1224 PART 5 Infectious Diseases
well as a protease and a neuraminidase. Unlike the α toxin of C. perfringens, that of C. septicum does not possess phospholipase activity. The
mechanisms remain to be fully elucidated, but it is likely that each of
these toxins contributes uniquely to C. septicum gas gangrene.
TREATMENT
Gas Gangrene
Patients with suspected gas gangrene (either traumatic or spontaneous) should undergo prompt surgical inspection of the infected site.
Direct examination of a Gram-stained smear of the involved tissues
is of major importance. Characteristic histologic findings in clostridial gas gangrene include widespread tissue destruction, a paucity
of leukocytes in infected tissues in conjunction with an accumulation of leukocytes in adjacent vessels (Fig. 154-4), and the presence
of gram-positive rods (with or without spores). CT and MRI are
invaluable for determining whether the infection is localized or
is spreading along fascial planes, and needle aspiration or punch
biopsy may provide an etiologic diagnosis in at least 20% of cases.
However, these techniques should not replace surgical exploration,
Gram’s staining, and histopathologic examination. When spontaneous gas gangrene is suspected, blood should be cultured since bacteremia usually precedes cutaneous manifestations by several hours.
For patients with evidence of clostridial gas gangrene, thorough emergent surgical debridement is of extreme importance. All
devitalized tissue should be widely resected back to healthy viable
muscle and skin so as to remove conditions that allow anaerobic
organisms to continue proliferating. Closure of traumatic wounds
or compound fractures should be delayed for 5–6 days until it is
certain that these sites are free of infection.
Except for infection caused by C. tertium (see below), antibiotic
treatment of traumatic or spontaneous gas gangrene (Table 154-1)
consists of the administration of penicillin and clindamycin for
10–14 days. Penicillin is recommended on the basis of in vitro
sensitivity data; clindamycin is recommended because of its superior efficacy over penicillin in animal models of C. perfringens gas
gangrene and in some clinical reports. Controlled clinical trials
comparing the efficacy of these agents in humans have not been
performed. In the penicillin-allergic patient, clindamycin may be
used alone. The superior efficacy of clindamycin is probably due to
its ability to inhibit bacterial protein toxin production, its insensitivity to the size of the bacterial load or the stage of bacterial growth,
and its ability to modulate the host’s immune response.
Although C. perfringens remains largely susceptible to first-line
antibiotics, antibiotic resistance has been reported. Case reports
from the United Kingdom and from Spain found clindamycin-resistant C. perfringens in cellulitis and in a spontaneous abscess,
respectively. Larger studies from Canada and Taiwan also showed
increasing resistance to clindamycin among bloodstream isolates.
In 2014, Marchand-Austin et al published a 2-year prospective
Canadian study that examined antimicrobial susceptibility of anaerobic bacteria isolated from blood, body fluids, and abscesses. Of
1412 isolates submitted for susceptibility testing, 68 were C. perfringens. Of these, all were universally susceptible to penicillin but 3.8%
were clindamycin-resistant. Notably, for Clostridium species other
than C. perfringens (n = 289), 14.2% were penicillin-resistant and
21.6% clindamycin-resistant. A more recent study from Iran found
that 21.2% of C. perfringens isolates were resistant to penicillin.
Lastly, a 2019 study from Hungary found resistance to penicillin
(2.6%) and clindamycin (3.8%) among C. perfringens isolates (n =
313) from tissues with gas gangrene. Among the non-perfringens
gas gangrene isolates (n = 59), higher resistance to penicillin and
clindamycin was observed (6.8% and 8.5%, respectively). These
findings, though not universal, highlight the importance of good
anaerobic microbiology susceptibility testing to provide up-to-date
information to guide optimal clinical management decisions for
clostridial infections.
C. tertium is resistant to penicillin, cephalosporins, and clindamycin. Appropriate antibiotic therapy for C. tertium infection is vancomycin (1 g every 12 h IV) or metronidazole (500 mg every 8 h IV).
The value of adjunctive treatment with hyperbaric oxygen (HBO)
for gas gangrene remains controversial. Basic-science studies suggest
that HBO can inhibit the growth of C. perfringens but not that of the
more aerotolerant C. septicum. In vitro, blood and macerated muscle
inhibit the bactericidal potential of HBO. Numerous studies in animals demonstrate little efficacy of HBO alone, whereas antibiotics
alone—especially those that inhibit bacterial protein synthesis—
confer marked benefits. Addition of HBO to the therapeutic regimen provides some additional benefit, but only if surgery and
antibiotic administration precede HBO treatment.
In conclusion, gas gangrene is a rapidly progressive infection
whose outcome depends on prompt recognition, emergent surgery,
and timely administration of antibiotics that inhibit toxin production. Gas gangrene associated with bacteremia probably represents
a later stage of illness and is associated with the worst outcomes.
Emergent surgical debridement is crucial to ensure survival, and
ancillary procedures (e.g., CT or MRI) or transport to HBO units
should not delay this intervention. Some trauma centers associated
with HBO units may have special expertise in managing these
aggressive infections, but proximity and speed of transfer must be
carefully weighed against the need for haste.
PROGNOSIS OF GAS GANGRENE The prognosis for patients with gas
gangrene is more favorable when the infection involves an extremity
rather than the trunk or visceral organs, since debridement of the latter
sites is more difficult. Gas gangrene is most likely to progress to shock
and death in patients with associated bacteremia and intravascular
hemolysis. Mortality rates are highest for patients in shock at the time
of diagnosis. Mortality rates are relatively high among patients with
spontaneous gas gangrene, especially that due to C. septicum. Survivors
of gas gangrene may undergo multiple debridements and face long
periods of hospitalization and rehabilitation.
PREVENTION OF GAS GANGRENE Initial aggressive debridement of
devitalized tissue can reduce the risk of gas gangrene in contaminated
deep wounds. Interventions to be avoided include prolonged application of tourniquets and surgical closure of traumatic wounds; patients
with compound fractures are at significant risk for gas gangrene if the
wound is closed surgically. Vaccination against α toxin is protective in
experimental animal models of C. perfringens gas gangrene but has not
been investigated in humans. In addition, as mentioned above, a hyperimmune globulin would represent a significant advance for prophylaxis
in victims of acute traumatic injury or for attenuation of the spread of
infection in patients with established gas gangrene.
FIGURE 154-4 Histopathology of experimental gas gangrene due to C. perfringens,
demonstrating widespread muscle necrosis, a paucity of leukocytes in infected
tissues, and accumulation of leukocytes in adjacent vessels (arrows). These
features are due to the effects of α and θ toxins on muscle cells, platelets,
leukocytes, and endothelial cells.
1225CHAPTER 155 Meningococcal Infections
Toxic Shock Syndrome Clostridial infection of the endometrium,
particularly that due to C. sordellii, can develop after gynecologic
procedures, childbirth, or abortion (spontaneous or elective, surgical or medical) and, once established, proceeds rapidly to TSS
and death. Systemic manifestations, including edema, effusions,
profound leukocytosis, and hemoconcentration, are followed by the
rapid onset of hypotension and multiple-organ failure. Elevation of
the hematocrit to 75–80% and leukocytosis of 50,000–200,000 cells/
μL, with a left shift, are characteristic of C. sordellii infection. Pain
may not be a prominent feature, and fever is typically absent. In one
series, 18% of 45 cases of C. sordellii infection were associated with
normal childbirth, 11% with medically induced abortion, and 0.4%
with spontaneous abortion; the case–fatality rate was 100% in these
groups. Of the infections in this series that were not related to gynecologic procedures or childbirth, 22% occurred in injection drug users,
and 50% of these patients died. Other infections followed trauma or
surgery (42%), mostly in healthy persons, and 53% of these patients
died. Overall, the mortality rate was 69% (31 of 45 cases). Of patients
who succumbed, 85% died within 2–6 days after infection onset or
following procedures. Rapidly fatal, spontaneous C. bifermentans
necrotizing endometritis with toxic shock, leukemoid reaction, and
capillary leak has also been described.
Early diagnosis of C. sordellii infections often proves difficult
for several reasons. First, the prevalence of these infections is low.
Second, the initial symptoms are nonspecific and frankly misleading.
Early in the course, the illness resembles any number of infectious
diseases, including viral syndromes. Given these vague symptoms
and an absence of fever, physicians usually do not aggressively pursue
additional diagnostic tests. The absence of local evidence of infection
and the lack of fever make early diagnosis of C. sordellii infection particularly problematic in patients who develop deep-seated infection
following childbirth, therapeutic abortion, gastrointestinal surgery, or
trauma. Such patients are frequently evaluated for pulmonary embolization, gastrointestinal bleeding, pyelonephritis, or cholecystitis.
Unfortunately, such delays in diagnosis increase the risk of death, and,
as in most necrotizing soft tissue infections, patients are hypotensive
with evidence of organ dysfunction by the time local signs and symptoms become apparent. In contrast, infection is more readily suspected
in injection drug users presenting with local swelling, pain, and redness
at injection sites; early recognition probably contributes to the lower
mortality rates in this group.
Physicians should suspect C. sordellii infection in patients who present within 2–7 days after injury, surgery, drug injection, childbirth, or
abortion and who report pain, nausea, vomiting, and diarrhea but are
afebrile. There is little information regarding appropriate treatment for
C. sordellii infections. In fact, the interval between onset of symptoms
and death is often so short that there is little time to initiate empirical
antimicrobial therapy. Indeed, anaerobic cultures of blood and wound
aspirates are time-consuming, and many hospital laboratories do not
routinely perform antimicrobial sensitivity testing on anaerobes. Antibiotic susceptibility data from older studies suggest that C. sordellii,
like most clostridia, is susceptible to β-lactam antibiotics, clindamycin,
tetracycline, and chloramphenicol but is resistant to aminoglycosides
and sulfonamides. Antibiotics that suppress toxin synthesis (e.g., clindamycin) may possibly prove useful as therapeutic adjuncts since they
are effective in necrotizing infections due to other toxin-producing
gram-positive organisms.
Other Clostridial Skin and Soft Tissue Infections Crepitant
cellulitis (also called anaerobic cellulitis) occurs principally in diabetic
patients and characteristically involves subcutaneous tissues or retroperitoneal tissues, whereas the muscle and fascia are not involved. This
infection can progress to fulminant systemic disease.
Cases of C. histolyticum infection with cellulitis, abscess formation, or endocarditis have also been documented in injection drug
users. Endophthalmitis due to C. sordellii or C. perfringens has been
described. C. ramosum is also isolated frequently from clinical specimens, including blood and both intraabdominal and soft tissues. This
species may be resistant to clindamycin and multiple cephalosporins.
■ FURTHER READING
Aldape MJ et al: Clostridium sordellii infection: Epidemiology, clinical
findings, and current perspectives on diagnosis and treatment. Clin
Infect Dis 43:1436, 2006.
Bodey GP et al: Clostridial bacteremia in cancer patients. A 12-year
experience. Cancer 67:1928, 1991.
Bos J et al: Fatal necrotizing colitis following a foodborne outbreak of
enterotoxigenic Clostridium perfringens type A infection. Clin Infect
Dis 40:e78, 2005.
Bryant AE et al: Clostridial gas gangrene II: Phospholipase C–induced
activation of platelet gpIIb/IIIa mediates vascular occlusion and myonecrosis in C. perfringens gas gangrene. J Infect Dis 182:808, 2000.
Leong HN et al: Management of complicated skin and soft tissue
infections with a special focus on the role of newer antibiotics. Infect
Drug Resist 11:1959, 2018.
Marchand-Austin A et al: Antimicrobial susceptibility of clinical
isolates of anaerobic bacteria in Ontario, 2010-2011. Anaerobe
28:120-125, 2014.
Obladen M: Necrotizing enterocolitis—150 years of fruitless search
for the cause. Neonatology 96:203, 2009.
Peetermans M et al: Necrotizing skin and soft-tissue infections in the
intensive care unit. Clin Microbiol Infect 26:8, 2020.
Sayeed S et al: Beta toxin is essential for the intestinal virulence of
Clostridium perfringens type C disease isolate CN3685 in a rabbit ileal
loop model. Mol Microbiol 67:15, 2008.
Stevens DL, Bryant AE: Necrotizing soft tissue infections. N Engl J
Med 377:2253, 2017.
Stevens DL et al: Practice guidelines for the diagnosis and management of skin and soft tissue infections: 2014 update by the Infectious
Diseases Society of America. Clin Infect Dis 59:e10, 2014.
Stevens DL et al: Clostridium, in Manual of Clinical Microbiology,
11th ed, JH Jorgensen et al (eds). Washington, DC, ASM Press, 2015,
pp 940–966.
Wang C et al: Hyperbaric oxygen for treating wounds: A systematic
review of the literature. Arch Surg 138:272, 2003.
Section 6 Diseases Caused by
Gram-Negative Bacteria
155
■ DEFINITION
Infection with Neisseria meningitidis most commonly manifests as
asymptomatic colonization in the nasopharynx of healthy adolescents
and adults. Invasive disease occurs rarely, usually presenting as either
bacterial meningitis or meningococcal septicemia. Patients may also
present with occult bacteremia, pneumonia, septic arthritis, conjunctivitis, and chronic meningococcemia.
■ ETIOLOGY AND MICROBIOLOGY
N. meningitidis is a gram-negative aerobic diplococcus that colonizes
humans only and that causes disease after transmission to a susceptible
individual. Several related neisserial organisms have been recognized,
including the pathogen N. gonorrhoeae and the commensals N. lactamica, N. flavescens, N. mucosa, N. sicca, and N. subflava. N. meningitidis
is a catalase- and oxidase-positive organism that utilizes glucose and
maltose to produce acid.
Meningococcal
Infections
Manish Sadarangani,
Andrew J. Pollard
1226 PART 5 Infectious Diseases
for typing of meningococci are restricted by the limited availability of
serologic reagents that can distinguish among the organisms’ highly
variable surface proteins. Where available, high-throughput antigen
gene sequencing has superseded serology for meningococcal typing. A
large database of antigen gene sequences for the outer-membrane proteins PorA, PorB, FetA, Opa, NadA, Neisserial heparin binding antigen
(NHBA), and factor H–binding protein (fHbp) is available online
(pubmlst.org/organisms/neisseria-spp). The number of specialized
iron-regulated proteins found in the meningococcal outer membrane
(e.g., FetA and transferrin-binding proteins) highlights the organisms’
dependence on iron from human sources. A thin peptidoglycan cell
wall separates the outer membrane from the cytoplasmic membrane.
The structure of meningococcal populations involved in local and
global spread has been studied with multilocus enzyme electrophoresis (MLEE), which characterizes isolates according to differences in the electrophoretic mobility of cytoplasmic enzymes. However,
this technique was replaced by multilocus sequence typing (MLST), in
which meningococci are characterized by sequence types assigned on
the basis of sequences of internal fragments of 7 housekeeping genes.
The online MLST database currently includes more than 15,000 unique
Neisseria sequence types. A limited number of hyperinvasive lineages
of N. meningitidis have been recognized and are responsible for the
majority of cases of invasive meningococcal disease worldwide. Hyperinvasive lineages may be associated with more than one capsular group.
The apparent genetic stability of these meningococcal clones over
decades and during wide geographic spread indicates that they are well
adapted to the nasopharyngeal environment of the host and to efficient
transmission. While MLST has become established as the main method
for meningococcal genotyping in many reference laboratories over the
past 15 years, whole-genome sequencing is gradually replacing this
approach, with more than 4500 genomes already available in the
United Kingdom’s national library.
The group B meningococcal genome is >2 megabases in length and
contains 2158 coding regions. Many genes undergo phase variation
that makes it possible to control their expression; this capacity is likely
to be important in meningococcal adaptation to the host environment
and evasion of the immune response. Meningococci can obtain DNA
from their environment and can acquire new genes—including the
capsular operon—such that capsule switching from one capsular group
to another can occur.
■ EPIDEMIOLOGY
Patterns of Disease Up to 500,000 cases of meningococcal disease
are thought to occur worldwide each year, although the numbers have
been declining recently as a result of both immunization programs and
secular trends. About 10% of affected individuals die. There are several
patterns of disease: epidemic, outbreak (small clusters of cases), hyperendemic, and sporadic or endemic.
Epidemics have continued since the original descriptions of meningococcal disease, especially affecting the sub-Saharan meningitis belt
of Africa, where tens to hundreds of thousands of cases (caused mainly
by capsular group A but also by capsular groups C, W, and X) may
be reported over a season and rates may be as high as 1000 cases per
100,000 population. Capsular group A epidemics took place in Europe
and North America after the First and Second World Wars, and capsular group A outbreaks have been documented over the past 30 years
in New Zealand, China, Nepal, Mongolia, India, Pakistan, Poland, and
Russia. However, 65% of outbreaks reported in the meningitis belt
between 2010 and 2017 were caused by capsular group C and 35% by
capsular group W meningococci, following an immunization campaign to control capsular group A outbreaks.
Clusters of cases occur where there is an opportunity for increased
transmission—i.e., in closed or semi-closed communities such as
schools, colleges, universities, military training centers, and refugee
camps. Recently, such clusters have been especially strongly linked
with a particular clone (sequence type 11) that is mainly associated
with capsular group C or W but was first described in association with
capsular group B. Clusters of capsular group W disease associated with
TABLE 155-1 Structure of the Polysaccharide Capsule of Common
Disease-Causing Meningococci
MENINGOCOCCAL
CAPSULAR GROUP
CHEMICAL STRUCTURE OF
OLIGOSACCHARIDE
CURRENT DISEASE
EPIDEMIOLOGY
A 2-Acetamido-2-deoxyD-mannopyranosyl
phosphate
Epidemic disease mainly in
sub-Saharan Africa; sporadic
cases worldwide
B α-2,8-N-acetylneuraminic
acid
Sporadic cases worldwide;
propensity to cause
hyperendemic disease
C α-2,9-O-acetylneuraminic
acid
Small outbreaks and
sporadic disease
Y 4-O-α-D-glucopyranosylN-acetylneuraminic acid
Sporadic disease and
occasional small institutional
outbreaks
W 4-O-α-D-galactopyranosylN-acetylneuraminic acid
Sporadic disease; outbreaks
of disease associated with
mass gatherings; epidemics
in sub-Saharan Africa
X (α1→4) N-acetyl-Dglucosamine-1-phosphate
Sporadic disease and large
outbreaks in the meningitis
belt of Africa
FIGURE 155-1 Electron micrograph of Neisseria meningitidis. Black dots are
gold-labeled polyclonal antibodies binding surface opacity proteins. Blebs of outer
membrane can be seen being released from the bacterial surface (arrow). (Photo
courtesy of D. Ferguson, Oxford University.)
Meningococci associated with invasive disease are usually encapsulated with polysaccharide, and the antigenic nature of the capsule
determines an organism’s capsular group (serogroup) (Table 155-1).
In total, 12 capsular groups have been identified (A–C, X–Z, E, W,
H–J, and L), but just six of these—A, B, C, X, Y, and W (formerly
W135)—account for the majority of cases of invasive disease. Group
D is often listed as the thirteenth capsular group but has recently been
identified as an unencapsulated variant of group C. Meningococci are
commonly isolated from the nasopharynx in studies of carriage; the
lack of capsule often is a result of phase variation of capsule expression,
but as many as 16% of isolates lack the genes for capsule synthesis and
assembly. These “capsule-null” meningococci and those that express
capsules other than A, B, C, X, Y, and W are only rarely associated with
invasive disease and are most commonly identified in the nasopharynx
of asymptomatic carriers.
Beneath the capsule, meningococci are surrounded by an outer phospholipid membrane containing lipopolysaccharide (LPS, endotoxin)
and multiple outer-membrane proteins (Figs. 155-1 and 155-2). Antigenic variability in porins expressed in the outer membrane defines the
serotype (PorB) and serosubtype (PorA) of the organism, and structural differences in LPS determine the immunotype. Serologic methods
1227CHAPTER 155 Meningococcal Infections
Iron-binding
proteins
e.g., FetA RmpM
LPS NadA PorA
Outer
membrane
Polysaccharide
capsule
Cytoplasmic
membrane
Periplasmic
space
Phospholipid
bilayer
Transporter protein
e.g., FbpA, SodC
Inner membrane
transporter complex
e.g., FbpB, FbpC
Pilus assembly
apparatus
Pilus
Opa PorB fHbp
FIGURE 155-2 Cross-section through surface structures of Neisseria meningitidis. LPS, lipopolysaccharide.
(Reproduced with permission from M Sadarangani, AJ Pollard: Serogroup B meningococcal vaccines–an unfinished
story. Lancet Infect Dis 10:112, 2010.)
the Hajj pilgrimage in 2000/2001 led to a requirement for vaccination
against meningococcal disease for travel to Saudi Arabia. Wider and
more prolonged community outbreaks (hyperendemic disease) due
to single clones of capsular group B meningococci account for ≥10
cases per 100,000. Regions affected in the past decade include the U.S.
Pacific Northwest, New Zealand (both islands), and the province of
Normandy in France.
Most countries now experience predominantly sporadic cases
(0.3–5 cases per 100,000 population), with many different diseasecausing clones involved and usually no clear epidemiologic link
between one case and another. The disease rate and the distribution
of meningococcal strains vary in different regions of the world and
also in any one location over time. For example, in the United States,
the rate of meningococcal disease fell from 1.2 cases per 100,000
population in 1997 to 0.10 cases per 100,000 in 2018 (Fig. 155-3).
Meningococcal disease in the United States was previously dominated
by capsular groups B and C; however, capsular group Y emerged during the 1990s and in 2018 group B was predominant in children age
<5 years, whereas adults 45 years and older were infected with groups
B, C, and Y (Fig. 155-4). In contrast, rates of disease in England and
Wales rose to >5 cases per 100,000 during the 1990s because of an
increase in cases caused by the ST11 capsular group C clone. As a result
of a mass immunization program against capsular group C in 1999,
capsular group B then became predominant. Introduction of a MenB
vaccine since 2015 has led to a significant reduction in group B cases, with an
increase in recent years of capsular group
W infections (Fig. 155-4). Over the last
decade, most industrialized nations have
seen a general decrease in meningococcal disease; this decrease is linked to
immunization against capsular group C
meningococci in Europe, Canada, and
Australia and to adolescent immunization programs for capsular groups A, C,
Y, and W in the United States. However,
other factors, including changes in population immunity and prevalent clones of
meningococci (factors that, in combination, probably explain the cyclic nature
of meningococcal disease rates) as well
as a reduction in smoking and passive
exposure to tobacco smoke (driven by
bans on smoking in buildings and public spaces) across wealthy countries, are
likely to have contributed to the fall in
cases. Over the past decade, a hyperinvasive ST11 clone bearing a W capsule has
emerged in South America and spread to the United Kingdom and has
also emerged in other countries in Europe and in Australia, leading to a
considerable increase in capsular group W cases. Increases in capsular
group Y disease have also been noted in various countries in Europe,
Canada, and South Africa.
Factors Associated with Disease Risk and Susceptibility The
principal determinant of disease susceptibility is age, with the peak
incidence in the first year of life (Fig. 155-5). The susceptibility of the
very young presumably results from an absence of specific adaptive
immunity in combination with very close contact with colonized individuals, including parents. Compared with other age groups, infants
appear to be particularly susceptible to capsular group B disease: >30%
of capsular group B cases in the United States occur during the first
year of life. In the early 1990s in North America, the median ages for
patients with disease due to capsular groups B, C, Y, and W were 6, 17,
24, and 33 years, respectively.
After early childhood, a second peak of disease occurs among adolescents and young adults (15–25 years of age) in Europe and North
America. It is thought that this peak relates to social behaviors and
environmental exposures in this age group, as discussed below. Most
cases of infection with N. meningitidis in developed countries today
are sporadic, and the rarity of the disease suggests that individual susceptibility may be important. A number of factors probably contribute
to individual susceptibility, including the host’s genetic constitution,
environment, and contact with a carrier or a case.
The best-documented genetic association with meningococcal
disease is complement deficiency, chiefly of the terminal complement
components (C5–9), properdin, or factor D; such a deficiency increases
the risk of disease by up to 600-fold and may result in recurrent
attacks. Complement components are believed to be important for the
bactericidal activity of serum, which is considered the principal mechanism of immunity against invasive meningococcal disease. However,
when investigated, complement deficiency is found in only a very
small proportion of individuals with meningococcal disease (0.3%).
Conversely, 7–20% of persons whose disease is caused by the less common capsular groups (W, X, Y, Z, E) have a complement deficiency.
Complement deficiency appears to be associated with capsular group
B disease only rarely. Individuals with recurrences of meningococcal
disease, particularly those caused by non-B capsular groups, should be
assessed for complement deficiency by measurement of total hemolytic
complement activity. There is also limited evidence that hyposplenism
(through reduction in phagocytic capacity) and hypogammaglobulinemia (through absence of specific antibody) increase the risk
of meningococcal disease. Genetic studies have revealed various
Cases per 100,000 population
1997
1.4
1.2
1
0.8
0.6
0.4
0.2
Meningococcal disease rates in ABCs surveillance area
Year
0
1998
1999
2000 2001
2002
2003 2004
2005 2006 2007 2008 200920102011
2012
2013
2014
2015
2016
2017
Other Y C B
FIGURE 155-3 Meningococcal disease in the United States, 1997–2017. ABCs,
active bacterial cores. (Adapted from ABC Surveillance data, Centers for Disease
Control and Prevention; www.cdc.gov.)
1228 PART 5 Infectious Diseases
B,C,Y
B,C
B
B,C
B,C
B,C A,B,C
B,W
A
W,A
B,C
A,W
(X)
A,W,C
FIGURE 155-4 Global distribution of meningococcal capsular groups, 1999–2009. Incidence / 100,000
1
0.8
0.6
0.4
0.2
0
Meningococcal disease by age and capsular group, USA, 2009-2018
<1 year 1-4
years
5-10
years
11-14
years
15-18
years
Age in years
19-22
years
23-26
years
27-64
years
65+
years
B ACYW
FIGURE 155-5 Age distribution of capsular groups B and ACWY meningococcal disease USA, 2009-
2018. (Adapted from www.cdc.gov/meningococcal/surveillance/surveillance-data.html#figure01.)
associations with disease susceptibility, including complement and
mannose-binding lectin deficiency, single-nucleotide polymorphisms
in Toll-like receptor (TLR) 4 and complement factor H, and variants
of Fc gamma receptors.
Factors that increase the chance of a susceptible individual’s acquiring N. meningitidis via the respiratory route also increase the risk of
meningococcal disease. Acquisition occurs through close contact with
carriers as a result of overcrowding (e.g., in poor socioeconomic settings, in refugee camps, during the Hajj pilgrimage to Mecca, during
freshman-year residence in college dormitories) and certain social
behaviors (e.g., attendance at bars and nightclubs, kissing). Secondary
cases may occur in close contacts of an index case (e.g., household
members, persons kissing the infected individual); the risk to these
contacts may be as high as 1000 times the background rate in the
population. Factors that damage the nasopharyngeal epithelium also
increase the risk of both colonization with N. meningitidis and invasive disease. The most important of these factors are tobacco smoking
(odds ratio, 4.1) and passive exposure to tobacco smoke. In addition,
recent viral respiratory tract infection, infection with Mycoplasma
species, and winter or the dry season have been associated with meningococcal disease; all of these factors presumably either increase the
expression of adhesion molecules in the nasopharynx, thus enhancing
meningococcal adhesion, or facilitate meningococcal invasion of the
bloodstream.
■ PATHOGENESIS
N. meningitidis has evolved as an effective colonizer of the human
nasopharynx, with asymptomatic infection rates of >25% described
in some series of adolescents and young adults and among residents
of crowded communities. Point-prevalence studies reveal widely
divergent rates of carriage for different types of meningococci. This
variation suggests that some types may be adapted to a short duration
of carriage with frequent transmission to maintain the population,
while others may be less efficiently transmitted but may overcome this
disadvantage by colonizing for a long period. Despite the high rates
of carriage among adolescents and young adults, only ~10% of adults
carry meningococci, and colonization is very rare in early childhood.
Many of the same factors that increase the risk of meningococcal disease also increase the risk of carriage. Colonization of the nasopharynx
involves a series of interactions of meningococcal adhesins (e.g., Opa
proteins and pili) with their ligands on the epithelial mucosa. N. meningitidis produces an IgA1 protease that is likely to reduce interruption
of colonization by mucosal IgA.
Colonization should be considered the normal state of meningococcal infection, with an increased risk of invasion being the unfortunate consequence (for both host and organism) of
adaptations of hyperinvasive meningococcal lineages.
The meningococcal capsule is an important virulence
factor: acapsular strains only very rarely cause invasive
disease. The capsule provides resistance to phagocytosis
and may be important in preventing desiccation during transmission between hosts. Antigenic diversity in
surface structures and an ability to vary levels of their
expression probably have evolved as important factors
in maintaining meningococcal populations within and
between individual hosts.
Invasion through the mucosa into the bloodstream
occurs rarely, usually within a few days of acquisition
of an invasive strain by a susceptible individual. Only
occasional cases of prolonged colonization prior to
invasion have been documented. Once the organism
1229CHAPTER 155 Meningococcal Infections
is in the bloodstream, its growth may be limited if the individual is
partially immune, although bacteremia may allow seeding of another
site, such as the meninges or the joints. Alternatively, unchecked proliferation may continue, resulting in high bacterial counts in the circulation. During growth, meningococci release blebs of outer membrane
(Fig. 155-1) containing outer-membrane proteins and LPS. Endotoxin binds cell-bound CD14 in association with TLR4 to initiate an
inflammatory cascade with the release of high levels of various mediators, including tumor necrosis factor (TNF) α, soluble TNF receptor,
interleukin (IL) 1, IL-1 receptor antagonist, IL-1β, IL-6, IL-8, IL-10,
plasminogen-activator inhibitor 1 (PAI-1), and leukemia inhibitory
factor. Soluble CD14-bound endotoxin acts as a mediator of endothelial activation. The severity of meningococcal disease is related
both to the levels of endotoxin in the blood and to the magnitude of
the inflammatory response. The latter is determined to some extent
by polymorphisms in the inflammatory response genes (and their
inhibitors), and the release of the inflammatory cascade heralds the
development of meningococcal septicemia (meningococcemia). Endothelial injury is central to many clinical features of meningococcemia,
including increased vascular permeability, pathologic changes in vascular tone, loss of thromboresistance, intravascular coagulation, and
myocardial dysfunction. Endothelial injury leads to increased vascular
permeability (attributed to loss of glycosaminoglycans and endothelial
proteins), with subsequent gross proteinuria. Leakage of fluid and
electrolytes into the tissues from capillaries (“capillary leak syndrome”)
leads to hypovolemia, tissue edema, and pulmonary edema. Initial
compensation results in vasoconstriction and tachycardia, although
cardiac output eventually falls. While resuscitation fluids may restore
circulating volume, tissue edema will continue to increase, and, in the
lung, the consequence may be respiratory failure.
Intravascular thrombosis (caused by activation of procoagulant
pathways in association with upregulation of tissue factor on the
endothelium) occurs in some patients with meningococcal disease and
results in purpura fulminans and infarction of areas of skin or even
of whole limbs. At the same time, multiple anticoagulant pathways
are downregulated through loss of endothelial thrombomodulin and
protein C receptors and decreases in levels of antithrombin III, protein
C, protein S, and tissue factor pathway inhibitor. Thrombolysis is also
profoundly impaired in meningococcal sepsis through the release of
high levels of PAI-1.
Shock in meningococcal septicemia appears to be attributable to
a combination of factors, including hypovolemia, which results from
the capillary leak syndrome secondary to endothelial injury, and
myocardial depression, which is driven by hypovolemia, hypoxia, metabolic derangements (e.g., hypocalcemia), and cytokines (e.g., IL-6).
Decreased perfusion of tissues as a result of intravascular thrombosis,
vasoconstriction, tissue edema, and reduced cardiac output in meningococcal septicemia can cause widespread organ dysfunction, including renal impairment and—later in the disease—a decreased level of
consciousness due to central nervous system involvement.
Bacteria that reach the meninges cause a local inflammatory
response—with release of a spectrum of cytokines similar to that seen
in septicemia—that presents clinically as meningitis and is thought to
determine the severity of neuronal injury. Local endothelial injury may
result in cerebral edema and rapid onset of raised intracranial pressure
in some cases.
■ CLINICAL MANIFESTATIONS
As discussed above, the most common form of infection with N. meningitidis is asymptomatic carriage of the organism in the nasopharynx.
Despite the location of infection in the upper airway, meningococcal
pharyngitis is rarely reported; however, upper respiratory tract symptoms are common prior to presentation with invasive disease. It is
not clear whether these symptoms relate to preceding viral infection
(which may promote meningococcal acquisition and/or invasion)
or to meningococcal acquisition itself. After acquiring the organism, susceptible individuals develop disease manifestations in 1–10
days (usually <4 days, although colonization for 11 weeks has been
documented).
Along the spectrum of presentations of meningococcal disease,
the most common clinical syndromes are meningitis and meningococcal septicemia. In fulminant cases, death may occur within hours
of the first symptoms. Occult bacteremia is also recognized and, if
untreated, progresses in two-thirds of cases to focal infection, including
meningitis or septicemia. Meningococcal disease may also present as
pneumonia, pyogenic arthritis or osteomyelitis, purulent pericarditis, endophthalmitis, conjunctivitis, primary peritonitis, or (rarely)
urethritis. Perhaps because it is difficult to diagnose, meningococcal
pneumonia is not commonly reported but is associated with capsular groups Y, W, and Z and appears most often to affect individuals
>10 years of age.
Rash A nonblanching rash (petechial or purpuric) develops in >80%
of cases of meningococcal disease; however, the rash is often absent
early in the illness. Usually initially blanching in nature (macules, maculopapules, or urticaria) and indistinguishable from more common
viral rashes, the rash of meningococcal infection becomes petechial or
frankly purpuric over the hours after onset. In the most severe cases,
large purpuric lesions develop (purpura fulminans; Fig. A1-41). Some
patients (including those with overwhelming sepsis) may have no rash.
While petechial rash and fever are important signs of meningococcal
disease, fewer than 10% of children (and, in some clinical settings,
fewer than 1% of patients) with this presentation are found to have
meningococcal disease. Most patients presenting with a petechial or
purpuric rash have a viral infection (Table 155-2). The skin lesions
exhibit widespread endothelial necrosis and occlusion of small vessels
in the dermis and subcutaneous tissues, with a neutrophilic infiltrate.
Meningitis Meningococcal meningitis commonly presents as nonspecific manifestations, including fever, vomiting, and (especially in
infants and young children) irritability, and is indistinguishable from
other forms of bacterial meningitis unless there is an associated petechial or purpuric rash, which occurs in two-thirds of cases. Headache
is rarely reported in early childhood but is more common in later childhood and adulthood. When headache is present, the following features,
in association with fever or a history of fever, are suggestive of bacterial
meningitis: neck stiffness, photophobia, decreased level of consciousness, seizures or status epilepticus, and focal neurologic signs. Classic
signs of meningitis, such as neck stiffness and photophobia, are often
absent in infants and young children with bacterial meningitis, who
more usually present with fever and irritability and may have a bulging
fontanelle.
While 30–50% of patients present with a meningitis syndrome
alone, up to 40% of meningitis patients also present with some features
of septicemia. Most deaths from meningococcal meningitis alone (i.e.,
without septicemia) are associated with raised intracranial pressure
presenting as a reduced level of consciousness, relative bradycardia
and hypertension, focal neurologic signs, abnormal posturing, and
signs of brainstem involvement—e.g., unequal, dilated, or poorly reactive pupils; abnormal eye movement; and impaired corneal responses
(Chap. 28).
TABLE 155-2 Common Causes of Petechial or Purpuric Rashes
Enteroviruses
Influenza and other respiratory viruses
Measles virus
Epstein-Barr virus
Cytomegalovirus
Parvovirus
Deficiency of protein C or S (including postvaricella protein S deficiency)
Platelet disorders (e.g., idiopathic thrombocytopenic purpura, drug effects, bone
marrow infiltration)
Henoch-Schönlein purpura, connective tissue disorders, trauma (including
nonaccidental injuries in children)
Pneumococcal, streptococcal, staphylococcal, or gram-negative bacterial
sepsis
1230 PART 5 Infectious Diseases
Septicemia Meningococcal septicemia alone accounts for up to
20% of cases of meningococcal disease. The condition may progress
from early nonspecific symptoms to death within hours. Mortality
rates among children with this syndrome have been high (25–40%),
but early aggressive management (as discussed below) may reduce the
figure to <10%. Early symptoms are nonspecific and suggest an influenza-like illness with fever, headache, and myalgia accompanied by
vomiting and abdominal pain. As discussed above, the rash, if present,
may appear to be viral early in the course until petechiae or purpuric
lesions develop. Purpura fulminans occurs in severe cases (Fig. A1-41),
with multiple large purpuric lesions and signs of peripheral ischemia.
Surveys of patients have indicated that limb pain, pallor (including a
mottled appearance and cyanosis), and cold hands and feet may be
prominent. Shock is manifested by tachycardia, poor peripheral perfusion, tachypnea, and oliguria. Decreased cerebral perfusion leads
to confusion, agitation, or decreased level of consciousness. With
progressive shock, multiorgan failure ensues; hypotension is a late sign
in children, who more commonly present with compensated shock
(tachycardia, poor peripheral perfusion, and normal blood pressure).
Poor outcome is associated with an absence of meningism, hypotension, young age, coma, relatively low temperature (<38°C), leukopenia,
and thrombocytopenia. Spontaneous hemorrhage (pulmonary, gastric,
or cerebral) may result from consumption of coagulation factors and
thrombocytopenia.
Chronic Meningococcemia Chronic meningococcemia, which
is rarely recognized, presents as repeated episodes of petechial rash
(Fig. A1-42) associated with fever, joint pain, features of arthritis, and
splenomegaly that may progress to acute meningococcal septicemia if
untreated. During the relapsing course, bacteremia characteristically
clears without treatment and then recurs. The differential diagnosis
includes bacterial endocarditis, acute rheumatic fever, Henoch-Schönlein purpura, infectious mononucleosis, disseminated gonococcal
infection, and immune-mediated vasculitis. This condition has been
associated with complement deficiencies in some cases and with inadequate sulfonamide therapy in others.
A study from the Netherlands found that half of isolates from
patients with chronic meningococcemia had an underacylated
lipid A (part of the surface LPS molecule) due to an lpxL1 gene
mutation, which markedly reduces the inflammatory response to
endotoxin.
Postmeningococcal Reactive Disease In a small proportion
of patients, an immune complex disease develops ~4–10 days after
the onset of meningococcal disease, with manifestations that include
a maculopapular or vasculitic rash (2% of cases), arthritis (up to 8%
of cases), iritis (1%), pericarditis, and/or polyserositis associated with
fever. The immune complexes involve meningococcal polysaccharide
antigen and result in immunoglobulin and complement deposition
with an inflammatory infiltrate. These features resolve spontaneously
without sequelae. It is important to recognize this condition since a
new onset of fever and rash, and/or arthritis, can lead to concerns
about relapse of meningococcal disease and unnecessarily prolonged
antibiotic treatment.
■ DIAGNOSIS
Like other invasive bacterial infections, meningococcal disease may
produce elevations of the white blood cell (WBC) count and of values
for inflammatory markers (e.g., C-reactive protein and procalcitonin
levels or the erythrocyte sedimentation rate). Values may be normal or
low in rapidly progressive disease, and a lack of rise in these laboratory
test values does not exclude the diagnosis. However, in the presence
of fever and a petechial rash, these elevations are suggestive of meningococcal disease. In patients with severe meningococcal septicemia,
common laboratory findings include hypoglycemia, acidosis, hypokalemia, hypocalcemia, hypomagnesemia, hypophosphatemia, anemia,
and coagulopathy.
Although meningococcal disease is often diagnosed on clinical
grounds, in suspected meningococcal meningitis or meningococcemia,
blood should routinely be sent for culture to confirm the diagnosis and
to facilitate public health investigations; blood cultures are positive in
up to 75% of cases. Culture media containing sodium polyanethol sulfonate, which may inhibit meningococcal growth, should be avoided.
Meningococcal viability is reduced if there is a delay in transport of the
specimen to the microbiology laboratory for culture or in plating of
cerebrospinal fluid (CSF) samples. In countries where treatment with
antibiotics before hospitalization is recommended for meningococcal
disease, the majority of clinically suspected cases are culture negative.
Real-time polymerase chain reaction (PCR) analysis of whole-blood
samples increases the diagnostic yield by >40%, and results obtained
with this method may remain positive for several days after administration of antibiotics. Indeed, in the United Kingdom, more than half of
clinically suspected cases are currently identified by PCR.
Unless contraindications exist (raised intracranial pressure, uncorrected shock, disordered coagulation, thrombocytopenia, respiratory
insufficiency, local infection, ongoing convulsions), lumbar puncture
should be undertaken to identify and confirm the etiology of suspected
meningococcal meningitis, whose presentation cannot be distinguished
from that of meningitis of other bacterial causes. Some authorities have
recommended a CT brain scan prior to lumbar puncture because of the
risk of cerebral herniation in patients with raised intracranial pressure.
However, a normal CT scan is not uncommon in the presence of raised
intracranial pressure in meningococcal meningitis, and the decision to
perform a lumbar puncture should be made on clinical grounds. CSF
features of meningococcal meningitis (elevated protein level and WBC
count, decreased glucose level) are indistinguishable from those of
other types of bacterial meningitis unless a gram-negative diplococcus
is identified. (Gram’s staining is up to 80% sensitive for meningococcal
meningitis.) CSF should be submitted for culture (sensitivity, 90%) and
(where available) PCR analysis. CSF antigen testing with latex agglutination is insensitive and should be replaced by molecular diagnosis
when possible.
Lumbar puncture should generally be avoided in meningococcal
septicemia, as positioning for the procedure may critically compromise
the patient’s circulation in the context of hypovolemic shock. Delayed
lumbar puncture may still be useful when the diagnosis is uncertain,
particularly if molecular diagnostic technology is available.
In other types of focal infection, culture and PCR analysis of normally sterile body fluids (e.g., synovial fluid) may aid in the diagnosis.
Although some authorities have recommended cultures of scrapings or
aspirates from skin lesions, this procedure adds little to the diagnostic
yield when compared with a combination of blood culture and PCR
analysis. Urinary antigen testing also is insensitive, and serologic testing
for meningococcal infection has not been adequately studied. Because
N. meningitidis is a component of the normal human nasopharyngeal
flora, identification of the organism on throat swabs has limited diagnostic value, but strains identified in the nasopharynx in the context of
a probable case are likely to be those responsible for disease.
TREATMENT
Meningococcal Infections
Death from meningococcal disease is associated most commonly
with hypovolemic shock (meningococcemia) and occasionally with
raised intracranial pressure (meningococcal meningitis). Therefore,
management should focus on the treatment of these urgent clinical
issues in addition to the administration of specific antibiotic therapy. Delayed recognition of meningococcal disease or its associated
physiologic derangements, together with inadequate emergency
management, is associated with poor outcome. Since the disease
is rare, protocols for emergency management have been developed
(see www.meningitis.org).
Airway patency may be compromised if the level of consciousness is depressed as a result of shock (impaired cerebral perfusion)
or raised intracranial pressure; this situation may require intervention. In meningococcemia, pulmonary edema and pulmonary
oligemia (presenting as hypoxia) require oxygen therapy or elective endotracheal intubation. In cases with shock, aggressive fluid
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