmB as induction therapy for cryptococcal meningitis is based on the drugs’ synergistic interaction and
favorable flucytosine CSF penetration that promotes a rapid decline
of the cryptococcal burden in the CSF. Flucytosine is also used in
combination with AmB for the treatment of candidal meningitis and
endocarditis, although comparative trials with AmB monotherapy are
lacking. Flucytosine monotherapy is not recommended as it is associated with the development of resistance. Flucytosine can cause bone
marrow suppression and liver toxicity, which are intensified when the
drug is used with AmB.
■ GRISEOFULVIN AND TERBINAFINE
Historically, griseofulvin was used for ringworm infection. Terbinafine,
which inhibits squalene epoxidase and ergosterol synthesis, is now
used for onychomycosis and ringworm infection and is as effective as
itraconazole and more effective than griseofulvin in both conditions.
Although active against other fungi, terbinafine penetrates poorly into
tissues beyond the skin and nails and therefore is not preferred for systemic mycoses. Terbinafine carries a risk for hepatotoxicity.
■ TOPICAL ANTIFUNGAL AGENTS
A detailed discussion of topical agents for mucocutaneous mycoses is
beyond the scope of this chapter; the reader is referred to Chap. 219
and the dermatology literature. Azoles such as clotrimazole, miconazole, and ketoconazole are often used topically to treat common
cutaneous mycoses as well as oropharyngeal and vaginal candidiasis.
In vaginal candidiasis, oral fluconazole given once has the advantage of
not requiring repeated intravaginal application. The polyenes nystatin
and AmB have also been used topically for oropharyngeal and vaginal
candidiasis. Agents from other classes that are used to treat these conditions include ciclopirox, haloprogin, terbinafine, naftifine, tolnaftate,
and undecylenic acid.
■ FURTHER READING
Bennett JE: Introduction to mycoses, in Mandell, Douglas, and Bennett’s
Principles and Practice of Infectious Diseases, 9th ed, JE Bennett et al
(eds). Philadelphia, Elsevier Saunders, 2020, pp 3082–3086.
Lionakis MS, Levitz SM: Host control of fungal infections: Lessons
from basic studies and human cohorts. Annu Rev Immunol 36:157,
2018.
Pappas PG et al: Clinical mycology today: A synopsis of the mycoses
study group education and research consortium (MSGERC) second
biennial meeting, September 27–30, 2018, Big Sky, Montana, a proposed global research agenda. Med Mycol 58:569, 2020.
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