Successful Treatment of Balamuthia mandrillaris Granulomatous Amebic Encephalitis with Nitroxoline

A patient in California, USA, with rare and usually fatal Balamuthia mandrillaris granulomatous amebic encephalitis survived after receiving treatment with a regimen that included the repurposed drug nitroxoline. Nitroxoline, which is a quinolone typically used to treat urinary tract infections, was identified in a screen for drugs with amebicidal activity against Balamuthia.

A patient in California, USA, with rare and usually fatal Balamuthia mandrillaris granulomatous amebic encephalitis survived after receiving treatment with a regimen that included the repurposed drug nitroxoline. Nitroxoline, which is a quinolone typically used to treat urinary tract infections, was identified in a screen for drugs with amebicidal activity against Balamuthia. and nontuberculous mycobacteria. Rereview of neuropathology raised concern for amebic forms, prompting us to add uPCR of brain biopsy sample for ameba species (10). The patient was discharged.
On day 27, the patient was rehospitalized, again with disorientation and inattention. Repeat MRI showed disease progression with multiple new supratentorial and infratentorial lesions consistent with amebic abscesses. After consulting with the Centers for Disease Control and Prevention, we started administering sulfadiazine ( (Figure 1).
MRI on day 42 (15 days of the 7-drug regimen) showed moderately reduced lesion size, reduced edema, and no new lesions. However, severe medication toxicities developed. Hypoglycemia required discontinuation of pentamidine. Subsequent renal failure caused by sloughing of renal calyces required discontinuation of sulfadiazine and placement of bilateral nephrostomy tubes. The patient's kidney function improved but remained impaired (baseline estimated glomerular filtration rate 20). Decreased absolute neutrophil count necessitated stopping and then reducing flucytosine dose. The ongoing limited regimen included dose-reduced flucytosine, fluconazole, miltefosine, albendazole, and azithromycin. Brain MRI on day 59 (14 days on this limited regimen) showed interval increase in lesion size, with increased edema.
Given his worsening prognosis, the patient and his family agreed to trial treatment with nitroxoline, a quinolone antibiotic with in vitro amebicidal activity against B. mandrillaris (6). Nitroxoline was selected instead of compounds identified in other high-throughput screens (12) because it is available internationally to treat urinary tract infections and is well tolerated (13). Nitroxoline was authorized through an emergency use authorization (Food and Drug Administration Investigational New Drug no. 154939), and on day 103, we initiated treatment (250 mg orally 3×/d). All other medications were continued. The patient experienced a transient acute kidney injury; although the nephrology staff considered it unrelated to nitroxoline, we submitted a possible adverse event report.
On day 109, after 1 week of nitroxoline treatment, MRI showed decreased size of the cerebral abscesses and no new lesions compared with MRI before nitroxoline on day 96 ( Figure 2, panel B). The patient was discharged, although neurologic examination continued to demonstrate mild disorientation and inattention. Recovery was complicated by a subsequent acute kidney injury because of malfunctioning ureteral stents, and nitroxoline administration was stopped while creatinine clearance was <20 (days 122-143). Interval MRIs on days 156 and 220 (7 and 17 weeks after nitroxoline initiation) showed continued marked improvement in lesion size (Figure 2, panel B).
As of 15 months after initial evaluation, the patient continues to take nitroxoline, miltefosine, azithromycin, albendazole, fluconazole, and dosereduced flucytosine. His infectious disease outpatient clinicians plan to sequentially discontinue medications after 1 year. He lives in the community, and his family assists with medication management and appointments.

Conclusions
Repurposed use of nitroxoline associated with survival from B. mandrillaris GAE demonstrates the potential of basic research to identify antiamebic agents that improve outcome of this rare and deadly disease. Given the limited options for treating Balamuthia GAE, several studies have used high-throughput screening tools to identify other amebicidal agents. Compounds from the Medicines for Malaria Ventures Pandemic Response Box underwent in vitro trials against B. mandrillaris, but the leading candidates have not been used in humans or are not commercially Occasional structures with a large nucleus present within a relatively rigid outline (lower right image) are suspicious for amebic cysts, the dormant, thick-walled life stage. B) Magnetic resonance images obtained before and after nitroxoline treatment. Upper row shows axial gadoliniumenhanced T1-weighted images; lower row shows axial fluidattenuated inversion recovery images. Images in the left series were obtained on day 96 after initial visit, 1 week before nitroxoline initiation; images in the right series were obtained on day 156 after initial visit, 7 weeks after nitroxoline initiation. BV, blood vessel.
available (12). In the screening for the patient reported here, which identified nitroxoline as having amebicidal activity against B. mandrillaris, in vitro efficacy of nitroxoline against B. mandrillaris cysts and trophozoites was determined to be higher than that of currently recommended drugs and prevented tissue destruction in fibroblast and explant models of B. mandrillaris infection (6).
In vitro efficacy of nitroxoline is better than that of other antiamebic medications; it also is safe and well tolerated. In a review of its use in urinary tract infections, 9.8% of patients reported adverse events, primarily nausea (13). In contrast, current antiamebic treatments can cause severe toxicity, especially pentamidine and sulfadiazine. It is not known if nitroxoline penetrates the CNS, but our limited experience suggests that it may, especially in a patient with a compromised blood-brain barrier.
A barrier to treating Balamuthia GAE is diagnostic delay. Imaging characteristics are nonspecific, and more common pathologies are often misdiagnosed (e.g., neoplasm or pyogenic abscesses) (4). CSF findings are typically nonspecific, direct detection tests of CSF can be insensitive, and visualization of organisms in CSF is rare. Thus, diagnosis often requires brain biopsy, specialized pathology, or dedicated PCR testing.
Unbiased diagnostics, such as mNGS, offer the opportunity to streamline and accelerate diagnosis of rare pathogens such as Balamuthia (8). Multiple Balamuthia GAE cases have been diagnosed by CSF mNGS (14,15). In the case we report, results of CSF mNGS testing were negative, concordant with negative CSF uPCR and indicating that no abscesses had ruptured or were abutting the ventricles (8). However, results of uPCR and research-based mNGS of brain tissue were positive. Currently, clinical mNGS is not available for brain biopsy samples; clinical validation of this test may speed diagnoses of future cases. Despite the limitations of any case study, we suggest that accelerated diagnosis with unbiased techniques and early initiation of nitroxoline may offer promise to improve survival rates for patients with Balamuthia GAE.

Acknowledgments
We thank the patient and his family for participating in this study.

About the Author
Dr. Spottiswoode is a research fellow in the Division of HIV, Infectious Diseases, and Global Medicine at the University of California San Francisco. Her research interests include the use of novel diagnostic tools and the combination of pathogen metagenomics and host responses to understand disease pathophysiology and outcome.