A Rare Case of Co-Infection with Nocardia farcinica, Pneumocystis jirovecii, and Aspergillus fumigatus Due to Tooth Extraction in a Mildly Immunosuppressed Patient.

We report a case of co-infection with Nocardia farcinica, Pneumocystis jirovecii, and Aspergillus fumigatus due to tooth extraction in a mildly immunosuppressed patient. This patient did not respond well to a meropenem-based regimen, and the number of lesions was significantly reduced after switching to imipenem. The patient's trough concentration was insufficient when using conventional doses of voriconazole for the treatment of pulmonary aspergillosis. After adding omeprazole, the concentration reached standard levels and symptoms improved. The patient eventually made a full recovery.

Plain Language Summary

Nocardia farcinica, Pneumocystis jirovecii, and Aspergillus fumigatus are opportunistic pathogens, and co-infection of these three species is very rare.

We report a case of co-infection with Nocardia farcinica, Pneumocystis jirovecii, and Aspergillus fumigatus in an immunosuppressed patient.

This patient did not respond well to a meropenem-based regimen, and the number of lesions was significantly reduced after switching to imipenem.

For the treatment of N. farcinica, especially for intracranial infection, imipenem is superior to meropenem.

During treatment with voriconazole, if the trough concentration of voriconazole does not reach the target, the concentration can be increased by adding omeprazole.

Introduction

Immunosuppressed patients are prone to opportunistic infections.1 Nocardia farcinica, Pneumocystis jirovecii, and Aspergillus fumigatus are opportunistic pathogens, and their risk factors include high-dose glucocorticoids or immunosuppressants, AIDS, solid organ transplantation, and hematological tumors.2–4 The mortality rate of such infections is high, and clinical treatment is a great challenge. Co-infection of these three species has not been reported before. We report a case of successful treatment of intracranial infection with N. farcinica combined with pulmonary infection with P. jirovecii and A. fumigatus.

Case Presentation

A 62-year-old male took dexamethasone tablets (2.25 mg three times per day) and ornidazole tablets (0.5g two times per day) orally after tooth extraction. Ten days later, he developed fever (body temperature of 39°C) accompanied by chills, headache, bloating, tinnitus, and hearing loss. Treatment at the local hospital was not effective, and he was transferred to our hospital three days later. On admission, the patient’s body temperature was 38.6°C, blood pressure was 134/74 mmHg, respiration was 16 beats/min, heart rate was 75 beats/min, and he was conscious. Relevant examinations were as follows: white blood cell count of 4.40×109/L, neutrophil percentage of 89.8%, lymphocyte count of 0.17×109/L, CD4+ lymphocyte count of 32/mm3, C-reactive protein level of 14.38 mg/L, creatinine level of 37.05 umol/L, pH of 7.399, procalcitonin level of 0.123 ng/mL, and 1,3-β-d-glucan level of 253.73 pg/mL. Cranial magnetic resonance imaging (MRI) showed multiple lesions in the brain. Enhanced MRI of the head showed multiple abnormal enhancement shadows in the brain: hematogenous disseminated lesions were possible. Chest computed tomography (CT) showed multiple ground-glass opacities in the anterior segment and lower lobe of the left lung. The patient’s cerebrospinal fluid (CSF) had a white blood cell count of 1352×106/L, neutrophil percentage of 92%, glucose level of 0.59 mmol/L, and protein level of 1.48 g/L. Next-generation sequencing (NGS) of the patient’s CSF reported 37,235 sequences from N. farcinica and 8 sequences from human cytomegalovirus. Blood NGS reported 61 sequences from Nocardia farcinica, 543 sequences from human cytomegalovirus, and 8 sequences from P. jirovecii. The patient’s condition gradually deteriorated, and he developed confusion and respiratory failure, requiring an invasive ventilator to assist breathing. After a week of treatment with meropenem, compound sulfamethoxazole (SMZ), linezolid, and ganciclovir, the patient’s symptoms improved slightly and he could breathe independently (Figure 1). On the 18th day, the patient’s sputum culture was positive for A. fumigatus and lung CT showed new lesions. N. farcinica and P. jirovecii were not found in the sputum culture and we did not perform NGS again. The doctor administered voriconazole by intravenous drip (400 mg every 12 hours on the first day then 200 mg every 12 hours) to fight infection. The patient showed minimal response for about a week, with occasional hemoptysis, and the voriconazole trough concentration was 0.8 mg/L. We added oral omeprazole to the patient’s regimen. On the 31st day, the patient’s voriconazole trough concentration was 1.1 mg/L, and the blood no longer appeared in the sputum. CT showed that the lesions were absorbed better than before. The patient still had occasional headaches. On the 35th day, head MRI still revealed multiple infection lesions, similar to previous scans (Figure 2). We replaced meropenem with imipenem. On the 70th day, head MRI revealed a significantly reduced number of lesions. On the 78th day, the patient was transferred to a local hospital for continued treatment, and the treatment plan was changed to SMZ combined with linezolid, amoxicillin, and clavulanate potassium. The patient fully recovered after six months of treatment.

Figure 1

Treatment timeline. ✹: Nocardia farcinica; ▲: Pneumocystis jirovecii; and ◉: Aspergillus fumigatus.

Figure 2

Magnetic resonance imaging scan of the patient.

Discussion

To the best of our knowledge, this is the first report of an immunocompromised patient with N. farcinica, P. jirovecii, and A. fumigatus co-infection. The patient presented with headache and hearing loss, and multiple lesions were observed on head MRI, which is indicative of intracranial infection. The number of sequences from N. farcinica in the patient’s CSF was very high and CSF examination showed N. farcinica infection in the patient’s brain. The patient’s CSF examination was consistent with purulent meningitis.5

The patient had respiratory dysfunction and low immune function; the CD4+ lymphocyte count was only 32/mm3, ground-glass shadows could be seen on chest CT, sequences from P. jirovecii were detected in the patient’s blood and 1,3-β-d-glucan levels were as high as 253.73 pg/mL. 1,3-β-d-glucan is an antigenic component of the cell wall of many fungi, including P. jirovecii. It can only be used for auxiliary diagnosis of P. jirovecii due to lack of specificity.6,7 Morjaria’s8 study found that 1,3-β-d-glucan ≥200 pg/mL had a sensitivity of 70%, specificity of 100%, positive predictive value of 100% for P. jirovecii. So we believe that the patient in the present case can be diagnosed with P. jirovecii pneumonia.4,9 The patient’s galactomannan test was negative, and initially he did not use drugs for Aspergillus, but the patient’s dyspnea was relieved after being treated for N. farcinica and P. jirovecii, so we believe that the patient’s Aspergillus infection is a secondary infection.

Using the search terms N. farcinica and P. jirovecii on PubMed, the co-infection of Nocardia and P. jirovecii was found to be very rare and only one report describe this kind of infection and the patient was on SMZ based treatment.10 SMZ is the main treatment for Nocardia and P. jirovecii. Amikacin, imipenem, meropenem, linezolid, and amoxicillin-clavulanate potassium are all active against N. farcinica. If dissemination or central nervous system infection occurs, at least two drugs should be selected for treatment.11 However, amikacin cannot reach an effective concentration intracranially, but imipenem is clinically effective and its activity is stronger than that of meropenem and linezolid can achieve a high intracranial concentration and can be used for severe infections.12 Imipenem can maintain higher concentrations intracranially than meropenem in cerebrospinal fluid and is four times more active against Nocardia.13,14 The patient’s initial treatment with a meropenem-based regimen for one month was ineffective, and a month after imipenem was substituted, the lesions were significantly reduced, proving that imipenem is superior to meropenem in the treatment of intracranial infection with N. farcinica.

On the 18th day, the patient’s sputum culture was positive for A. fumigatus, and CT showed a new lesion. The doctor considered fungal infection and initiated voriconazole for treatment. However, during treatment, the patient occasionally had blood in the sputum, and chest CT showed that the infection was still progressing. The voriconazole trough concentration was 0.8 mg/L. According to guidelines and previous reports, the trough concentration of voriconazole should be maintained between 1 and 6 mg/L.15,16 Therefore, the poor antifungal effect observed in patients is likely related to the insufficient concentration of voriconazole, but voriconazole is very expensive and the treatment course for fungal infections is relatively long so patients may not be able to afford higher doses. The label of voriconazole states that CYP450 inhibitors such as omeprazole and esomeprazole will lead to an increase in voriconazole concentration.17 Therefore, we added omeprazole to the patient’s treatment regimen. After three days, the patient’s voriconazole trough concentration reached the treatment standard, and the patient’s symptoms gradually improved. After about two months of voriconazole treatment, it was discontinued. Therefore, we believe that for patients with insufficient voriconazole concentrations at conventional doses, the voriconazole concentration can be increased by adding omeprazole.

There were some limitations in this study. Our microbiology laboratory failed to culture Nocardia and P. jirovecii, and we were unable to perform drug susceptibility testing for Aspergillus. Therefore, the drug susceptibility to these three pathogens can only be based on previous literature reports. Considering the problem of fungal resistance, drug susceptibility testing should be performed before using triazoles and the treatment strategy with voriconazole is only applicable in MIC≤1 ug/mL for Aspergillus.

Conclusion

N. farcinica, P. jirovecii and A. fumigatus are opportunistic pathogens, and co-infection of these three species is very rare. These pathogens are usually associated with strong, long-lasting immunosuppressive regimens, but the tooth extraction-associated incident described in this report highlights the need to pay attention even to such inconspicuous cases. For the treatment of N. farcinica, especially for intracranial infection, imipenem is superior to meropenem. During treatment with voriconazole, if the trough concentration of voriconazole does not reach the target, the concentration can be increased by adding omeprazole.