1272 PART 5 Infectious Diseases
P. mirabilis causes 90% of Proteus infections, which occur in the
community, LTCFs, and hospitals. By contrast, Proteus vulgaris and
Proteus penneri are associated primarily with infections acquired in
LTCFs or hospitals. Correspondingly, P. mirabilis colonizes healthy
humans (prevalence, 50%), whereas P. vulgaris and P. penneri are isolated primarily from individuals with underlying disease. By far the
most common site of Proteus infection is the urinary tract, where the
principal known urovirulence factors of Proteus include adhesins, flagella, IgA-IgG protease, iron acquisition systems, and urease. Proteus less
commonly causes infection at a variety of other extraintestinal sites.
■ INFECTIOUS SYNDROMES
UTI P. mirabilis causes only 1–2% of UTIs in healthy women, and
Proteus species collectively cause only 5% of hospital-acquired UTIs.
However, Proteus is responsible for 10–15% of cases of complicated
UTI, primarily those associated with catheterization; indeed, Proteus
accounts for 20–45% of urine isolates from chronically catheterized
patients. This high prevalence is due in part to bacterial production of
urease, which hydrolyzes urea to ammonia and results in alkalization of
the urine. In alkaline urine, organic and inorganic compounds precipitate, contributing to the formation of struvite and carbonate–apatite
crystals, biofilms on catheters, and/or frank calculi. Proteus becomes
associated with the stones and biofilms; thereafter, it usually cannot
be eradicated without removal of the stones or catheter. Over time,
staghorn calculi may form within the renal pelvis and lead to obstruction and renal failure. Although biologically plausible, clinical support
is lacking for the concept that urine samples exhibiting unexplained
alkalinity should be cultured, and that isolation of a Proteus species
(or other urea-splitting organism) should prompt consideration of an
evaluation for urolithiasis.
Other Infections Proteus occasionally causes pneumonia (primarily in LTCF residents or hospitalized patients), nosocomial sinusitis,
intraabdominal abscesses, biliary tract infection, surgical site infection, soft tissue infection (especially decubitus and diabetic ulcers),
and osteomyelitis (primarily contiguous); in rare cases, it causes nontropical myositis. In addition, Proteus uncommonly causes neonatal
meningitis, with the umbilicus frequently implicated as the source;
this disease is often complicated by development of a cerebral abscess.
Otogenic brain abscess also occurs.
Bacteremia Most episodes of Proteus bacteremia originate from
the urinary tract, although intravascular devices and any of the less
common sites of Proteus infection are also potential sources. Endovascular infection is rare. Proteus species are occasional agents of sepsis in
neonates and of bacteremia in neutropenic patients.
■ DIAGNOSIS
Proteus is readily isolated and identified in the laboratory. Most
strains are lactose-negative, produce H2
S, and demonstrate characteristic swarming motility on agar plates. P. mirabilis and P. penneri are
indole-negative, whereas P. vulgaris is indole-positive. The inability
to produce ornithine decarboxylase differentiates P. penneri from P.
mirabilis.
TREATMENT
Proteus Infections
Intrinsic resistance occurs in all Proteus spp. to nitrofurantoin,
polymyxins, imipenem, and the tetracycline derivatives (e.g.,
tigecycline, eravacycline, omadacycline) and, in P. vulgaris and
P. penneri, also to ampicillin and the first- and second-generation
cephalosporins. Acquired resistance (% of isolates) occurs in
P. mirabilis to ampicillin (15–65%), and in Proteus spp. to fluoroquinolones (10–55%), fosfomycin (7–22%), and TMP-SMX
(20–50%). In P. mirabilis, ampicillin-sulbactam is more active than
ampicillin, with resistance prevalences of 6–18%, but the prevalence of ESBL production (which confers ampicillin-sulbactam
resistance) is increasing in the United States (5–10%) and Asia (up
to 60%). Isolates of P. mirabilis that produce CTX-M ESBLs have
been recovered from ambulatory patients with no recent health
care contact (see the section on the treatment of extraintestinal
E. coli infections for treatment considerations). The use of thirdgeneration cephalosporins can induce or select for stable de-repression
of AmpC β-lactamase in P. vulgaris. Acquired carbapenem resistance remains relatively infrequent (<10%). However, production
of a class B metallo-β-lactamase (e.g., NDM) limits treatment
options due to the inherent resistance of Proteus spp. to polymyxins and tetracycline derivatives (see “Carbapenemase” above). For
critically ill patients, agents with excellent activity overall against
Proteus spp. (90–100% of isolates susceptible) include carbapenems
(excepting imipenem), amikacin, piperacillin-tazobactam, aztreonam, cefepime, ceftazidime-avibactam, ceftolozane-tazobactam,
and meropenem-vaborbactam.
ENTEROBACTER AND CRONOBACTER
INFECTIONS
The E. cloacae complex is responsible for most Enterobacter infections,
whereas Cronobacter sakazakii (formerly Enterobacter sakazakii),
Cronobacter malonaticus, Enterobacter cancergenus, and Enterobacter
gergoviae are less commonly isolated (<1% for each). Enterobacter
bugandensis has been recently described as an agent of sepsis in neonates and was isolated from the International Space Station. Enterobacter spp. cause primarily health care–related infections. The organisms
are widely prevalent in foods, environmental sources (including equipment at health care facilities), and a variety of animals.
Colonization with these organisms is uncommon among healthy
humans, but increases significantly with LTCF residence or hospitalization. Although colonization is an important prelude to infection, direct
introduction via IV lines (e.g., contaminated IV fluids or pressure
monitors) or contaminated non-FDA-approved stem cell products also
occurs. Extensive antibiotic resistance has developed in Enterobacter
spp. and probably has contributed to these organisms’ emergence as
prominent nosocomial pathogens. Risk factors for Enterobacter infection include prior antibiotic treatment, comorbid disease, and ICU residency. Enterobacter spp. causes a spectrum of extraintestinal infections
similar to those described for other GNB.
■ INFECTIOUS SYNDROMES
The most commonly encountered syndromes include pneumonia,
UTI (particularly catheter-associated), intravascular device–related
infection, surgical site infection, and abdominal infection (primarily
postoperative or related to devices such as biliary stents). Nosocomial
sinusitis, meningitis related to neurosurgical procedures (including
use of intracranial pressure monitors), osteomyelitis, and endophthalmitis after eye surgery are less frequent. Neonates (particularly
if low-birth-weight) are at risk for C. sakazakii infection, including
neonatal bacteremia, necrotizing enterocolitis, and meningitis (which
is often complicated by brain abscess or ventriculitis). Contaminated
powdered infant formula has been implicated as a source for such
neonatal infections. The WHO recommends that, to reduce the initial
number of bacteria, powdered infant formula should be reconstituted
with hot water (>70°C) and, to limit replication of residual bacteria,
the reconstituted formula should be stored at <5°C or its storage time
minimized.
Enterobacter bacteremia can result from primary infection at any
anatomic site. In bacteremia of unclear origin, particularly in an outbreak setting, sources for consideration should include contaminated
IV fluids or medications, blood components or plasma derivatives,
catheter-flushing fluids, pressure monitors, and dialysis equipment.
Enterobacter can also cause bacteremia in neutropenic patients.
Enterobacter endocarditis is rare, occurring primarily in association
with illicit IV drug use or prosthetic valves.
■ DIAGNOSIS
Enterobacter is readily isolated and identified in the laboratory. Most
strains are lactose-positive and indole-negative.
1273CHAPTER 161 Diseases Caused by Gram-Negative Enteric Bacilli
TREATMENT
Enterobacter Infections
E. cloacae is intrinsically resistant to ampicillin, ampicillin-sulbactam,
ampicillin-clavulanate, the first-generation cephalosporins, and the
cephamycins. The prevalence of acquired resistance has ranged
from 15 to 40% for piperacillin-tazobactam, 5 to 23% for polymyxin
E, 15 to 17% for fosfomycin, 15 to 30% for TMP-SMX, and 5 to
20% for fluoroquinolones and is ~10% for omadacycline (53% if
tetracycline resistant). USNHSN data from 2015−2017 identified
8.9% of E. cloacae isolates as presumptively ESBL-producing, based
on cefepime resistance. The prevalence of ESBLs in E. cloacae outside of the United States is 20−50%. The use of third-generation
cephalosporins can induce or select for stable de-repression of
AmpC β-lactamase. Because resistance may emerge during therapy
(in one study, this phenomenon was documented in 20% of clinical
isolates), these agents should be avoided in the treatment of serious
Enterobacter infection.
Cefepime is stable in the presence of AmpC β-lactamases; thus,
it is a suitable option for treatment of Enterobacter infections so
long as no coexistent ESBL is present. Overall, resistance prevalence
generally ranges from 10 to 25% for cefepime and 25 to 50% for
aztreonam and the third-generation cephalosporins. Carbapenem
resistance remains relatively uncommon (USNHSN data from
2015−2017 identified a 5% prevalence) and is more commonly
associated with increased AmpC expression and decreased permeability due to porin mutations rather than carbapenemase production, although acquisition of carbapenemase genes is increasing
(see “Carbapenemase” above). Uncertainty exists on the optimal
treatment for non-CP-CR-Enterobacter spp. Fortunately, overall, the
percentage of susceptibility is high (90–99%) for carbapenems, amikacin, plazomicin, ceftazidime-avibactam, meropenem-vaborbactam,
imipenem/cilastatin-relebactam, cefiderocol, tigecycline, eravacycline, and omadacycline (the latter three for tetracycline-susceptible
isolates). Once susceptibility data for a patient’s isolate become
available, de-escalation of the antimicrobial regimen is advisable
whenever possible.
SERRATIA INFECTIONS
S. marcescens causes >90%, and Serratia liquefaciens complex <10%, of
Serratia infections. Serratiae are found primarily in the environment
(including in health care institutions), particularly in moist settings.
Serratiae have been isolated from a variety of animals, insects, and
plants, but only infrequently from healthy humans. In LTCFs and
hospitals, reservoirs for the organisms include the hands and fingernails of health care personnel, food, milk (on neonatal units), sinks,
medical equipment or devices, IV solutions or parenteral medications
(particularly those generated by compounding pharmacies), prefilled
syringes and multiple-access medication vials (e.g., for heparin, propofol, saline), blood products (e.g., platelets), hand soaps and lotions,
irrigation solutions, and even disinfectants such as chlorhexidine.
Infection results from either direct inoculation (e.g., via contaminated injected substances [IV fluids, medications, or recreational
drugs] or snake bite) or colonization (primarily of the respiratory
tract). Sporadic infection is most common, but outbreaks (often
involving MDR strains in adult and neonatal ICUs) also occur.
Hygiene, medication-compounding standards, sterile technique, and
infection control programs are critical measures to prevent infection.
The spectrum of extraintestinal infections caused by Serratia is
similar to that for other GNB. Serratia species are usually considered to
cause mainly health care–associated infections; they account for 1–3%
of hospital-acquired infections. However, population-based laboratory
surveillance studies in Canada and Australia have demonstrated that
community-acquired Serratia infections occur more commonly than
was previously appreciated, and case reports have documented serious
infection in otherwise healthy hosts. Serratia also is one of the pathogens associated with chronic granulomatous disease.
■ INFECTIOUS SYNDROMES
The most common primary sites of Serratia infection are the respiratory and genitourinary tracts, intravascular devices, the eye (contact
lens–associated keratitis and other ocular infections), surgical wounds,
and the bloodstream (from contaminated infusions), although most
episodes of Serratia bacteremia arise from one of the listed focal infections rather than contaminated infusate. Less common syndromes are
soft tissue infections (including myositis, fasciitis, mastitis), osteomyelitis, abdominal and biliary tract infections (usually postprocedural),
and septic arthritis (primarily from intraarticular injections). Serratiae
are uncommon causes of neonatal meningitis; postsurgical meningitis,
endophthalmitis, or breast implant infection; and bacteremia in neutropenic patients. Endocarditis is rare, occurring most commonly in
IV drug users.
■ DIAGNOSIS
Serratiae are readily cultured and identified by the laboratory and are
usually lactose- and indole-negative. The red pigmentation of some S.
marcescens strains and Serratia rubidaea can produce distinctive clinical findings (e.g., pink breast milk or hypopyon; pseudohemoptysis).
TREATMENT
Serratia Infections
Most Serratia strains (>80%) are intrinsically resistant to ampicillin, amoxicillin-clavulanate, ampicillin-sulbactam, first- and secondgeneration cephalosporins, cephamycins, nitrofurantoin, and
polymyxins; likewise, tetracycline derivatives are poorly active.
By contrast, fluoroquinolones, TMP-SMX, piperacillin-tazobactam,
fosfomycin, and omadacycline are active against 85−95% of
U.S. and European isolates, including those resistant to tetracycline. Both in the United States and globally, the prevalence of
ESBL-producing isolates is generally low (<10%), but rates of
20–30% have been reported in Asia and Latin America. The use
of third-generation cephalosporins may result in the induction
or selection of variants with stable de-repression of chromosomal
AmpC β-lactamases during therapy but is uncommon. Resistance
prevalence generally ranges from 10 to 20% for aztreonam and
the third-generation cephalosporins. Acquisition of carbapenemaseencoding genes is uncommon but increasing. Production of a
class B metallo-β-lactamase (e.g., NDM) limits treatment options
due to Serratia’s predictable resistance to polymyxins and tetracycline derivatives (see “Carbapenemase” above). For critically
ill patients, the most active agents overall (>90% susceptible)
are carbapenems, piperacillin-tazobactam, cefepime, amikacin,
plazomicin, ceftazidime-avibactam, ceftolozane-tazobactam, and
meropenem-vaborbactam.
CITROBACTER INFECTIONS
C. freundii and Citrobacter koseri cause most human Citrobacter infections, which are epidemiologically and clinically similar to Enterobacter
infections. Citrobacter species are commonly present in water, food,
soil, and certain animals. Colonization with these organisms is uncommon among healthy humans, but increases significantly with LTCF
residence or hospitalization. Citrobacter species account for 1–2% of
nosocomial infections. The affected hosts are usually immunocompromised and/or have comorbid disease or disruption of skin or mucosal
barriers. Infection from treatment with contaminated, non-FDAapproved stem cell products has been described. Citrobacter causes
extraintestinal infections similar to those described for other GNB.
■ INFECTIOUS SYNDROMES
The urinary tract accounts for 40–50% of Citrobacter infections. Less
commonly involved sites include the biliary tree (particularly with
stones or obstruction), the respiratory tract, surgical sites, soft tissue
(e.g., decubitus ulcers), the peritoneum, and intravascular devices.
Osteomyelitis (usually from a contiguous focus), central nervous system infection in adults (from neurosurgical or other types of meningeal
1274 PART 5 Infectious Diseases
disruption), and myositis occur rarely. Citrobacter (primarily C. koseri)
also causes 1–2% of neonatal meningitis cases, of which 50–80% are
complicated by brain abscess. Further, case reports in adults suggest
that C. koseri infection has a predilection for abscess formation. Citrobacter bacteremia is most often due to UTI, biliary/abdominal infection, or intravascular device infection, and occurs in some neutropenic
patients. Endocarditis and other endovascular infections are rare.
■ DIAGNOSIS
Citrobacter species are readily isolated and identified; 35–50% of isolates are lactose-positive, and 100% are oxidase-negative. C. freundii is
indole-negative, whereas C. koseri is indole-positive.
TREATMENT
Citrobacter Infections
C. freundii is more extensively antibiotic-resistant than is C. koseri.
Most C. freundii isolates are intrinsically resistant to ampicillin, ampicillin-sulbactam, amoxicillin-clavulanate, first-generation
cephalosporins, and cephamycins. C. koseri exhibits intrinsic resistance to ampicillin and ampicillin-sulbactam. Overall, the prevalence of acquired resistance generally ranges from 15 to 35% for
third-generation cephalosporins, piperacillin-tazobactam, fluoroquinolones, and TMP-SMX and is ~10% for nitrofurantoin and
omadacycline (but 39% for omadacycline if tetracycline-resistant).
The prevalence of ESBL production ranges from 5 to 30%. The use
of third-generation cephalosporins may result in the induction
or selection of variants with stable de-repression of chromosomal
AmpC β-lactamases during therapy. Presently, <10% of isolates have
acquired carbapenemases (see “Carbapenemase” above). Carbapenems, amikacin, plazomicin, fosfomycin, polymyxins, cefepime,
ceftazidime-avibactam, cefiderocol, tigecycline, eravacycline, and
omadacycline (the latter three if tetracycline-susceptible) are the
most active agents against Citrobacter isolates (>90% susceptible).
MORGANELLA AND PROVIDENCIA
INFECTIONS
M. morganii, Providencia stuartii, and (less frequently) Providencia
rettgeri are the members of their respective genera that cause systemic
human infections. P. alcalifaciens has been implicated as a cause of
food-borne gastroenteritis. These organisms’ epidemiologic associations, pathogenic properties, and clinical manifestations resemble
those of Proteus species. Morganella and Providencia occur more
commonly among LTCF residents than among hospitalized patients,
largely resulting from chronic urinary catheter use. Because of these
organisms’ intrinsic resistance to polymyxins and tigecycline, they may
become increasingly common in settings with extensive use of these
agents.
■ INFECTIOUS SYNDROMES
These species are primarily urinary tract pathogens, causing UTIs that
are most often associated with long-term (>30-day) catheterization.
Such infections commonly lead to biofilm formation and catheter
encrustation (sometimes causing catheter obstruction) or the development of struvite bladder or renal stones (sometimes causing renal
obstruction, abscess, and extrarenal extension, and serving as foci for
relapse). They can cause purple urine (“purple bag syndrome”), as can
P. mirabilis, K. pneumoniae, E. coli, and P. aeruginosa. Morganella is also
commonly isolated from snakebite infection.
Other, less common infectious syndromes due to Morganella and
Providencia include surgical site infection, soft tissue infection (primarily involving decubitus and diabetic ulcers), burn site infection,
pneumonia (particularly ventilator-associated), intravascular device
infection, and intraabdominal infection. Rarely, the other extraintestinal infections described for GNB also occur. Bacteremia is uncommon;
when it does occur, any infected site can serve as the source, but the
urinary tract accounts for most cases, followed by surgical site, soft
tissue, and hepatobiliary infections.
■ DIAGNOSIS
M. morganii and Providencia are readily isolated and identified. Nearly
all isolates are lactose-negative and indole-positive.
TREATMENT
Morganella and Providencia Infections
Morganella and Providencia are intrinsically resistant to ampicillin, ampicillin-clavulanate, ampicillin-sulbactam, first-generation
cephalosporins, nitrofurantoin, tetracyclines and derivatives (e.g.,
tigecycline), imipenem (but not the other carbapenems), and the
polymyxins. P. stuartii additionally exhibits intrinsic resistance to
gentamicin and tobramycin, as does M. morganii to second-generation
cephalosporins. Fosfomycin is poorly active (>50% resistance). The
prevalence of resistance generally ranges from 10 to 30% for the
third-generation cephalosporins, from 10 to 40% for fluoroquinolones, and from 20 to 40% for TMP-SMX; the prevalence is more
widely variable for piperacillin-tazobactam. The prevalence of ESBL
production is generally <10%. The use of third-generation cephalosporins can induce or select for stable de-repression of AmpC
β-lactamase for both Morganella and Providencia. The prevalence
of acquired carbapenemase production is <10%. Production of a
class B metallo-β-lactamase (e.g., NDM) limits treatment options
due to the inherent resistance of the Proteeae to polymyxins and
tetracycline derivatives (see “Carbapenemase” above). Overall, the
most active agents (>90% of isolates susceptible) are carbapenems
(excepting imipenem), amikacin, cefepime, ceftazidime-avibactam,
ceftolozane-tazobactam, meropenem-vaborbactam, and cefiderocol. Removal of a colonized urinary catheter or stone is critical for
eradication of UTI.
EDWARDSIELLA INFECTIONS
E. tarda is the only member of the genus Edwardsiella that is associated
with human disease. This organism is found predominantly in freshwater and marine environments and in the associated aquatic animal species. Human acquisition occurs primarily from interaction with these
reservoirs or ingestion of raw or inadequately cooked aquatic animals.
E. tarda infection is rare in the United States, where acquisition occurs
mainly along the Gulf of Mexico; recently reported cases are mostly
from Asia. This pathogen shares clinical features with Salmonella
species (as an intestinal pathogen; Chap. 165), Vibrio vulnificus (as an
extraintestinal pathogen; Chap. 168), and Aeromonas hydrophila (as
both an intestinal and an extraintestinal pathogen; Chap. 158).
■ INFECTIOUS SYNDROMES
Gastroenteritis is the predominant Edwardsiella-associated infectious
syndrome (50–80% of reported cases). Self-limiting watery diarrhea
is most common, but severe colitis also occurs. The most common
extraintestinal infection is wound infection due to direct inoculation, which is often associated with brackish or freshwater injuries,
snakebites, or fish-related trauma. A case of pneumonia occurred
after a near-drowning incident. Cholecystitis, cholangitis, and hepatic
abscess may be due to ascending infection via the biliary tree. Other
infectious syndromes result from invasion of the gastrointestinal
tract and subsequent bacteremia. A primary bacteremic syndrome,
sometimes complicated by meningitis, has a 40% case–fatality rate;
hematogenous seeding may result in hepatic and intra- and extraperitoneal abscesses, endocarditis, mycotic aneurysm, septic arthritis,
osteomyelitis, necrotizing fasciitis, and empyema. Most hosts who
develop systemic Edwardsiella infection have significant comorbidities
(e.g., hepatobiliary disease, iron overload, cancer, or diabetes mellitus).
■ DIAGNOSIS
Although E. tarda can readily be isolated and identified, most laboratories do not routinely screen for or identify it in stool samples. Production of hydrogen sulfide is a characteristic biochemical property.
1275CHAPTER 162 Acinetobacter Infections
TREATMENT
Edwardsiella Infections
E. tarda is susceptible to most antimicrobial agents appropriate for use
against GNB. Gastroenteritis is generally self-limiting, but treatment with a fluoroquinolone may hasten resolution. In the setting
of severe sepsis, fluoroquinolones, third- and fourth-generation
cephalosporins, carbapenems, and amikacin—either alone or in
combination—are the safest choices pending susceptibility data.
INFECTIONS CAUSED BY MISCELLANEOUS
GENERA
Other gram-negative organisms such as Hafnia, Kluyvera, Cedecea,
Pantoea, Ewingella, Leclercia, Raoultella, and Photorhabdus spp. are
occasionally isolated from diverse clinical specimens, including blood,
sputum, urine, cerebrospinal fluid, joint fluid, bile, and wounds. Such
organisms cause infection predominantly in compromised hosts or
in association with an invasive procedure or foreign body. Cephalosporinases from Kluyvera have been implicated as the progenitors of
CTX-M ESBLs. Kluyvera and Raoultella may produce carbapenemases.
■ FURTHER READING
Anesi JA et al: Poor clinical outcomes associated with communityonset urinary tract infections due to extended-spectrum cephalosporin-resistant Enterobacteriaceae. Infect Control Hosp Epidemiol
39:1431, 2018.
Baker TM et al: Epidemiology of bloodstream infections caused by
Escherichia coli and Klebsiella pneumoniae that are piperacillintazobactam-nonsusceptible but ceftriaxone-susceptible. Open Forum
Infect Dis 5:ofy300, 2018.
Boisen N et al: Shiga toxin 2a and enteroaggregative Escherichia
coli—A deadly combination. Gut Microbes 6:272, 2015.
Bonten M et al: Epidemiology of Escherichia coli bacteremia: A systematic literature review. Clin Infect Dis 72:1211, 2021.
Cheng MP et al: Beta-lactam/beta-lactamase inhibitor therapy for
potential AmpC-producing organisms: A systematic review and
meta-analysis. Open Forum Infect Dis 6:ofz248, 2019.
David S et al: Epidemic of carbapenem-resistant Klebsiella pneumoniae
in Europe is driven by nosocomial spread. Nat Microbiol 4:1919,
2019.
Gurieva T et al: The transmissibility of antibiotic-resistant Enterobacteriaceae in intensive care units. Clin Infect Dis 66:489, 2018.
Harris PNA et al: Effect of piperacillin-tazobactam vs meropenem
on 30-day mortality for patients with E coli or Klebsiella pneumoniae
bloodstream infection and ceftriaxone resistance: A randomized
clinical trial [published correction appears in JAMA 321:2370, 2019].
JAMA 320:984, 2018.
Holy O, Forsythe S: Cronobacter spp. as emerging causes of healthcareassociated infection. J Hosp Infect 86:169, 2014.
Kamiyama S et al: Edwardsiella tarda bacteremia, Okayama, Japan,
2005-2016. Emerg Infect Dis 25:1817, 2019.
Lim C et al: Epidemiology and burden of multidrug-resistant bacterial
infection in a developing country. Elife 5:E18082, 2016.
Nordmann P et al: Carbapenem resistance in Enterobacteriaceae:
Here is the storm! Trends Mol Med 18:263, 2012.
Peirano G, Pitout JDD: Extended-spectrum β-lactamase-producing
Enterobacteriaceae: Update on molecular epidemiology and treatment options. Drugs 79:1529, 2019.
Russo TA, Marr CM: Hypervirulent Klebsiella pneumoniae. Clin
Microbiol Rev 32:e00001, 2019.
van Duin D et al: Molecular and clinical epidemiology of carbapenemresistant Enterobacterales in the USA (CRACKLE-2): A prospective
cohort study Lancet Infect Dis 20:731, 2020. [Erratum in Lancet
Infect Dis 19:30755, 2020].
Weiner-Lastinger LM et al: Antimicrobial-resistant pathogens associated with adult healthcare-associated infections: Summary of data
reported to the National Healthcare Safety Network, 2015-2017.
Infect Control Hosp Epidemiol 41:1, 2020.
■ DEFINITION
Acinetobacter species were first described in 1911 and named Micrococcus calcoaceticus. Thereafter, the genus was renamed multiple
times; since 1950, it has been known as Acinetobacter. Acinetobacter
species are gram-negative, oxidase-negative, nonmotile, nonfermenting coccobacilli that are easily recovered on standard culture media.
Differentiation among Acinetobacter species on the basis of phenotypic
characteristics alone is very difficult. Molecular-based methods such as
matrix-assisted laser desorption–ionization–time-of-flight mass spectrometry (MALDI-TOF-MS) and quantitative real-time polymerase
chain reaction (PCR) are usually necessary to identify Acinetobacter
baumannii, the most clinically relevant species of the genus.
■ ETIOLOGY AND EPIDEMIOLOGY
Acinetobacter species are naturally encountered in water and soil
and have also been recovered from fruits and vegetables. In humans,
Acinetobacter can be found on the skin and in the respiratory and
gastrointestinal tracts. A. baumannii is capable of surviving environmental desiccation for weeks; this characteristic is important from an
infection-control perspective as it allows this organism to persist in the
hospital environment and on equipment.
Acinetobacter was historically considered a pathogen of hot and
humid climates. In recent years, however, hospital outbreaks caused
by A. baumannii have been reported worldwide, even in temperate
climates. In the United States, the Centers for Disease Control and
Prevention (CDC) estimates that 12,000 Acinetobacter infections occur
every year, 7300 of which are caused by multidrug-resistant strains,
with 500 attributable deaths. The increase in the number of infections
with A. baumannii is suspected to be due to the rapid spread of certain
genetically distinct lineages; of the three international clonal lineages
(ICLs), ICL I and ICL II are multidrug resistant. The predominance of
these lineages remains unexplained, although it has been proposed that
this population structure is the result of two waves of expansion. The
first wave followed a bottleneck (possibly linked to a restricted ecologic
niche) that occurred in the distant past. The second wave is ongoing
and is being driven by the rapid expansion of a limited number of
multidrug-resistant clones.
Analysis of the A. baumannii pangenome (the sum of the core and
dispensable genomes) has shown that its organization is characterized by a small core genome and a large accessory or disposable
genome. This organization reflects A. baumannii’s high plasticity,
which enables it to acquire exogenous genetic material. With few
exceptions, gene functions associated with virulence are found in the
core genome; this observation suggests a limited role for the acquisition of new virulence traits in the recent nosocomial expansion of A.
baumannii clones. Genes associated with resistance to antimicrobial
agents are found in both the species core genome and the accessory
genome. In the accessory genome, these genes have been found in alien
islands, often flanked by integrases, transposases, or insertion
sequences. This pattern suggests possible acquisition by horizontal
gene transfer from other Acinetobacter strains or even from different
bacterial species present in the immediate environment. Acquisition of
these antimicrobial resistance genes is hypothesized to have led to the
recent rapid expansion of highly homogeneous clonal lineages, whose
main difference from nonclonal A. baumannii appears to be their antimicrobial resistance.
Health Care–Associated Infections Infections caused by A.
baumannii occur frequently among patients admitted to intensive
care units (ICUs). Risk factors for colonization and infection with
this pathogen include nursing home residence, prolonged ICU stay,
central venous catheterization, tracheostomy, mechanical ventilation,
enteral feedings, and treatment with third-generation cephalosporins,
162 Acinetobacter Infections
Rossana Rosa, L. Silvia Munoz-Price
1276 PART 5 Infectious Diseases
fluoroquinolones, and carbapenems. Acquisition of carbapenemresistant A. baumannii is most common among patients exposed to
carbapenems. Spread of A. baumannii across different regions is facilitated by the movement of patients between health care systems and
throughout the continuum of health care. Within the hospital, environmental spread of A. baumannii occurs as a result of inappropriate
hand hygiene among workers providing health care for infected or
colonized patients and the contamination of hospital equipment, such
as respiratory therapy and ventilation equipment. The air surrounding
the patient may also play a role in environmental colonization with
A. baumannii, especially in inpatient areas without physical barriers
between patients and with an inadequate number of air exchanges.
A. baumannii strains identified during hospital outbreaks are typically resistant to more antibiotic classes than strains from the community. The prevalence of colonization with A. baumannii at the time of
admission or during a stay in a long-term acute-care hospital (LTACH)
or nursing home is variable and depends on regional flora. Outbreaks
of A. baumannii in acute-care hospitals and LTACHs that “share”
patients have been described in Ohio, Michigan, Illinois, and Indiana.
Community-Acquired Infections Community-acquired infections caused by Acinetobacter have been described in Australia and
Asia. Few cases have been reported in regions with a temperate climate,
and even those few cases have taken place during warm and humid
months. Risk factors for community-acquired pneumonia due to this
organism include a history of alcohol abuse, diabetes mellitus, smoking, and chronic lung disease.
War Zone–Associated Infections Infections caused by Acinetobacter in war zones include skin and soft tissue infections associated
with traumatic injuries and bloodstream infections. Outbreak investigations of A. baumannii infections among military personnel returning
from Iraq and Afghanistan suggested the acquisition of A. baumannii
in field hospitals rather than colonization of the skin before an injury.
This view is supported by the recovery of A. baumannii isolates with
similar genetic characteristics from inanimate surfaces in field hospitals and from patients.
Disaster Medicine A. baumannii is linked to infections among
victims of trauma during tsunamis, earthquakes, and terrorist attacks.
The types of infections most frequently observed in these settings are
soft tissue injuries, but bloodstream infections and pneumonia have
also been reported. In addition, outbreaks of A. baumannii infection in
ICUs caring for disaster victims have been described.
■ PATHOGENESIS
Mechanisms of pathogenesis and virulence in Acinetobacter species have
not been fully elucidated. However, A. baumannii seems to have greater
virulence potential than other Acinetobacter species, as evidenced by its
ability to grow at 37°C and to resist uptake by macrophages.
Initial A. baumannii colonization of the host and the environment
is facilitated by the organism’s ability to adhere to surfaces and human
cells and to create biofilms. The ability to form a biofilm is phenotypically associated with exopolysaccharide production and pilus formation. A quorum-sensing molecule encoded by the abaI autoinducer
synthase gene has been implicated in A. baumannii biofilm formation
on abiotic surfaces. Outer-membrane porins appear to mediate cell
apoptosis. A. baumannii can survive in harsh environments within
the host and on inanimate surfaces by modifying the structure of its
lipid A, with a consequent decrease in susceptibility to antibiotics and
antimicrobial peptides and an increase in survival upon desiccation.
Acinetobacter species produce an extracellular capsule that protects
the bacteria from external threats, including complement-mediated
killing. Studies of mouse models showed that Acinetobacter species can
increase capsule production in the presence of subinhibitory levels of
antibiotic—an ability that leads to increased resistance to complementmediated killing and a hypervirulent phenotype.
Phospholipase C and phospholipase D have been identified as virulence factors in A. baumannii. These enzymes exert cytotoxic effects on
epithelial cells and facilitate their invasion.
Iron-acquisition systems are also important virulence mechanisms in
A. baumannii. Through secretion of siderophores (low-molecular-mass
ferric-binding compounds), A. baumannii is able to grow despite iron
deficiencies in the surrounding environment (e.g., in the human host).
Several protein-secretion systems have been identified in A. baumannii. The most recently described is a type II secretion system. The
substrate for this system, the LipA lipase, is required for growth on
medium containing lipids as a sole carbon source. Mutants lacking the
genes for the type II secretion system or its substrate exhibit defective
in vivo growth in a neutropenic murine model of bacteremia. A. baumannii also has a type VI secretion system whose primary function
seems to be to secrete antibacterial toxins that kill competing bacteria,
including other strains in the same species.
The type V autotransporter system has been characterized in A.
baumannii. In a murine systemic model of Acinetobacter infection, the
Acinetobacter trimeric autotransporter mediates biofilm formation and
maintenance; adherence to extracellular matrix components such as
collagen I, II, and IV; and virulence.
Outer-membrane vesicles (OMVs) play a special role in protein
secretion. Many A. baumannii strains secrete OMVs containing various virulence factors, including outer-membrane protein A (OmpA),
proteases, and phospholipases. The membrane proteins in OMVs are
responsible for eliciting a potent innate immune response. Several
studies have shown that A. baumannii OMVs could be used as an acellular vaccine to effectively control A. baumannii infections.
Nosocomial strains of Acinetobacter can deploy multiple mechanisms of resistance, including alterations in porins and efflux pumps
and expression of β-lactamases. More specifically, Acinetobacter species can reduce the expression of porins, thus hindering the passage
of β-lactam antibiotics into the periplasmic space. These species can
overexpress bacterial efflux pumps and decrease the concentration of
β-lactam antibiotics in the periplasmic space. Efflux pumps can also
actively remove quinolones, tetracyclines, chloramphenicol, disinfectants, and tigecycline. Acinetobacter species possess chromosomally
encoded cephalosporinases and are capable of acquiring β-lactamases,
including serine and metallo-β-lactamases. AmpC β-lactamases are
class C β-lactamases intrinsic to all A. baumannii strains. Although
these enzymes are expressed at low levels and are not inducible,
the addition of the insertion sequence ISAba1 next to the AmpC
gene increases β-lactamase production, with resulting resistance to
cephalosporins.
Carbapenem resistance in Acinetobacter species is mostly tied to
the emergence of Ambler class D oxacillinases of group 2d, some of
which are intrinsic and chromosomal (e.g., OXA-51-like) while others
are acquired and are found in plasmids or are chromosomally encoded
(e.g., OXA-23-like, 24 [33-like, 40-like], 58-like, 143-like, and 235-like).
■ CLINICAL MANIFESTATIONS
Pneumonia A. baumannii is a notorious cause of nosocomial pneumonia, most frequently among patients requiring prolonged mechanical ventilation. The onset of disease tends to be later than that caused
by other gram-negative bacilli; however, clinical symptoms of hospitalacquired or ventilator-associated pneumonia due to A. baumannii are
similar to those of nosocomial or ventilator-associated pneumonia due
to other nosocomial pathogens. Thus, the most common indicators of
infection include fever and increased sputum production. The positivity of respiratory cultures in most cases may present a challenge for the
clinician, since airway colonization with A. baumannii is a risk factor
for infection itself. Radiologic findings are nonspecific and can include
lobar consolidations and pleural effusions, but cavitations are rarely
seen. The crude mortality rates associated with nosocomial pneumonia
due to A. baumannii are reported to be as high as 65%. However, since
these infections occur in debilitated patients, their attributable mortality has been difficult to establish.
Community-acquired pneumonia due to A. baumannii is a relatively rare entity. Its clinical presentation is characterized by fever,
severe respiratory symptoms, and multiple-organ dysfunction. Patients
frequently have a cough productive of purulent sputum, shortness of
1277CHAPTER 162 Acinetobacter Infections
breath, and chest pain. Imaging studies usually show lobar consolidation. Mortality rates associated with this process are >50%.
Bloodstream Infections Bloodstream infections due to A. baumannii are most frequent among ICU patients and usually occur in the
presence of a central venous catheter or as a secondary complication of
hospital-acquired or ventilator-associated pneumonia. Polymicrobial
growth has been reported in 20–36% of bacteremia episodes. Fever
is the most common sign of infection (developing in >95% of cases),
and presentation with septic shock and disseminated intravascular
coagulopathy has been described in as many as 25 to 30% of patients,
respectively. A. baumannii bloodstream infections often result in
higher hospitalization costs and longer ICU stays. Crude mortality
rates from this infection are as high as 40%; however, rates can be as
high as 70% from infections caused by carbapenem-resistant isolates.
In patients with infections caused by extremely drug-resistant strains,
poor outcomes are thought to be driven by delays in the initiation of
adequate antimicrobial therapy.
Skin and Soft Tissue Infections Acinetobacter species have been
described as part of the skin flora, yet the majority of the organisms
from this genus that colonize the skin are not those associated with
nosocomial infections. Discerning infection from wound colonization is challenging. Gunshot wounds and the presence of orthopedic
external-fixation devices are common among patients with combat
trauma–associated A. baumannii skin and soft tissue infections. The
report on a case series of eight U.S. military patients described the
clinical presentation of their infections as evolving from an edematous
peau d’orange appearance to a sandpaper appearance with overlying
vesicles and then to a necrotizing process with hemorrhagic bullae.
Other case series have also included necrotizing fasciitis. A. baumannii
is an important pathogen in burn units worldwide. Large burns provide ideal conditions for A. baumannii and facilitate patient-to-patient
transmission. The presence of A. baumannii in wounds contributes to
healing delays and graft loss. In addition, wound colonization is a risk
factor for bloodstream infections among patients with extensive burn
injuries.
A. baumannii infections resulting from trauma to soft tissues in the
setting of natural disasters, such as tsunamis and earthquakes, have
been reported. The implication is that A. baumannii should be considered in the differential diagnosis of soft tissue infections following
exposure to tropical and subtropical environments.
Urinary Tract Infections A. baumannii is an infrequent cause of
urinary tract infections. The majority of cases reported are catheterassociated infections, reflecting the ability of A. baumannii to form
biofilms on these devices. A few reports have described communityacquired infections occurring in the setting of nephrolithiasis and after
renal transplantation.
Meningitis Central nervous system infections with A. baumannii
have been reported in the context of outbreaks, traumatic injuries,
neurosurgical procedures, and external ventricular drains. One case
series described a petechial rash in up to 30% of patients. Acinetobacter
species may look similar to Neisseria meningitidis on a Gram’s stain of
cerebrospinal fluid; both appear as gram-negative paired cocci.
Other Miscellaneous Infections A few cases of A. baumannii
keratitis associated with the use of contact lenses have been reported.
Cases of native- and prosthetic-valve endocarditis have also been
described.
TREATMENT
Acinetobacter Infections
Treatment of Acinetobacter infections is challenging because Acinetobacter can develop resistance to most available antibiotics. Therefore, the choice of empirical therapy should be based on local
epidemiology and the patient’s colonization status. Definitive therapy should be determined by antimicrobial susceptibility testing.
Antimicrobial options for the management of infections caused by
A. baumannii are displayed in Table 162-1.
Acinetobacter species possess intrinsic β-lactamases that inactivate first- and second-generation cephalosporins. Through acquisition of extended-spectrum β-lactamases, the organisms can also
become resistant to third- and fourth-generation cephalosporins.
Nevertheless, when the isolate is susceptible, β-lactam agents are
the drugs of choice for the treatment of A. baumannii. Among βlactamase inhibitors, sulbactam is active against A. baumannii
and is as effective as carbapenems and polymyxins. Cefiderocol
is a novel cephalosporine and is stable against many β-lactamase
classes, including extended-spectrum β-lactamases, AmpC, and
carbapenemases. Cefiderocol has shown in vitro activity against A.
baumannii isolates producing OXA-23, OXA-40, OXA-58, NDM,
and IMP. However, published clinical trials have not included
patients with infections caused by carbapenem-resistant strains.
Carbapenems have been the preferred drugs for treatment of
invasive or hospital-acquired infections. Unfortunately, surveillance
data from U.S. hospitals show that up to 50% of A. baumannii isolates recovered from ICUs are carbapenem resistant, and rates of
carbapenem resistance are even higher around the world.
Aminoglycosides are of limited utility against A. baumannii
because of toxicity and lack of lung penetration. Inhaled formulations of tobramycin have been used with variable success.
Polymyxins are cationic detergents that fell out of use as a result
of nephrotoxicity and neurotoxicity. In vitro, they are the most
active agents against carbapenem-resistant A. baumannii. Colistin has been used in both intravenous and inhaled formulations,
although the optimal dosage has not yet been determined. Combination therapy using colistin as a base has long been preferred but
randomized controlled trials have failed to show improved survival
compared to colistin monotherapy.
Tigecycline is a glycylcycline with clinical activity against A.
baumannii. It reaches only low serum concentrations and therefore
cannot be used for bloodstream infections. The susceptibility of
TABLE 162-1 Therapeutic Options for the Management of
Multidrug-Resistant Acinetobacter baumannii Infections
ANTIBIOTIC DOSINGa COMMENTS
Sulbactam 3–9 g/d (9–27 g/d if given
in combination with
ampicillin)
Unavailable as single drug in many
countries (including the United
States)
Meropenem 2 g q8h Prolonged infusion (3–4 h) has been
used; limited data
Imipenem 500 mg q6h Prolonged infusion (3–4 h) has been
used; limited data
Cefiderocol 2g q8h Prolonged infusion (3 h) used in
pharmacokinetic models
Colistin Loading dose of 5 mg/
kg followed by 2.5–5.0
mg/kg per day of colistin
base given in 2–4 divided
doses
Optimal dosing regimen unknown
Inhaled formulation has been used as
adjunct treatment in lung infections.
Polymyxin B 1.5–3 mg/kg q12h
Tigecycline 100-mg loading dose
followed by 50 mg q12h
Low serum concentrations and
bacteriostatic activity limit use in
bacteremia.
Minocycline 100 mg q12h Loading dose of 200 mg IV has been
used.
Eravacycline 1 mg/kg q12h
Amikacin 15 mg/kg qd Inhaled formulation of tobramycin
has been used as adjunct treatment
in lung infections.
Rifampin 600 mg qd or 600 mg q12h Use in combination therapy
Fosfomycin 4 g q12h PO Use in combination therapy
IV formulation not available in the
United States
a
All drugs are given by the IV route unless otherwise stated.
1278 PART 5 Infectious Diseases
isolates is variable, especially in outbreak settings, and the emergence of resistance during treatment has been reported.
Minocycline is a tetracycline that has a bacteriostatic effect
on A. baumannii. Synergistic and bactericidal activity has been
noted when minocycline is used in combination with colistin or a
carbapenem.
Eravacycline is a novel tetracycline with in vitro activity against
multidrug-resistant and extensively drug-resistant strains of
A. baumannii. However, only a small number of carbapenemresistant isolates have been included in clinical studies. Furthermore, eravacycline has been approved for the treatment of complicated intraabdominal infections but was shown to be inferior to
levofloxacin and ertapenem for the management of complicated
urinary tract infections.
Fosfomycin is an inhibitor of peptidoglycan synthesis that has
no direct activity against A. baumannii but has been observed to
be synergistic in vitro in combination with colistin or sulbactam.
Clinical data have shown higher rates of microbiologic cure, but no
differences in clinical response, with combinations of fosfomycin
and colistin.
In vitro data favor combination therapy with colistin in many
different regimens containing a carbapenem (imipenem, meropenem), rifampin, minocycline, ceftazidime, azithromycin, doxycycline, trimethoprim-sulfamethoxazole, or ampicillin-sulbactam.
However, clinical data have not shown such combination therapy
to be superior to colistin alone.
Bacteriophage therapy against multidrug-resistant A. baumannii
has been reported with varied success rates. Furthermore, dosing
and duration of therapy vary by syndrome and resistance can also
arise during treatment.
■ COMPLICATIONS AND PROGNOSIS
Infections caused by A. baumannii can be associated with high mortality rates. Factors contributing to higher mortality are thought to
include severity of the patient’s underlying illness and drug resistance
in the infecting strain.
■ INFECTION CONTROL AND PREVENTION
Acinetobacter species are capable of surviving on hospital surfaces for
prolonged periods. In the hospital environment, A. baumannii has
been associated with establishment of a fecal patina; this term refers
to a coating of enteric organisms that can cover the skin of colonized
patients and extend to their surrounding environment. Concentrations
of enteric organisms are highest in the colonized patient’s rectum,
with spread in a target-like concentric pattern covering the patient’s
body and the surrounding environment. High-frequency touch areas
in rooms occupied by patients colonized with A. baumannii are more
likely to be contaminated. The hands, gloves, and gowns of health care
workers can be contaminated after entry into the room of a patient
colonized with A. baumannii (Fig. 162-1).
Outbreaks caused by A. baumannii are frequently mono- or oligoclonal. A common source of infection has been identified in ~50% of
outbreaks. These sources include respiratory therapy equipment, the
hands of health care workers, bedside humidifiers, warm bathwater,
hospital-prepared distilled water, bedpans, urine jugs, heparinized
saline solution, mattresses, reusable pressure transducers in arterial
lines, and fluids used for pressure lavage of wounds.
Control of multidrug-resistant Acinetobacter outbreaks starts with
early recognition, with subsequent halting of the spread of infection throughout a facility and prevention of the establishment of an
endemic strain. It is important to identify the outbreak strain and
differentiate it from nonoutbreak strains so that infection control
activities can be better targeted. Traditionally, the strain was identified
with phenotypic typing systems (biotyping) or by determination of
antimicrobial susceptibility patterns. Molecular typing systems have
ushered in an era of molecular epidemiology that allows more precise
identification of outbreak strains through use of techniques such as
ribotyping, pulse-field gel electrophoresis, repetitive sequence-based
PCR, and multilocus sequence testing.
During outbreaks, the simultaneous introduction of multiple
(“bundled”) measures makes it difficult to assess the impact of each
individual measure. These interventions include aggressive cleaning of
the general environment, active surveillance, contact isolation of colonized or infected patients, cohorting of medical staff, reinforcement
of compliance with hand hygiene by health care workers, and use of
aseptic care devices.
Colonization with A. baumannii is a strong predictor of subsequent
clinical infection by this organism. Exposure to carbapenems is a risk
factor for initial acquisition of this pathogen; therefore, efforts to curtail unnecessary use of antibiotics are fundamental to the prevention of
A. baumannii–
positive patient
A. baumannii–
negative patient
Health care worker’s
hands
Health care
-Physical separation from environment
A. baumannii–negative
patients
-Rectal surveillance
-Cohorting nursing
personnel
-Chlorhexidine baths
-Antibiotic stewardship
-Hand hygiene
-Contact precautions
-Daily and terminal
disinfection
-Limits on shared equipment
-Disinfection of equipment
between patients
-Physical separation from
A. baumannii–positive
patients
-Cohorting nursing
personnel
-Chlorhexidine baths
-Antibiotic stewardship
Shared equipment
FIGURE 162-1 Strategies for the prevention of dissemination of Acinetobacter baumannii in health care facilities.
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