Murine typhus is a disease caused by Rickettisa typhi, an obligate intracellular bacterium transmitted by rodent fleas. The disease has a worldwide distribution; however the true burden is unknown, related to its non-specific presentation and lack of access to diagnosis in many regions. A systematic review of untreated murine typhus based on observational studies of a total of 239 patients has estimated the mortality associated with the disease at between 0.4% and 3.6%. Scrub typhus is caused by Orientia tsutsugamushi and transmitted by the larval stage of chigger mites (Trombiculidae family). It has been estimated to affect at least one million people each year. A systematic review found varying reports of the mortality associated with untreated scrub typhus ranging from 0-70% (median 6%). Polymerase chain reaction (PCR) based diagnosis of rickettsial infections is only available in one centre (Mahosot Hospital) in Vientiane. A number of hospitals use a variety of point-of-care antibody tests to diagnose rickettsial infections however many of these have not been validated and they are of uncertain sensitivity and specificity. In 2006 results of a two year prospective study of 427 patients presenting to Mahosot Hospital with a febrile illness and negative blood cultures showed that 115 (27%) patients had an acute rickettsial infection, confirmed by serological testing. Among these patients, 41 were diagnosed with murine typhus and 63 with scrub typhus. Antibacterial agents with activity against rickettsial pathogens include doxycycline, azithromycin, chloramphenicol and rifampicin. Azithromycin is often reserved for pregnant women or children below the age of 8 years due to lasting concerns after the tetracycline-associated staining of growing bones and teeth in the past. Evidence is accumulating that doxycycline is superior to azithromycin for the treatment of rickettsial disease. Clinical treatment failures have occurred following azithromycin treatment of murine typhus. The relationship between rickettsial bacteria load and both disease severity and response to treatment has not been characterised. Rickettsial concentrations in blood are generally low, of the order of 210 DNA copies/mL blood for R. typhi and 284 DNA copies/mL blood for O. tsutsugamushi. At present, there is no standard antibiotic susceptibility testing (AST) method for R. typhi and O. tsutsugamushi. The gold standard method for AST for Rickettsia pathogens is the plaque assay which determines minimal inhibitory concentration (MICs) from the smallest antimicrobial concentration inhibiting rickettsial plaque forming unit formation. This method is laborious and time consuming, taking approximately 14-16 days based on species to yield a result. Molecular detection methods are useful for diagnosing patients infected with rickettsial pathogens and has been applied for antibiotic susceptibility testing. Antibiotic susceptibility testing based on DNA synthesis inhibition detecting by quantitative PCR (qPCR) for O. tsutsugamushi clinical isolates has been reported. However, the relationship between antibiotic susceptibility profiles and treatment response has not been studied. There is a need to develop a reliable ex vivo method to characterize the treatment response and compare susceptibility of R. typhi and O. tsutsugamushi to different agents.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
72
100-mg film-coated tablets; Pfizer
250-mg capsules; Pfizer
Lao-Oxford-Mahosot Hospital-Wellcome Trust Research Unit (LOMWRU)
Vientiane, Vientaine, Laos
RECRUITINGVientiane Provincial Hospital
Vientiane Province, Vientiane Province, Laos
RECRUITINGRate of clearance of R. typhi or O. tsutsugamushi from peripheral blood of patients using serial qPCR measurement
Measure of clearance or R. typhi or O. tsutsugamushi DNA assessed by serial qPCR measurements on the blood from murine typhus patients treated with either doxycycline or azithromycin. Rickettsia clearance rate will be estimated from serial qPCR measurement in each patient. The clearance rate is the slope of the initial log linear decline in qPCR estimated bacteria densities
Time frame: Within 72 hours after treatment
Area under the plasma concentration versus time curve (AUC) of doxycycline or azithromycin for the treatment of murine typhus or scrub typhus
AUC of doxycycline or azithromycin versus time from zero to infinity in the treatment of murine typhus and scrub typhus will be estimated using a modelling approach
Time frame: Doxycycline: Based on plasma concentrations measure up to 96 hours after the last dose. Azithromycin: Based on plasma concentrations measure up to 2 weeks after the first dose.
Area under the intracellular concentration in the buffy coat versus time curve (AUC) of doxycycline or azithromycin for the treatment of murine typhus or scrub typhus
AUC of doxycycline or azithromycin versus time from zero to infinity in the treatment of murine typhus and scrub typhus will be estimated using a modelling approach
Time frame: Doxycycline: Based on intracellular concentrations in the buffy coat measure up to 96 hours after the last dose. Azithromycin: Based on intracellular concentrations in Buffy coat measure up to 2 weeks after the first dose.
Peak plasma concentration (Cmax) of doxycycline or azithromycin for the treatment of murine typhus or scrub typhus
Cmax of doxycycline or azithromycin versus time from zero to infinity in the treatment of murine typhus and scrub typhus will be estimated using a modelling approach
Time frame: Doxycycline: Based on plasma concentrations measure up to 96 hours after the last dose. Azithromycin: Based on plasma concentrations measure up to 2 weeks after the first dose.
Peak of the intracellular concentration (Cmax) in the buffy coat of doxycycline or azithromycin for the treatment of murine typhus or scrub typhus
Cmax of doxycycline or azithromycin versus time from zero to infinity in the treatment of murine typhus and scrub typhus will be estimated using a modelling approach
Time frame: Doxycycline: Based on intracellular concentrations in the buffy coat measure up to 96 hours after the last dose. Azithromycin: Based on intracellular concentrations in the buffy coat measure up to 2 weeks after the first dose.
Time to peak plasma concentration (Tmax) of doxycycline or azithromycin for the treatment of murine typhus or scrub typhus
Tmax of doxycycline or azithromycin versus time from zero to infinity in the treatment of murine typhus and scrub typhus will be estimated using a modelling approach
Time frame: Doxycycline: Based on plasma concentrations measure up to 96 hours after the last dose. Azithromycin: Based on plasma concentrations measure up to 2 weeks after the first dose.
Time to peak of the intracellular concentration (Tmax) in the buffy coat of doxycycline or azithromycin for the treatment of murine typhus or scrub typhus
Tmax of doxycycline or azithromycin versus time from zero to infinity in the treatment of murine typhus and scrub typhus will be estimated using a modelling approach
Time frame: Doxycycline: Based on intracellular concentrations in the buffy coat measure up to 96 hours after the last dose. Azithromycin: Based on intracellular concentrations in the buffy coat measure up to 2 weeks after the first dose.
Time at doxycycline or azithromycin has lost half its maximum concentration (T1/2) for the treatment of murine typhus or scrub typhus
T1/2 of doxycycline or azithromycin versus time from zero to infinity in the treatment of murine typhus and scrub typhus will be estimated using a modelling approach
Time frame: Doxycycline: Based on plasma concentrations measure up to 96 hours after the last dose. Azithromycin: Based on plasma concentrations measure up to 2 weeks after the first dose.
Time at doxycycline or azithromycin has lost half its maximum intracellular concentration (T1/2) for the treatment of murine typhus or scrub typhus
T1/2 of doxycycline or azithromycin versus time from zero to infinity in the treatment of murine typhus and scrub typhus will be estimated using a modelling approach
Time frame: Doxycycline: Based on intracellular concentrations in the buffy coat measure up to 96 hours after the last dose. Azithromycin: Based on intracellular concentrations in the buffy coat measure up to 2 weeks after the first dose.
Fever clearance time in patients with scrub typhus or murine typhus treated with doxycycline or azithromycin
Fever clearance time is defined as the time in hours from onset of antibiotic treatment, to the first Axillary temperature recording less than or equal 37.5°C, which then remains less than or equal 37.5°C for 24 hours
Time frame: First 7 days after treatment
Frequency of serious adverse events (SAEs) after treatment
SAEs will be defined using the Common Toxicity Criteria (v5.0) of the US National Cancer Institute
Time frame: Day 0 to day 28
Evaluation the accuracy of the new brand RDT, Rickettsia IgG/IgM Combo (Lumiquick) compared to Scrub typhus Detect IgM Rapid System (Dipstick) (InBios)
Sensitivity and specificity of Rickettsia IgG/IgM Combo (Lumiquick) compared to Scrub typhus Detect IgM Rapid System (Dipstick) (InBios) will be compared
Time frame: Day 0
Evaluation the accuracy of Rickettsia IgG/IgM Combo (Lumiquick) compared to a combined gold standard of PCR assays and serology (paired samples)
Sensitivity and specificity of RDT (Lumiquick) result will be compared to a combined gold standard of PCR assays and serology (paired serum)
Time frame: Day 0 and Day 28
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