Cryptococcal meningitis Melicent Peck MD, PhD Stanford University Department of Medicine

Transcription

Cryptococcal meningitis Melicent Peck MD, PhD Stanford University Department of Medicine
Cryptococcal meningitis
Melicent Peck MD, PhD
Stanford University
Department of Medicine
Case One
HPI: 73 y/o male admitted for 3-week h/o acute memory loss. Per pt’s wife, pt getting lost, repeating
same story over and over, unable to recall details of recent events. No F/C, no HA, no recent illness.
Patient had acute-onset aphasia in 07/09 and 09/09 with resolution over several weeks. Found to have L
temporal stroke on MRI brain.
PMHx: IDDM, HLD, HTN, vertigo (x 2 years, attributed to Meniere's disease)
Meds: Metformin, Lantus, Nicardipine, Citicholine SR
SHx: No etoh, tobacco. Retired administrator, lives in Bangalore, India but travels to US ~ 1x/year to see
family. No rural contacts, no hiking, no pets.
FHx: NC
PE: VSS. AAO x 3. Exam unremarkable.
Labs: Na 133, CRP < 0.2, ESR 38, HIV negative, serum CrAg 1:4
LP: OP 22cm, 116 wbc ((N28L66M6)), 12,625 rbc, xanthochromia, g
glucose 69, TP 536, CrAg
g 1:4
Gram Stain: small number polys, small number PMNs, small number rbc, no organisms, Cx: NGTD
MRI brain: new temporal lobe CVA
Case Two
HPI: 55 y/o male with h/o HIV (CD4+ 2 cells/l, VL 1850 copies/ml) not on HAART with OI disseminated KS
and Candidiasis, homeless admitted for abdominal pain, SOB. Pt found to have SBO s/p lysis of
adhesions, PNA 2/2 KS vs CAP. +HA primarily in morning, diffuse.
PMHx: HIV (1990), disseminated KS (lung, skin), Candidiasis (esophageal), polysubstance abuse
Meds: Atazanavir, Truvada, Ritonovir, Bactrim, Fluconazole, Azithromycin
SHx: Homeless, + etoh, + crack cocaine
FHx: NC
PE: VS: RR 24 Chronically ill-appearing male, cachectic OP: oral thrush, areas of mild ulceration on hard
palate, CV: RRR no mrg Lung: diffuse coarse crackles, decreased BS in RLL Abd: TTP RLQ with voluntary
guarding Skin: 2 x 2 cm violaceous macule on dorsum of L foot Neuro: non-focal
Labs: Hct 29, Na 132, albumin 2
BCx +Cryptococcemia, CrAg 1:256
LP <1
LP:
1 wbc,
b <1
1 rbc,
b Glucose
Gl
66,
66 TP 24
24,CrAg
C A 1:8
18
GS: no polys, no orgs Cx: NGTD Fungal Cx: Cryptococcus neoformans (liquid media, not on plate)
CT Head: unremarkable
DDX: Chronic Meningitis
 Bacteria




Mycobacterium Tb
Syphilis
Lyme disease
Nocardiosis
 Parasites


Cysticercosis
y
Acanthamebiasis
 Fungal





•
Cryptococcosis
Coccidiomycosis
Histoplasmosis
Candidiasis
Aspergillosis
Viral
•
•
HSV
VZV
•Sarcoid
•Tumor
Cryptococcal Meningitis
 Signs/Symptoms
 HA,, F,, nuchal rigidity,
g
y, p
photophobia
p
 Decreased vision, unsteady gait, CN palsies
 Confusion, lethargy, memory loss over several weeks
 Seizure or strokes in multiple vascular territories
 Causative Agent
Strain
Global
Distribution
Environmental
Reservoir
C. neoformans
Global
Temperate
climates
Pigeon droppings/
guano/ birds nests
Rotting
g vegetation
g
Epidemiology
 Occurs
O
in
i ~ 1 million
illi people
l per year
 ~600,000 deaths annually
 3-month mortality rate ~20% in developed countries, ~70% in Africa
 Primarily seen in immunocompromised patients
 Newly diagnosed HIV patients


Most common OI in AIDS (CD4+ < 50 cells/l)
 Incidence 0.04%-12% per year
Look for co-morbid CNS processes (Toxoplasma, Nocardia, lymphoma)
 Solid organ transplant patients


Median time to disease onset 21 months after transplantation
g transplant
p
recipients
p
Documented in 2.8% of sold-organ
 High dose CS, monoclonal Abs, other immunosuppressants
 Global disease burden
 Sub-Saharan
Sub Saharan Africa > S and SE Asia > Latin America >
E Europe and Central Asia > > N America > N Africa
and Middle East> W and Central Europe
 95% of cryptococcal meningitis cases in developing countries
are HIV associated
i t d

Account for 10-20% of all deaths in HIV infected patients in Africa (> Tb)
Pathogenesis
g
 Virulence Factors
 Capsule
 Antiphagocytosis barrier, depletes complement, dysregulates
cytokine secretion
 Melanin
 Antioxidant (UV light, toxic free radicals), interferes with T-cell
response
 Growth at high-temperature (37o C)
Mechanism of Infection
 Yeast spores enter host through lungs via inhalation
 Spores deposited in alveoli
 Phagocytosed by macrophages
 Granulomatous inflammation
 CD4, CD8, NK cells inhibit growth

Immunosuppressed
Yeast proliferates/
disseminates
Immunocompetent Yeast produce small
Yeast eliminated
lung-lymph node complex
Remain dormant (latency)
Host asymptomatic
y p
Clinical Manifestations
 Lung


1/3 pts asymptomatic (abnormal CXR with single or multiple pulmonary nodules)
PNA (F, chest pain, SOB, productive cough)

CXR: lobar infiltrate, hilar LAD, pleural effusions, lung cavitations
 CNS

Subacute meningitis or meningoencephalitis
 Skin

Ulceration, cellulitis, abscess
 Prostate


Usually asymptomatic
Can serve as reservoir of infection
 Eye


Ocular p
palsies,, p
papilledema
p
Can lead to blindness


Optic neuritis
Cerebral edema 2/2 elevated ICPs
 Bone/joint (osteolytic lesion)
Diagnosis
 CSF
 Elevated opening pressure
 Mononuclear pleocytosis
 Elevated protein
 Decreased glucose (< 40mg/dl)
 Cryptococcal antigen
 Direct detection (India Ink)
 Spherical, narrow based, budding, encapsulated yeast
 50% of non
non-AIDS
AIDS pts, 80% of AIDS pts CNS positive
 Culture
 Growth 48-72 hours on laboratory media at 20-37o C
 Routine
R ti blood
bl d culture
lt
can d
detect
t t cryptococcemia
t
i (3
(3-7
7 days)
d )
 CSF fungal culture
Diagnosis
 Serology
 Cryptococcal polysaccharide antigen (sera and CSF)
 Latex agglutination and enzyme immunoassay
>90% sensitive and specific
CSF titer ≥ 1:4 positive
Titer ≥ 1:1024
-High burden of yeasts, poor host immunity, greater chance of
therapeutic
h
ffailure
l
Serial titers imprecise but can be used for disease follow-up
Can be negative in pulmonary disease
 Radiology
 No pathognomonic scan
 CT brain: cryptococcomas (single/multiple), hydrocephalus, gyral
enhancement
 50% of CT scans normal
 MRI brain: hyperintense clustered foci in basal ganglia or midbrain
 Follow-up scans may show worsening of lesions
 Represents enhancement by inflammation as yeast being eliminated
 Not necessarilyy treatment failure
Treatment: Drugs
 Amphotericin B
 Amphotericin B deoxycholate (0.7 mg/kg/day)
 Nephrotoxic
 Acute infusion rxn (F/C, N/V, SOB)
 Liposomal amphotericin B (Ambisome:3-6 mg/kg/day)
 Amphotericin B lipid complex (Abelcet:3-6
(Abelcet:3 6 mg/kg/day)
 Flucytosine (100 mg/kg/day) (FC)
 MIC ≥ 128 g/ml associated with treatment failure
 Drug resistance as monotherapy
 Monitor for cytopenias
 2hr post-dose level 30-80 g/ml 3-5 days after initiation of treatment
 Fluconazole (200-1200 mg/day)
 MIC ≥ 16 g/ml
g/ml associated with treatment failure
 Resistance emerging problem when used as monotherapy (Africa)
Treatment: HIV
 Induction phase
 Amphotericin B + FC x 2 weeks
 Continue up to 6 weeks if pt sx (AMS),
(AMS) persistent increased
ICP, CSF culture remains positive
 Consolidation phase
p
 Fluconazole 400 mg Qday (6 mg/kg) x 8 weeks
 Suppressive phase
 Fluconazole 200 mg Qday
 Initiate HAART 2-10 weeks after commencement of initial
antifungal treatment
 Stop if CD4+ > 100 cells/l, VL ND x ≥ 3 months, CrAG
negative, minimum 12 mos of antifungal therapy
 Reinstitute maintenance therapy if CD4+ < 100 cells/l or
C A iincreases
CrAg
 Primary antifungal prophylaxis not recommended
IDSA Guidelines, 2010
Treatment: Organ Transplant
 Induction phase
 Amphotericin B + FC x 2 weeks
 Consolidation phase
 Fluconazole 400 mg-800 mg Qday (6 mg/kg) x 8 weeks
 Suppressive phase
 Fluconazole 200-400 mg Qday x 6-12 months
 Reduce immunosuppressants
 Lower prednisone to < 20 mg/day
IDSA Guidelines, 2010
Treatment: Normal
 Induction phase
 Amphotericin B + FC x 4 weeks
 No neurological
l
l complications
l
 CSF culture results negative after 2 weeks of treatment
 Extend treatment to 6 weeks if neurological complications
 If low-risk for therapeutic failure can shorten treatment to 2
weeks
 Consolidation phase
 Fluconazole 400 mg Qday (6 mg/kg) x 8 weeks
 Suppressive phase
 Fluconazole 200 mg Qday x 6-12 months
IDSA Guidelines, 2010
Elevated ICP
 Seen in ~ 50% of HIV infected patients
 Linked to high burden of yeast in CSF
 Opening CSF pressure ≥ 25 cm H2O + symptoms
 CSF drainage to reduce OP by 50% or to ≤ 20 cm H2O
 Repeat LP daily until CSF pressure and sx stabilized for > 2 days
 Consider placement of temporary CSF shunt or lumbar drain
IDSA Guidelines, 2010
Treatment in Resource-Limited
S tti
Settings
 Induction/Consolidation
 Amphotericin B (1 mg/kg/day) x 2 weeks -> fluconazole (800
mg/day) x 8 weeks
 Amphotericin B (0.7 mg/kg/day) + fluconazole (800 mg/day) x 2
weeks -> fluconazole (800 mg/day) x 8 weeks
 Fluconazole (1200 mg/day) + FC (100 mg/kg/day) x 2-10 weeks
 Fluconazole (1200 mg/day) x 10-12 weeks
 Maintenance
M i t
 Fluconazole 200-400 mg/day
 Open-labeled
p
RCT in Malawi ((2008))
 HIV positive adults (mean CD4+ count 21 cells/l, VL 99,000 cells/ml)
with first episode of cryptococcal meningitis
 Patients with ANC < 500, plt < 50K, ALT > 200, or on ART excluded
 Randomized to fluconazole (1200 mg/day) (n
(n=20)
20) vs fluconazole + FC
(100 mg/kg/day) (n=21) x 14 days -> 800 mg fluconazole Qday
 ART started after 4 weeks of antifungal therapy
 Monitored LP at t =0, 1, 3, 7, 14 days
 More frequent LP if OP > 30 cm H2O (mean OP at baseline 34 cm H2O)
 Followed LFTs, creatinine, CD4+ cells, HIV VL at baseline, LFTS and
cbc at weeks 1,2,4,6,10.
 Primary outcome: mean rate of decrease in CSF cryptococcal counts
 Secondary
S
d
outcomes:
t
serious
i
adverse
d
events,
t d
drug S/E
S/E, mortality
t lit att 2
& 10 weeks
Results/Conclusions
Fungicidal Activity: High-dose
fluconazole + FC > than high
high-dose
dose
fluconazole alone (p< 0.001).
Four patients in combination arm and
one in monotherapy arm had sterile
cultures
lt
att D14
D14.
10%
37%
43%
58%
Survival: Trend toward improved survival at 2 and 10 weeks among patients
who received combination therapy.
Results/Conclusions
Safety: Combination regimen safe w/o
monitoring
g FC levels
Limitations:
-FC not available in most of developing world, including Africa
-Underpowered to detect mortality benefit
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yp
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g
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