Q fever endocarditis: diagnostic approaches and monitoring of therapeutic effects

Summary The scope of current diagnostic methods for Q fever endocarditis includes serology, direct demonstration of Coxiella burnetii in the resected heart valve tissue, and animal inoculation studies. Illustrated by a clinical case report, the different methods are presented and discussed. Serology represents the primary method, using the techniques of complement fixation, indirect immunofluorescence, and enzyme-linked immunosorbent assay (ELISA). The latter two techniques allow the detection of immunoglobulins G, M, and A to the phase I and II antigens of C. burnetii. After cardiac surgery, we visualized C. burnetii on smears and specifically stained it on histologic sections of the resected heart valve by light and electron microscopic immunohistochemistry. In addition, seroconversion in animals after inoculation with valve specimens confirmed the presence of C. burnetii in the heart valve. The antibody titers determined by ELISA correlated well with the patient's clinical course during the treatment period. Therefore it is suggested that its usefulness for monitoring the efficacy of antimicrobial agents in patients with Q fever endocarditis should be further evaluated.Abbreviations IFA indirect fluorescent antibody test - ELISA enzyme-linked immunosorbent assay - CF complement fixation - TMP/SMX trimethoprim/sulfamethoxazole - CDC Center for Disease Control - PAP peroxidase-antiperoxidase - PBS phosphate-buffered saline     

Acute Acalculous Cholecystitis Associated with Q Fever: Report of Seven Cases and Review of the Literature

Q fever is a worldwide-occurring zoonosis caused by Coxiella burnetii. There are various clinical manifestations of acute Q fever, of which acute cholecystitis is a very rare clinical presentation. This study reports seven cases of acute cholecystitis associated with Coxiella burnetii and reviews two other cases from the literature. All patients were admitted to hospital for fever and abdominal pain in the right upper quadrant. Abdominal echography showed a distended gallbladder with biliary sludge without concrements in eight cases and with a single stone in one case. Diagnosis was made by specific serological investigation (microimmunofluorescence assay) for Coxiella burnetii. All nine patients were cured, six after laparoscopic cholecystectomy and three with antibiotics only. Histological examination of the gallbladders showed inflammation in five cases, although Coxiella burnetii was not detected by immunohistochemistry. The results show that laboratory investigations in patients admitted to hospital for symptoms consistent with acute acalculous cholecystitis should include a systematic search for Coxiella burnetii. Electronic Publication     

Coxiella burnetii infection among subjects infected with HIV type 1 in the Central African Republic

Sixty-six sera from HIV-1-seropositive adult African subjects and 49 sera from HIV-seronegative age and sex matched healthy African controls living in Bangui, Central African Republic, were screened forCoxiella burnetii antibody by an indirect immunofluorescent antibody test. 16.7 % of HIV-infected patients and 16.3 % of the HIV-negative controls had positive IgG titres, with no significant difference between the two groups. Two of the seven HIV-infected patients seropositive forCoxiella burnetii for whom clinical data was available had a medical history compatible with symptomatic Q fever. These findings indicate that there is a high degree of exposure toCoxiella burnetii infection in Bangui. In individuals co-infected with HIV andCoxiella burnetii, cellular immunosuppression could favour symptomatic Q fever. Physicians should be aware of the possibility of symptomaticCoxiella burnetii infection among HIV-infected people, particularly in endemic regions for both infections such as in sub-saharan Africa.     

Conventional viral cultures and shell vial assay for diagnosis of apparently culture-negativeCoxiella burnetii endocarditis

A patient with culture-negative endocarditis was diagnosed with Q fever endocarditis based on the results of serological tests and positive leukocyte cultures obtained using conventional viral cultures and the shell vial technique. This case report suggests that isolation ofCoxiella burnetii from blood may allow better diagnostic and therapeutical evaluation of patients with Q fever endocarditis. The use of both conventional and shell vial viral cultures is recommended for the isolation ofCoxiella burnetii from the blood of patients with apparently culture-negative endocarditis.     

Lack of pathotype specific gene in human Coxiella burnetii isolates

Human Q fever, due to the obligate intracellular bacterium Coxiella burnetii may be acute or chronic. The acute form is rarely fatal, although the chronic form, mostly represented by chronic Q fever endocarditis, is severe and usually fatal in lack of appropriate treatment. A correlation between the human disease state and plasmid types has been described, and specific DNA sequences unique to each plasmid type and which would code for specific pathotypes have been characterized. Because this gene specificity of the pathogenesis was hypothesized only on a small number of isolates, we evaluated seven reference isolates and 30 recent C. burnetii isolates from France for which all clinical data were available using the polymerase chain reaction by employing two specific primer sets. Our studies indicate that the previously described CbhE′ plasmid-gene is not unique to C. burnetii isolates associated with acute disease, which would mean that the hypothesis of the correlation between gene specificity and pathotype has to be revised.     

Emergence of Q Fever Arthritis in France

Osteoarticular infection is an uncommon presentation of Q fever. Positron emission tomography (PET) scanning is a valuable tool for the diagnosis of Coxiella burnetii graft prosthesis infection and endocarditis. Our objective was to test a series of culture-negative osteoarticular samples using molecular assays for Coxiella burnetii. We tested for C. burnetii by molecular assays targeting the IS1111 and the IS30A spacer regions, using culture-negative osteoarticular samples obtained in our laboratory between January 2011and December 2012. We examine a total of 1,410 osteoarticular samples, and we observed two cases of arthritis and subacromial bursitis caused by C. burnetii. The infections were localized using PET scanning, and the diagnosis was confirmed through serology. For one, a C. burnetii strain with a multispacer sequence type 8 genotype was isolated from synovial fluid culture. Q fever articular infections could be undiagnosed because of the long evolution of articular attack, and patients with high antibody titers against C. burnetii should be tested using PET scanning to localize the site of infection.     

Immunological arousal during acute Q fever infection

Physicians often encounter patients who present with a vague clinical syndrome. A wide serological workup is often ordered, which may include tests for Coxiella burnetii in endemic areas. Often, the results of these tests pose new dilemma, with overlapping positive laboratory assays. The objective of this investigation was to characterise the serological overlap between acute Q fever and other infectious and immunological diseases. We retrospectively scanned the files of patients with a positive or equivocal immunoglobulin (Ig) M for C. burnetii phase II over a period of 8 years in a general hospital. Clinical and laboratory data, including antibodies to infectious agents and antibodies related to immunological states, were recorded. Anti-nuclear antibody (ANA), smooth muscle antibody (SMA) and rheumatoid factor were positive in 38%, 33.3% and 22.2% of the cases, respectively. In patients with acute Q fever, elevated IgM levels for Epstein–Barr Virus (EBV), cytomegalovirus (CMV), Mycoplasma pneumoniae, parvovirus, Bordetella pertussis, Rickettsia conorii and R. typhi were noted in 13.8%, 8.3%, 12.12%, 22.2%, 25%, 13% and 21.7% of cases, respectively. Acute Q fever induces a non-specific immunological arousal in a significant number of patients. This may interfere with diagnosis and delay treatment. Caution, clinical judgment and serological follow-up is warranted in such conditions.     

Comparison of ELISA and indirect immunofluorescent antibody assay detecting <Emphasis Type="Italic">Coxiella burnetii</Emphasis> IgM phase II for the diagnosis of acute Q fever

A commercially available enzyme-linked immunosorbent assay (ELISA) detecting Coxiella burnetii phase II-specific IgM for the diagnosis of acute Q fever was compared with indirect immunofluorescent antibody assay (IFA). IFA is the current reference method for the detection of antibodies against C. burnetii, but has disadvantages because the judgment of fluorescence is subjective and tiring, and the test is expensive and automation is not possible. To examine whether phase II IgM ELISA could be used as a screening assay for acute Q fever, we compared the sensitivity and specificity of IFA and ELISA. The sensitivity of the IFA and ELISA tests were 100 and 85.7%, respectively, with a specificity of 95.3 and 97.6%, respectively. Because of the high sensitivity and specificity of the ELISA in combination with the practical disadvantages of the IFA, we introduced a new algorithm to screen samples of patients with symptoms of acute Q fever infection.     

Real-Time PCR with Serum Samples Is Indispensable for Early Diagnosis of Acute Q Fever

The world''s largest Q fever outbreak is ongoing in The Netherlands with around 3,000 confirmed cases since the first half of 2007. Increased awareness has resulted in early referral of patients for diagnostics. An important drawback to serological diagnosis of acute Q fever is the lag phase in antibody response. Therefore, we evaluated the performance of a real-time PCR for detection of Coxiella burnetii DNA using serum samples from patients with acute Q fever. PCR, targeting IS1111, was retrospectively performed on acute-phase and follow-up convalescent-phase serum samples from 65 patients with acute Q fever as diagnosed by immunofluorescence assay. The results obtained by PCR were related to disease stage as defined by subsequent appearance of phase II IgM, phase II IgG, phase I IgM, and phase I IgG (IgM-II, IgG-II, IgM-I, and IgG-I, respectively) antibodies and time since onset of disease. In addition, we analyzed seronegative acute-phase serum samples from patients with inconclusive Q fever serology, because no convalescent-phase serum samples were available. PCR was scored positive in 49/50 (98%) seronegative sera, 9/10 (90%) sera with isolated IgM-II antibodies, 3/13 (23%) sera with IgM-II/IgG-II antibodies, 2/41 (5%) sera with IgM-II/IgG-II/IgM-I antibodies, 0/15 (0%) sera with IgM-II/IgG-II/IgM-I/IgG-I antibodies, and 0/1 (0%) serum sample with IgM-II/IgG-II/IgG-I antibodies. The latest time point after onset of disease in which C. burnetii DNA could be detected was at day 17. In patients with inconclusive Q fever serology, PCR was positive in 5/50 (10%) cases. We conclude that real-time PCR with serum samples is indispensable for early diagnosis of acute Q fever. C. burnetii DNA becomes undetectable in serum as the serological response develops.Q fever, an infection caused by the bacterium Coxiella burnetii, results in a self-limiting disease in 40 to 50% of infected cases. Pneumonia is the predominant presenting symptom in acute Q fever, although fever and hepatitis are also frequently observed (9, 10). Failure to diagnose acute Q fever and delay in treatment may lead to prolonged morbidity and increased hospital admission rates (4, 7, 11, 14).During three consecutive years, large Q fever epidemics occurred in an area in the south of The Netherlands where the disease was formerly not prevalent (11). In 2007 there were a total of 191 confirmed cases reported, in 2008 a total of 998, and in 2009 more than 2,000 confirmed cases were reported, which ranks the outbreak as the largest Q fever epidemic recorded to date. The affected area has a large density of dairy goats, of which a number have tested positive for Q fever. Next to the differences in sizes of the epidemics, the interval between onset of disease and date of diagnosis decreased from a median of 77 days in 2007 to 29 days in 2008 and 17 days in 2009 (12). Moreover, the hospital admission rates were reduced from 40% in 2007 to 20% in 2008 (11). Both observations are most likely due to increased awareness among physicians in the affected area resulting in early submission of clinical samples to the laboratory, subsequent earlier diagnosis, and probably fewer undiagnosed cases. The majority of diagnostic samples from both epidemics were submitted to our laboratory, which lies in the center of the epidemic area and serves a catchment area of roughly 500,000 persons in a semirural district supporting two hospitals and surrounding general practitioners.The gold standard for serological diagnosis of an infectious disease is either a seroconversion or a 4-fold rise in antibody titer. The reference test for serological diagnosis of Q fever is the immunofluorescence assay (IFA) (8). Antibodies are expressed against phase II antigens during the acute infection and against phase I antigens in the established infection. For both antigens, IgM antibody production precedes IgG production, and thus three phases can be distinguished in acute Q fever: a seronegative phase followed by IgM/IgG phase II seroconversion during the acute infection and subsequent IgM/IgG phase I seroconversion in the established infection. However, an important drawback to serological diagnosis of acute Q fever is the lag phase in antibody response of 7 to 15 days after onset of clinical symptoms (8).Apart from serology, C. burnetii-specific PCR of serum samples can be an additional tool to diagnose Q fever in the early acute phase, but conflicting sensitivities have been reported (3, 13). Here, we evaluated the performance of an in-house-developed real-time PCR assay for detection of C. burnetii DNA in serum samples from patients with acute Q fever.     

Q fever and lymphadenopathy: report of four new cases and review

Coxiella burnetii, the causative agent of Q fever, is responsible for various clinical syndromes, but lymphadenitis has been described during Q fever in only three recent case reports. Four new cases of acute Q fever associated with lymphadenopathy are reported here, and these cases are discussed along with the three previously reported cases. Coxiella burnetii was isolated for the first time from a lymph node. Q fever should be considered an etiologic agent of lymphadenitis.     

Long-term serological follow-up after primary Coxiella burnetii infection in patients with vascular risk factors for chronic Q fever

We evaluated the long-term serological follow-up of patients with vascular risk factors for chronic Q fever that were previously Coxiella burnetii seropositive. C. burnetii phase I IgG titers were reevaluated in patients that gave informed consent or retrospectively collected in patients already deceased or lost to follow-up. Of 107 patients, 25 (23.4%) became seronegative, 77 (72.0%) retained a profile of past resolved Q fever infection, and five (4.7%) developed chronic Q fever. We urge clinicians to stay vigilant for chronic Q fever beyond two years after primary infection and perform serological testing based on clinical presentation.

     

Dysregulation of Serum Gamma Interferon Levels in Vascular Chronic Q Fever Patients Provides Insights into Disease Pathogenesis

A large community outbreak of Q fever occurred in the Netherlands in the period 2007 to 2010. Some of the infected patients developed chronic Q fever, which typically includes pathogen dissemination to predisposed cardiovascular sites, with potentially fatal consequences. To identify the immune mechanisms responsible for ineffective clearance of Coxiella burnetii in patients who developed chronic Q fever, we compared serum concentrations of 47 inflammation-associated markers among patients with acute Q fever, vascular chronic Q fever, and past resolved Q fever. Serum levels of gamma interferon were strongly increased in acute but not in vascular chronic Q fever patients, compared to past resolved Q fever patients. Interleukin-18 levels showed a comparable increase in acute as well as vascular chronic Q fever patients. Additionally, vascular chronic Q fever patients had lower serum levels of gamma interferon-inducible protein 10 (IP-10) and transforming growth factor β (TGF-β) than did acute Q fever patients. Serum responses for these and other markers indicate that type I immune responses to C. burnetii are affected in chronic Q fever patients. This may be attributed to an affected immune system in cardiovascular patients, which enables local C. burnetii replication at affected cardiovascular sites.     

Chronic Q Fever in the Netherlands 5 Years after the Start of the Q Fever Epidemic: Results from the Dutch Chronic Q Fever Database

Coxiella burnetii causes Q fever, a zoonosis, which has acute and chronic manifestations. From 2007 to 2010, the Netherlands experienced a large Q fever outbreak, which has offered a unique opportunity to analyze chronic Q fever cases. In an observational cohort study, baseline characteristics and clinical characteristics, as well as mortality, of patients with proven, probable, or possible chronic Q fever in the Netherlands, were analyzed. In total, 284 chronic Q fever patients were identified, of which 151 (53.7%) had proven, 64 (22.5%) probable, and 69 (24.3%) possible chronic Q fever. Among proven and probable chronic Q fever patients, vascular infection focus (56.7%) was more prevalent than endocarditis (34.9%). An acute Q fever episode was recalled by 27.0% of the patients. The all-cause mortality rate was 19.1%, while the chronic Q fever-related mortality rate was 13.0%, with mortality rates of 9.3% among endocarditis patients and 18% among patients with a vascular focus of infection. Increasing age (P = 0.004 and 0.010), proven chronic Q fever (P = 0.020 and 0.002), vascular chronic Q fever (P = 0.024 and 0.005), acute presentation with chronic Q fever (P = 0.002 and P < 0.001), and surgical treatment of chronic Q fever (P = 0.025 and P < 0.001) were significantly associated with all-cause mortality and chronic Q fever-related mortality, respectively.     

Molecular detection of Coxiella burnetii in the sera of patients with Q fever endocarditis or vascular infection

In the absence of a specific diagnosis based on serology, chronic Q fever is inevitably fatal. However, diagnosis is often delayed because the test is not widely available. To shorten the diagnostic delay, we adapted a nested-PCR assay with serum as a template and the LightCycler as a thermal cycler, termed LCN-PCR. We retrospectively and prospectively applied this method to samples from 48 patients diagnosed with Q fever endocarditis or vascular infection and to samples from 100 controls with endocarditis caused by other microorganisms. We also prospectively applied this technique to samples from 30 patients treated for a Q fever endocarditis and to samples from 13 patients with a convalescent acute Q fever with ambiguous immunoglobulin G (IgG) phase I titer. LCN-PCR had a specificity of 100%. It was positive only in samples from patients with evolutive Q fever, as none of the samples from patients with a treated chronic Q fever or with a convalescent acute Q fever presented positive results. When performed prospectively on recently stored sera, the sensitivity of LCN-PCR is 64% (7 of 11 samples; P = 0.004), but the efficiency of LCN-PCR was dramatically altered by the storage of specimens at -20 degrees C. High IgG phase I titers decreased the sensitivity of LCN-PCR. A significant difference was observed among LCN-PCR results for sera with IgG phase I titers of > or =1:25,600 compared to sera with IgG phase I titers of <1:25,600 (0 of 15 samples versus 13 of 33 samples; P = 0.004). In patient samples with titers below 1:25,600 tested prospectively, sensitivity was 100% (7 of 7). The LCN-PCR assay may be helpful in establishing an early diagnosis of chronic Q fever.     

Q fever endocarditis in India: A report of two cases

Q fever is a zoonotic disease caused by the obligate intracellular bacterium Coxiella burnetii. Infective endocarditis is the most common form of chronic Q fever. Diagnosis of Q fever is difficult, as there are no pathognomonic symptoms. Methods of isolation of the organism in culture are tedious, hence serological and molecular techniques remain the mainstay of diagnosis. We report two cases of Q fever endocarditis diagnosed by IFA and real-time PCR.     

Reactivation of Q fever following cardiac surgery

To determine whether reactivation of Q fever occurs following cardiac surgery 43 patients who had antibodies toCoxiella burnetii were identified pre-operatively. Serum samples were collected 1, 4 to 6, and 24 weeks post-operatively. One patient had active Q fever endocarditis. Seven of the remaining 42 (17 %) had a fourfold rise in titres for antibodies toCoxiella burnetii post-operatively. Only two of these seven had an increase in antibody titres for other agents suggesting that the fourfold titre rise forCoxiella burnetii was not part of a polyclonal response. It is concluded that self-limited reactivation of infection may occur amongCoxiella burnetii seropositive patients undergoing open heart surgery.     

High Coxiella burnetii DNA Load in Serum during Acute Q Fever Is Associated with Progression to a Serologic Profile Indicative of Chronic Q Fever

PCR is very effective in diagnosing acute Q fever in the early stages of infection, when bacterial DNA is present in the bloodstream but antibodies have not yet developed. The objective of this study was to further analyze the diagnostic value of semiquantitative real-time PCR (qPCR) in diagnosing acute Q fever in an outbreak situation. At the Jeroen Bosch Hospital, in 2009, qPCR testing for Coxiella burnetii DNA was performed for 2,715 patients suspected of having acute Q fever (positive, n = 385; negative, n = 2,330). The sensitivity, specificity, positive predictive value (PPV), and negative predictive value (NPV) of the qPCR assay were calculated for patients with negative qPCR results with a follow-up sample obtained within 14 days (n = 305) and qPCR-positive patients with at least one follow-up sample (n = 369). The correctness of the qPCR result was based on immunofluorescence assay results for samples submitted for qPCR and follow-up testing. The sensitivity of the Q fever qPCR assay was 92.2%, specificity 98.9%, PPV 99.2%, and NPV 89.8%. Patients who later developed serologic profiles indicative of chronic Q fever infection had significantly higher C. burnetii DNA loads during the acute phase than did patients who did not (P < 0.001). qPCR testing is a valuable tool for the diagnosis of acute Q fever and should be used in outbreak situations when the onset of symptoms is <15 days earlier. Special attention is needed in the follow-up monitoring of patients with high C. burnetii DNA loads during the acute phase, as this might be an indicator for the development of a serologic profile indicative of chronic infection.     

Evaluation of Commonly Used Serological Tests for Detection of Coxiella burnetii Antibodies in Well-Defined Acute and Follow-Up Sera

In this study, we compared Coxiella burnetii IgG phase I, IgG phase II, and IgM phase II detection among a commercially available enzyme-linked immunosorbent assay (ELISA) (Virion/Serion), an indirect fluorescent antibody test (IFAT) (Focus Diagnostics), and a complement fixation test (CFT) (Virion/Serion). For this, we used a unique collection of acute- and convalescent-phase sera from 126 patients with acute Q fever diagnosed by positive Coxiella burnetii PCR of blood. We were able to establish a reliable date of onset of disease, since DNA is detectable within 2 weeks after the start of symptoms. In acute samples, at t = 0, IFAT demonstrated IgM phase II antibodies in significantly more sera than did ELISA (31.8% versus 19.7%), although the portion of solitary IgM phase II was equal for IFAT and for ELISA (18.2% and 16.7%, respectively). Twelve months after the diagnosis of acute Q fever, 83.5% and 62.2% of the sera were still positive for IgM phase II with IFAT and ELISA, respectively. At 12 months IFAT IgG phase II showed the slowest decline. Therefore, definitive serological evidence of acute Q fever cannot be based on a single serum sample in areas of epidemicity and should involve measurement of both IgM and IgG antibodies in paired serum. Based on IgG phase II antibody detection in paired samples (at 0 and 3 months) from 62 patients, IFAT confirmed more cases than ELISA and CFT, but the differences were not statically significant (100% for IFAT, 95.2% for ELISA, and 96.8% for CFT). This study demonstrated that the three serological tests are equally effective in diagnosing acute Q fever within 3 months of start of symptoms. In follow-up sera, more IgG antibodies were detected by IFAT than by ELISA or CFT, making IFAT more suitable for prevaccination screening programs.     

The sexual dimorphism of anticardiolipin autoantibodies in acute Q fever patients

ObjectivesQ fever is a zoonotic disease caused by Coxiella burnetii which affects men more than women (sex ratio men/women: 2.2). Acute Q fever complications are associated with elevation of anticardiolipin (aCL) antibodies. Here, we investigate the sexual dimorphism of aCL antibodies during acute C. burnetii infection.MethodsIgG aCL antibodies were evaluated at the time of Q fever serological diagnosis with enzyme-linked immunosorbent assay. Results were analysed according to sex.ResultsAmong the 1323 patients with Q fever tested for aCL, 1013 had acute Q fever (692 men/321 women) and 310 had persistent focalized infection (226 men/84 women). In cases of acute Q fever, men presented a significantly higher proportion of positive aCL antibodies (351/692, 50.7%) than women (113/321, 35.2%) (p <0.05). In addition, men had significantly higher aCL antibodies levels than women (p <0.001).ConclusionsWe highlight a relationship between sex and markers of autoimmunity during Q fever. Further investigations are necessary to better understand the mechanisms of this sexual dimorphism.     

Fluorescence in situ hybridization for detecting Coxiella burnetii in tissue samples from chronic Q fever patients

ObjectiveDetection of the intracellular bacterium Coxiella burnetii, causative agent of chronic Q fever, is notoriously difficult. Diagnosis of and duration of antibiotic treatment for chronic Q fever is partly determined by detection of the bacterium with polymerase chain reaction (PCR). Fluorescence in situ hybridization (FISH) might be a promising technique for detecting C. burnetii in tissue samples from chronic Q fever patients, but its value in comparison with PCR is uncertain. We aim to assess the value of FISH for detecting C. burnetii in tissue of chronic Q fever patients.MethodsFISH and PCR were performed on tissue samples from Dutch chronic Q fever patients collected during surgery or autopsy. Sensitivity, specificity, and overall diagnostic accuracy were calculated. Additionally, data on patient and disease characteristics were collected from electronic medical records.ResultsIn total, 49 tissue samples from mainly vascular walls, heart valves, or placentas, obtained from 39 chronic Q fever patients, were examined by FISH and PCR. The sensitivity and specificity of FISH compared to PCR for detecting C. burnetii in tissue samples from chronic Q fever patients was 45.2% (95% confidence interval (CI), 27.3% – 64.0%) and 84.6% (95% CI, 54.6% – 98.1%), respectively. The overall diagnostic accuracy was 56.8% (95% CI, 42.2% - 72.3%). Two C. burnetii PCR negative placentas were FISH positive. Four FISH results (8.2%) were deemed inconclusive because of autofluorescence.ConclusionWith an overall diagnostic accuracy of 57.8%, we conclude that FISH has limited value in the routine diagnostics of chronic Q fever.