Fan Hw

Significant changes of peripheral T lymphocyte subsets in patients with severe acute respiratory syndrome.

This report demonstrates that a rapid decrease of peripheral T cell subsets is a unique characteristic in patients with SARS during acute infection, although total white blood cell counts, red blood cell counts, and platelet counts remain relatively normal. In recovering patients, a rapid and dramatic restoration of peripheral T cell subsets was seen in the periphery. Although the underlying mechanism of the acute decrease of peripheral T cell subsets observed in patients with SARS during the acute stage remains unknown, this clinical characteristic can facilitate an earlier and more accurate diagnosis of SARS.

Brain Abscess Caused by Bacillus megaterium in an Adult Patient

Bacillus megaterium, a Gram-positive, aerobic, spore-forming, rod-shaped bacterium, has been found in widely diverse habitats and has been widely used as a source of recombinant protein in the industry.[1] With a cell length of up to 4 μm and a diameter of 1.5 μm, B. megaterium belongs to one of the largest known bacteria.[2] To the best of our knowledge, B. megaterium has not been reported as the cause of brain abscesses, and infections caused by this bacterium are rare. For example, in 2006, Ramos-Esteban et al. reported the case of a 23-year-old man who developed delayed onset of lamellar keratitis caused by B. megaterium after an eye surgery.[3] In addition, in 2011, Duncan and Smith reported a 25-year-old woman who had a primary cutaneous infection caused by this bacterium most likely through microabrasions in the skin.[4] Here, we reported a case of brain abscess caused by B. megaterium in a Chinese woman. On October 1, 2012, a 50-year-old woman with psoriasis was transferred to Peking Union Medical College Hospital (Beijing, China), with a 3-month history of fever and headache. She was in her usual state of health until July 2012, when she experienced a moderate (38–39°C) fever, right visual field defect, paralysis in the right extremities, headache, and vomiting. The patients medical history was notable for psoriasis, and she was treated with oral corticosteroids (unknown category and dosage) for 1 month in July 2012. A lumber puncture showed an intracranial pressure of 270 mmH2O, a white blood cell count of 2080/μl with 81.5% polymorphonuclear leukocytes, and elevated protein levels of 1.9 g/L in cerebrospinal fluid (CSF). The CSF culture was negative. A magnetic resonance image (MRI) of the brain demonstrated lumpy enhancing lesions of T1-weighted imaging hypointense signal and slight T2-weighted imaging hyperintense signals in the left parietal, temporal, and occipital lobes as well as the ventriculitis [Figure 1a]. A needle biopsy of the lesions in the parietal lobe demonstrated chronic inflammation with scattered multinucleated giant cells. The patient was diagnosed with an intracranial infection at the outside hospital and treated with cephalosporins, vancomycin, fluconazole, and amphotericin for 1 month. Her health deteriorated with recurrent fever and headache despite the aforementioned medications, and she was transferred to our department. Figure 1 (a) In August 2012, brain magnetic resonance image (MRI) demonstrated lumpy enhancing lesions of T1-weighted imaging hypointense signals and slight T2-weighted imaging hyperintense signals in the left parietal, temporal, and occipital lobes as well as ... At admission, on October 7, 2012, complete blood count, erythrocyte sedimentation rate, C-reactive protein, immunoglobulin levels, autoimmune antibodies, and a T-SPOT. TB test were within normal ranges. A CSF analysis showed a white blood cell count of 560 cells/μl with 78% polymorphonuclear leukocytes, protein 2.0 g/L, glucose 2.0 mmol/L, and chlorine 108 mmol/L [Figure 1c]. CSF culture was negative. We reviewed the brain biopsy specimen conducted at the outside hospital, which had shown an inflammatory granuloma. The patient was empirically treated with ceftazidime and vancomycin. The differential diagnosis at that stage was broad and included chronic bacterial infection, tuberculosis (TB), fungal infection, and neurosyphilis. On October 9, 2012, the CSF tested positive for rapid plasma reagin (RPR). The patient, therefore, was suspected to have neurosyphilis, and was treated with ceftriaxone. On re-examination with RPR and a treponeme-specific test, we found that her CSF was negative, and neurosyphilis was subsequently excluded. She was suspected to have chronic bacterial cerebromeningitis, and was therefore treated with ceftriaxone and moxifloxacin. On October 29, the patient still experienced fever and headaches; thus, we suspected that she had TB cerebromeningitis since the pathological examination had revealed a granuloma, and the broad-spectrum antibiotics did not alleviate her symptoms. Moreover, TB was the most common cause of chronic cerebromeningitis in China. We subsequently stopped ceftriaxone, and initiated diagnostic anti-TB therapy, which included isoniazid, rifampin, ethambutol, moxifloxacin, and amikacin. On December 7, 2012, a repeated MRI demonstrated that the lesions remained unchanged. In addition, the patients CSF was still abnormal. Stereotactic partial resection (3 cm × 3 cm) of the lesion was then performed on December 24, 2012 [Figure ​[Figure1d1d and ​ande].e]. Brain tissue was grinded in 1 ml of sterile nutritious broth by using a tissue grinder. The tissue-broth suspension was injected into aerobic and anaerobic blood culture bottles (BACTEC, Becton Dickinson, USA), and then incubated in automatic blood culture instrument (BACTEC9120). B. megaterium was cultured from the brain specimens after a 17-h incubation [Table 1]. The histological results demonstrated inflammation with small abscesses [Figure 1f]. Following this discovery, the patient was diagnosed with brain abscesses caused by B. megaterium and was treated with amoxicillin-potassium clavulanate and moxifloxacin. Table 1 The results of the culture of the brain tissue specimens After surgery, the patients fever and neurological symptoms remitted, and the antibiotics were switched to penicillin on March 3, 2013 (4MU intravenous drip every six hours) [Figure 1b], until her CSF was normal [Figure 1c], and the cerebral MRI was stable. Penicillin was discontinued in November 2013, and the patient has been stable ever since December 2013. We report a rare case of a B. megaterium-related brain abscess, which is the first adult brain abscess of this etiology described in the medical literature. Antibiotic therapy combined with surgical resection is considered crucial for successful treatment of large brain abscess. This case highlights the need for early microbiological diagnosis of brain abscesses to identify unusual pathogens when there is no response to empirical antibiotics. Since the incubation time of B. megaterium of our patient was <48 h during bacterial culture, and long-term antimicrobial therapy and excision of the lesions were effective in alleviating her symptoms, we determined that B. megaterium was the culprit of the brain abscess. Importantly, when this bacterium is found in clinical laboratory specimens, it is often reported as “insignificant contaminant”.[4] However, this case report proves that chronic brain abscesses can be caused by B. megaterium. When histological results demonstrate granulomatous lesions but cultures are negative, intracranial space-occupying lesions are difficult to diagnose. Intracranial granuloma can be due to the response to infection, of which TB is the most common cause. Moreover, fungal lesions are also a well-documented cause. Of the various types of brain granulomas, neurosyphilis (cerebral gummas) is very rare but has been reported. Systemic granulomatous diseases, including sarcoid and Wegeners granulomatosis may have central nervous system (CNS) involvement. The differential diagnosis for our patient was challenging at admission, and she had been misdiagnosed with neurosyphilis and TB. Thus, chronic bacterial infection by B. megaterium should be considered when histological results demonstrated granulomatous lesions. We found the brain abscess caused by B. megaterium first presented as a granulomatous lesion, and later as a small abscess. In our patient, the spreading route of B. megaterium was unclear. We hypothesize that the bacterium entered into her bloodstream and later localized to the brain. The infection had progressed significantly over a long period since the patient had not sought immediate medical attention. Therefore, the initial management of the patient at the clinic was suboptimal. Although antibiotics were effective on B. megaterium, the bacterium could already have had formed spores, and thus it was difficult to eradicate. The ideal management of B. megaterium infections in the CNS is currently unknown due to the small number of cases in the literature. We postulate that if the organism is susceptible to penicillin, it will be a reasonable choice to treat CNS infection because it passes the blood-brain barrier. The successful treatment of our patient was mostly ascribed to surgical excision of the lesions. Taken together, we suggest that surgical resection of the brain abscess and the culture of tissue is necessary in cases where antibiotics are not effective. There are limited data available for the treatment of brain abscess caused by B. megaterium, and thus, careful follow-up is necessary. The successful treatment of our patient was ascribed to surgical excision of the lesions and the effective antibiotic therapy.

Longitudinal profiles of immunoglobulin G antibodies against severe acute respiratory syndrome coronavirus components and neutralizing activities in recovered patients.

Abstract Background: Immunological memory is the basis for vaccination. Currently, the longitudinal profiles of antibody responses in recovered severe acute respiratory syndrome (SARS) patients have not been fully characterized. Methods: In this study we sequentially followed up 19 recovered SARS patients over a 3-y period in order to characterize the dynamic changes in antibody responses against viral components in detail. In addition, 4 blood samples were obtained at month 60. Results: We found that immunoglobulin G (IgG) antibodies and their neutralizing activities decreased throughout the entire phase of the study. For IgG antibodies in the 3rd y, the positive rate of whole-virus-specific antibodies was 42%, which was tested with commercial kits at 1/10 dilution of the sera. In comparison, the positive rate of spike (S) protein-specific antibodies was 100%, which was tested by spike protein-based ELISA at 1/100 dilution; 4 samples at month 60 were included. The average optical density (OD) reading of nucleocapsid (N) protein-specific antibodies fell dramatically between month 3 and month 12, and it decreased gradually at low levels that were a little higher than the cut-off value from month 12. For neutralizing antibodies, neutralizing activity was detectable in 89% of recovered patients in the 3rd y. S protein-specific IgG levels (r = 0.717) correlated better with neutralizing activity than SARS coronavirus-specific IgG levels (r = 0.571). Conclusions: These systematic findings provide valuable information on natural humoral memory responses, and the data will be helpful for understanding the pathogenesis of SARS coronavirus infection and for the rational design of vaccines.

Retrospective Examination of Q Fever Endocarditis: An Underdiagnosed Disease in the Mainland of China

Background: Q fever endocarditis, a chronic illness caused by Coxiella burnetii, can be fatal if misdiagnosed or left untreated. Despite a relatively high positive rate of Q fever serology in healthy individuals in the mainland of China, very few cases of Q fever endocarditis have been reported. This study summarized cases of Q fever endocarditis among blood culture negative endocarditis (BCNE) patients and discussed factors attributing to the low diagnostic rate. Methods: We identified confirmed cases of Q fever endocarditis among 637 consecutive patients with infective endocarditis (IE) in the Peking Union Medical College Hospital between 2006 and 2016. The clinical findings for each confirmed case were recorded. BCNE patients were also examined and each BCNE patients Q fever risk factors were identified. The risk factors and presence of Q fever serologic testing between BCNE patients suspected and unsuspected of Q fever were compared using the Chi-squared or Chi-squared with Yates’ correction for continuity. Results: Among the IE patients examined, there were 147 BCNE patients, of whom only 11 patients (7.5%) were suspected of Q fever and undergone serological testing for C. burnetii. Six out of 11 suspected cases were diagnosed as Q fever endocarditis. For the remaining136 BCNE patients, none of them was suspected of Q fever nor underwent relevant testing. Risk factors for Q fever endocarditis were comparable between suspected and unsuspected patients, with the most common risk factors being valvulopathy in both groups. However, significantly more patients had consulted the Infectious Diseases Division and undergone comprehensive diagnostic tests in the suspected group than the unsuspected group (100% vs. 63%, P = 0.03). Conclusions: Q fever endocarditis is a serious yet treatable condition. Lacking awareness of the disease may prevent BCNE patients from being identified, despite having Q fever risk factors. Increasing awareness and guideline adherence are crucial in avoiding misdiagnosing and missed diagnosing of the disease.