EECP-Role in management of heart failure
Download
Report
Transcript EECP-Role in management of heart failure
RICKETTSIAL INFECTION:
DIVERSITIES, DILEMMA AND
CHALLENGES
Dr. Moniruzzaman Ahmed
Associate Professor, Dept of Medicine
MAG Osmani Medical College, Sylhet
Rickettsial diseases - 4 distinct genera:
•Rickettsia, Orientia, Ehrlichia (Ehrlichia
chaffeensis, the agent of human
monocytic ecrlichiosis) and Anaplasma
(Anaplasma phagocytophilium, the
agent of human granulocytic
anaplasmosis)
•Diseases caused by Rickettsia and
Orientia species often reffered to as
rickettsioses
•Coxiella burnetii, the agent of Q fever
and Bartonella spp. were recently
removed from the order Rickettsiales
Parola P, Paddock CD, Raoult D. Tick-borne rickettsioses around the world: emerging diseases challenging old
concepts. Clin Microbiol Rev. 2005;18:719–56
RICKETTSIAL SPECIES-BIOVARS
SPOTTED FEVER GROUP RICKETTSIOSES (SFGR) /
TICK BORN RICKETTSIAL DISEASE (TBRD)
TYPHUS GROUP (TG)
SCRUB TYPHUS GROUP
RICKETTSIA- BIOLOGY
• Small obligate intracellular parasites
• Gram-negative bacteria
• Stain poorly with Gram stain
(Giemsa)
• “Energy parasites” but not obligate,
have capacity to make ATP
• Parasite of arthropods – fleas, lice,
ticks and mites
• Reservoirs - animals, insects and
humans
The genus Rickettsia is named after
Howard Taylor Ricketts (1871–1910),
who studied Rocky Mountain spotted
fever in the Bitterroot Valley
From 1906 to 1910, Howard T Ricketts
isolated the pathogen and showed that
it circulated among ticks and mammals
in the wild. Tragically, this talented
rickettsiologist
was
affected
by
epidemic typhus and died in 1910, at
the age of 39 years.
TRANSMISSION, PATHOGENESIS &
PATHOPHYSIOLOGY
SPOTTED FEVER GROUP RICKETTSIOSES (SFGR)/
TICK BORN RICKETTSIAL DISEASE(TBRD)
PROTYPICAL DISEASES (SFGR)/(TBRD)
ORGANISM
DISEASE
DISTRIBUTION
R.Rickettsii
Rocky Mountain spotted fever
Western hemisphere
R. akari
Rickettsialpox
USA, former Soviet Union
R. conorii
Boutonneuse fever, Kenya tick
typhus, Israeli tick typhus,
Mediterranean spotted
fever(MSF), Indian tick typhus,
Astrakhan tick typhus,
Marseilles fever
Mediterranean countries,
Africa, India, Southwest Asia
R. sibirica
Siberian tick typhus
Siberia, Mongolia, northern
China
R. australia
Australian tick typhus
Australia
R. japonica
Oriental spotted fever
Japan
GEOGRAPHICAL DISTRIBUTION
Update on Tick-Borne Rickettsioses around the World: a Geographic
Approach
Philippe Parola,a Christopher D. Paddock,b Cristina Socolovschi,a Marcelo B. Labruna,c Oleg Mediannikov,a Tahar Kernif,d
Mohammad Yazid Abdad,e* John Stenos,e Idir Bitam,f Pierre-Edouard Fournier,a Didier Raoulta
October 2013 Volume 26 Number 4 Clinical Microbiology Reviews p. 657–702
GEOGRAPHICAL DISTRIBUTION (South
America)
Update on Tick-Borne Rickettsioses around the World: a Geographic
Approach
Philippe Parola,a Christopher D. Paddock,b Cristina Socolovschi,a Marcelo B. Labruna,c Oleg Mediannikov,a Tahar Kernif,d
Mohammad Yazid Abdad,e* John Stenos,e Idir Bitam,f Pierre-Edouard Fournier,a Didier Raoulta
October 2013 Volume 26 Number 4 Clinical Microbiology Reviews p. 657–7
GEOGRAPHICAL DISTRIBUTION (EUROPE)
Update on Tick-Borne Rickettsioses around the World: a Geographic
Approach
Philippe Parola,a Christopher D. Paddock,b Cristina Socolovschi,a Marcelo B. Labruna,c Oleg Mediannikov,a Tahar Kernif,d
Mohammad Yazid Abdad,e* John Stenos,e Idir Bitam,f Pierre-Edouard Fournier,a Didier Raoulta
October 2013 Volume 26 Number 4 Clinical Microbiology Reviews p. 657–7
GEOGRAPHICAL DISTRIBUTION
Update on Tick-Borne Rickettsioses around the World: a Geographic
Approach
Philippe Parola,a Christopher D. Paddock,b Cristina Socolovschi,a Marcelo B. Labruna,c Oleg Mediannikov,a Tahar Kernif,d
Mohammad Yazid Abdad,e* John Stenos,e Idir Bitam,f Pierre-Edouard Fournier,a Didier Raoulta
October 2013 Volume 26 Number 4 Clinical Microbiology Reviews p. 657–7
GEOGRAPHICAL DISTRIBUTION
Update on Tick-Borne Rickettsioses around the World: a Geographic
Approach
Philippe Parola,a Christopher D. Paddock,b Cristina Socolovschi,a Marcelo B. Labruna,c Oleg Mediannikov,a Tahar Kernif,d
Mohammad Yazid Abdad,e* John Stenos,e Idir Bitam,f Pierre-Edouard Fournier,a Didier Raoulta
October 2013 Volume 26 Number 4 Clinical Microbiology Reviews p. 657–7
GEOGRAPHIC DISTRIBUTION
Geographic and temporal distribution of
rickettsioses is largely determined by their vectors
“One continent, one
rickettsia” an anachronism
pathogenic
tick-born
Prevalent throughout the world except Antarctica
Summary of prevalent Rickettsiae in Southeast Asia,their
reservoirs and vectors for disease transmission
Rickettsiae
Main reservoirs
Main vectors
Typhus group
Murine typhus (R.typhi)
Rats(Rattus rattus, Rattus
norvegicus, other Rattus sp.)
Xenopsylla cheopis
Scrub typhus (O. tsutsugamushi)
Rats (Rattus sp. and Bandicota sp.)
Trombiculid mites (Larval stage )
Spotted fever group
R.Honei
Rats ( Rattus sp. And Bandicota
indica.)
Ixodes granulatus, Ixodes sp.,
Rhipicephalus sp.
R. felis
Rats(Rattus sp) and shrews (Suncus
murinus)
Ctenocephalides orientis, C. felis
felis, X. cheopis
R. Conorii subsp. indica
Rats ( Rattus sp.)
R. sanguineus
R. helvetica
Unknown
Ixodes spp
R. japonica
Rats ( Rattus sp. And B. indica.)
Various species of animal ticks.
Domestic cats, dogs, cows and pigs.
Am. J. Trop. Med. Hyg., 91(3), 2014, pp. 451–460
Review Article: Rickettsial Infections in Southeast Asia: Implications for Local Populace
and Febrile Returned Travelers
Ar Kar Aung,* Denis W. Spelman, Ronan J. Murray, and Stephen Graves
Short Report: Serosurveillance of Orientia
tsutsugamushi and Rickettsia typhi in Bangladesh
Short Report: Serosurveillance of Orientia tsutsugamushi and Rickettsia typhi in Bangladesh
Rapeephan R. Maude,* Richard J. Maude, Aniruddha Ghose, M. Robed Amin, M. Belalul Islam, Mohammad Ali, M. Shafiqul Bari,
M. Ishaque Majumder, Ampai Tanganuchitcharnchai, Arjen M. Dondorp, Daniel H. Paris, Robin L. Bailey, M. Abul Faiz, Stuart D.
Blacksell, and Nicholas P. J. Day
Am. J. Trop. Med. Hyg., 91(3), 2014, pp. 580–583
An ongoing study in
Mymensingh Medical
College
A case series of 40
rickettsial infection in
MMCH found 60%
positive
for
scrub
typhus by using WeilFelix test
(Miah MT, Rahman S, Sarker
CN, Khan GK, Barman TK,
2007. Study on 40 cases of
Rickettsia. Mymensingh Med
J 16: 85–88)
A total of 155 clinically suspected
febrile patients were enrolled in
the study. Out of them, 136
(88%), 31 (23%) and 61 (43%)
were positive by Weil-Felix test,
ELISA and PCR respectively.
Out of the 61 PCR positive
products, 16 were sequenced in
Sapporo
Medical
University,
Japan where 13 were found to be
99.9% consistent with Rickettsia
felis.
Association of tick genera and rickettsial species
CLINICAL MANIFESTATIONS
•Clinical symptoms of tick-borne SFG rickettsioses begin 4 to 10
days after a bite and typically include fever, headache, muscle
pain, rash, local lymphadenopathy, and, for most of these
diseases, a characteristic inoculation eschar at the bite site
•Life-threatening manifestations : prolonged fever, renal failure,
myocarditis, meningoencephalitis, hypotension, ARDS, multiple
organ failure
ESCHAR (TACHE NOIRE)
A crusty necrotic lesion with or without a surrounding
erythematous halo which suggests the location of the vector bite
LAR
Lymphangitis may be present
in several rickettsioses
Half of the cases of R. sibirica
subsp.
mongolitimonae
infection present this sign
(rope-like
lymphangitis
between
the
inoculation
eschar and lymphadenitis)
the infection being termed
lymphangitis-associated rickettsiosis (LAR)
also present in infections
caused by R. heilongjiangensis
and R. africae
DEBONEL / TIBOLA /SENLAT
Two dominant signs characterize
this syndrome: an inoculation eschar
and regional lymphadenopathy
The occurrence of fever and rash
is rare.
DEBONEL/TIBOLA (Dermacentorborne
necrosis
erythema
lymphadenopathy/tick-borne
lymphadenopathy),
also
called
SENLAT (scalp eschar and neck
lymphadenopathy after tick bite)
when the tick bite affects only the
scalp
Produced by different species of
Rickettsia. The main etiological
agent is Rickettsia slovaca
TYPHUS GROUP
HISTORY AND HISTORICAL IMPACT OF TYPHUS
Europian history has been affected by Typhus epidemics from the the 15th through the 20th centuries, Pediculus humanus corporis
as having a more profound effect on human history than any other animal
Rickettsia prowazeki is isolated and identified by Da Rocha-Lima in 1916. Named in honor of H. T. Ricketts and L. von Prowazek,
both of whom contracted typhus in the course of their investigations and died
In 1829, the French clinician Louis clearly differentiated Typhus Fever from Typhoid Fever (Wolback et al., 1922)
Transmission of Epidemic Typhus by the body louse was first demonstrated experimentally by Nicolle and others (1909)
Early History. The first pestilence attributed to louse-borne typhus was the Athenian Plague of 430 B.C.
The Fifteen Century. An epidemic of louse-borne typhus struck the besieging army of Spanish and within a month had killed 17,000
of the original 25,000 soldiers.
The Sixteen Century. Western civilizations at that time regarded their God as a somewhat capricious tyrant, who either gave life or
took it. Having no recourse to medicine as a means of explaining their devastations, medieval man turned to spiritual and
metaphysical sources.
A number of so-called "Assize Epidemics" occurred in England at this time, most notably at Oxford in 1577 and Exeter in 1589. The
Oxford epidemic was of such import that the University there was closed for 30 years afterward.
The Seventeenth Century. In the Thirty Years War of 1618-1648 along with Plague and starvation, typhus was responsible for the
loss of 10,000,000 people in which only 350,000 men died in combat .
The Eighteenth Century. The 18th century was marred by many small epidemics of typhus
The Nineteenth Century. Napoleon Bonaparte's campaign against the Russians in 1812 Napoleon had organized his "Grande Armee",
numbering 600,000 well-seasoned troops -Only 90,000 French soldiers reached Moscow out of the original army of 600,000. The
great majority, possibly as high as 300,000, had died of Epidemic Typhus and dysentery.
Epidemic Typhus had helped defeat Napoleon and end his dreams of a French-ruled world.
Typhus was endemic in Russia with some 82,000 cases a year recorded before 1914
‘Either socialism will defeat the louse’, ‘or the louse will defeat socialism’; ‘All attention to this problem comrades!’ Lenin observed
The Twentieth Century. Nicolle's proof of the transmission of typhus by body lice in 1910
Insurance Company as saying that as many as twenty-five million cases of typhus occurred during the years 1918-1922 with
upwards of three million deaths.
To dehumanise the Jews the Nazi Propaganda Minister Joseph Goebbels declared: ‘These are no longer people…The task is not
humanitarian but surgical. Steps have to be taken here, and really radical ones tool. Otherwise Europe will perish from the Jewish
disease.’
HISTORY AND HISTORICAL IMPACT OF TYPHUS
Rickettsia prowazeki is isolated and identified by Da Rocha-Lima
in 1916. Named in honor of H. T. Ricketts and L. von Prowazek,
both of whom contracted typhus in the course of their
investigations and died
In 1829, the French clinician Louis clearly differentiated Typhus
Fever from Typhoid Fever (Wolback et al., 1922)
Transmission of Epidemic Typhus by the body louse was first
demonstrated experimentally by Nicolle and others (1909). Nicolle
received the Nobel Prize for his work on typhus in 1928.
Henrique da Rocha Lima and Stanislas von
Prowazeck
Charles Jules Henri Nicolle
HISTORY AND HISTORICAL IMPACT OF
TYPHUS
15th-19th century Epidemics in Europe as a result of war,
disaster, or in prisoners
The Sixteen Century The Oxford was closed for 30 years
The Seventeenth Century. In the Thirty Years War of 16181648 along with Plague and starvation, typhus was responsible for
the loss of 10,000,000 people in which only 350,000 men died in
combat
The Nineteenth Century. Only 90,000 French soldiers reached
Moscow out of the original army of 600,000. Epidemic Typhus had
helped defeat Napoleon and end his dreams of a French-ruled
world
HISTORY AND HISTORICAL
IMPACT OF TYPHUS
‘Either socialism will defeat the louse’, ‘or the louse will
defeat socialism’; ‘All attention to this problem
comrades!’ Lenin observed
To dehumanise the Jews the Nazi Propaganda Minister
Joseph Goebbels declared: ‘These are no longer Steps
have to be taken here, and really radical ones tool.
Otherwise Europe will perish from the Jewish disease.’
End of WWII, DDT for control
Discovery of Tetracycline and Chloramphenicol in late
1940
Delousing and Disinfection
In German soilders had to show
delousing certificates when on leave
Neither the queens nor the kings,
the lice shaped the history of
Europe
TYPHUS
Disease
Group
Disease
Agent
Vector
Animal
Reservoir
Typhus
Group
Epidemic
Typhus
R.
prowazekii
Human
body
louse
Humans,
Sylvatic
typhus
Murine
typhus
R. typhi
Flea
Fleas,
flying
squirells
Rat flea
(Xenopsy
Rats, cat,
mice
lla
cheopis)
Geographical
Distribution
Mountainous regions
of Africa, Asia, and
Central, north and
South America.
Tropical and
subtropical areas
Worldwide
EPIDEMIC TYPHUS
•
•
•
•
•
•
Incubation period approximately 1
week
Sudden onset of fever, chills, headache
and myalgia
Rash after one week
– Maculopapular
progressing
to
petechial or hemorrhagic
– First on trunk and spreads to
extremities (centrifugal spread)
Complications
– Myocarditis, stupor, delirium (Greek
“typhos” = smoke)
Recovery may take months, debilitating
Mortality rate can be high (60-70%) but
this may be because of the situation,
such as famine
Brill-Zinsser
Disease
•
•
•
The rickettsia can remain latent
and reactivate months or years
later, with symptoms similar to or
even identical to the original
attack of typhus, including a
maculopapular rash
Mild illness and low mortality rate.
Rash is rare
Rickettsia typhi - Murine or endemic typhus
• Occurs worldwide
• Vector - rat flea
– Bacteria in feces
• Reservoir - rats
– No transovarian
transmission
– Normal cycle - rat to flea to
rat
• Humans accidentally infected
• Incubation period 1 - 2 weeks
• Sudden onset of fever, chills,
headache and myalgia
• Rash in most cases begins on
trunk and spreads to
extremities (centrifugal
spread)
• Mild disease - resolves even if
untreated
SCRUB TYPHUS
SCRUB TYPHUS GROUP
Antigenic
group
Disease
Species
Vector
Animal
reservoir
Geographic
distribution
Scrub typhus
Scrub typhus
Orientiatsutsu
gamushi
Larval
mite(chigger)
Rodents
Asia-Pacific
region from
maritime Russia
and China to
Indonesia and
North Australia to
Afghanistan
Scrub typhus
Scrub Typhus
Orientia chuta Unknown
Unknown
Dubai
Isolation of a Novel Orientia Species (O. chuto sp. nov.)
from a Patient Infected in Dubai
Leonard Izzard,1,2 Andrew Fuller,3 Stuart D. Blacksell,4,5 Daniel H. Paris,4,5 Allen L. Richards,4,6,7
Nuntipa Aukkanit,4,5 Chelsea Nguyen,1 Ju Jiang,6 Stan Fenwick,2 Nicholas P. J. Day,4
Stephen Graves,1 and John Stenos1,2*
JOURNAL OF CLINICAL MICROBIOLOGY, Dec. 2010, p. 4404–4409 Vol. 48, No. 12
Scrub typhus
Orientia tsutsugamushi is the causative agent & transmitted to
humans through the bite of thrombiculid mites.
The chigger (larval) phase is the only stage that is parasitic on
animals or humans.
First described in china 318 AD, isolated in Japan in 1930
Disease of rural villages and suburban areas.
Term scrub is used because of the vegetation (terrain between
woods and clearing) that harbours the vector.
Scrub typhus is endemic in tsutsugamushi triangle which extends
from northern Japan, far eastern Russia in the north to the
Northern Australia in the south and pakistan in the west.
Estimated 1 billion people are at risk of scrub typhus and
estimated 1 million cases occur annually.
TSUTSUGAMUSHI TRIANGLE
TSUTSUGAMUSHI TRIANGLE
Clinical features-Scrub typhus
Incubation period - 1 to 3 weeks
Sudden onset of fever, chills, headache and myalgia
Maculopapular rash (spots and bumps)
Begins on trunk and spreads to extremities (centrifugal spread)
Commonest symptom high grade fever ,headache muscle pain
,cough, and GI symptoms
Severe disease in 2ND week.
Meningitis , meningo-encephalitis , deafness, pneumonia, ARDS,
MODS & myocarditis.
Reinfection & Relapses are seen due to variable immunity to
different strains
Mortality rates variable (1-15%)
ESCHAR
SYNDROMIC CLASSIFICATION OF RICKETTSIOSES
Syndromic classification of rickettsioses: an approach for clinical
Practice´l
varo A. Faccini-Marti´nez a, Lara Garci´a-A´ lvarez b, Marylin Hidalgo a, Jose´ A. Oteo b,*
International Journal of Infectious Diseases 28 (2014) e126–e139
SYNDROMIC CLASSIFICATION OF RICKETTSIOSES
Syndromic classification of rickettsioses: an approach for clinical
Practice´
lvaro A. Faccini-Marti´nez a, Lara Garci´a-A´ lvarez b, Marylin Hidalgo a, JoseInfectious Diseases 28 (2014) e126–e139
Laboratory Diagnosis
• Serologic assays (eg, indirect immunofluorescence,
complement fixation, indirect hemagglutination, latex
fixation, enzyme immunoassay, microagglutination) are
preferable to the nonspecific and insensitive Weil-Felix
test based on the cross-reactive antigens of Proteus
vulgaris strains
• Immunofluorescence assay (IFA) is currently considered
to be the reference serological method.
• Polymerase chain reaction (PCR) to detect rickettsiae in
blood or tissue provides promise for early diagnosis.
PCR testing and immunohistochemical staining of skin
specimen obtained by performing a biopsy may help
confirm the clinical diagnosis in patients with rash.
• The swabs of eschars may be used for molecular
detection of rickettsial infections when biopsies are
difficult to perform.
DILEMMA & CHALLENGES
DIAGNOSIS
A thorough history and knowledge of the distribution
of rickettsial agents and their vectors
evidence of exposure to vector
clinical features like fever, rash, eschar, headache and
myalgia
high index of suspicion are crucial factors
TREATMENT
Antibiotic
Indication
Dosage
Treatment
Doxycycline (standard
treatment of
rickettsosis)
Severe rickettsioses
(including pregnant
women and children)
Ideally intravenous
Adults or
children>45kg
Adults or children>45kg;100 mg twice a day
pregnant women(last trimester):100 mg twice a
day
Children<45kg;22 mg twice a day
Continued for 3 days
after symptoms has
resolved
Macrolides(josamycin,
clarythromycin and
azithrothromycin
Option for not severe
rickettsioses in children
and pregnant women
Josamycin:children 50 mg/kg twice a day,
pregnant women 1g/8hrly
Clarithromycin for children :15mg/kg twice a
day
Josamycin 5 days
Clarithromycin 7
days and
Azithromycin 3 days
Chloramphenicol
Alternative option in
severe rickettsioses
Azithromycin in children :10 mg /kg/day in 1
dose
Adults and pregnant (first and second
trimester); 60-75 mg/kg in4 divided doses
Children12-25 mg/kg every 6 hourly
5-10 days
Syndromic classification of rickettsioses: an approach for clinical
Practice´
lvaro A. Faccini-Marti´nez a, Lara Garci´a-A´ lvarez b, Marylin Hidalgo a, JoseInfectious Diseases 28 (2014) e126–e139
But however secure and wellregulated civilized life may
become; bacteria, protozoa,
viruses, infected fleas, lice,
ticks, mosquitoes, and bedbugs
will always lurk in the
shadows ready to pounce when
neglect, poverty, famine, or
war lets down the defenses.
Hans Zinsser
Rats, Lice and History (1934), 13-4.