Severe Pediatric COVID-19 and Multisystem Inflammatory Syndrome in Children From Wild-type to Population Immunity: A Prospective Multicenter Cohort Study With Real-time Reporting.

BACKGROUND: SARS-CoV-2 variant evolution and increasing immunity altered the impact of pediatric SARS-CoV-2 infection. Public health decision-making relies on accurate and timely reporting of clinical data. METHODS: This international hospital-based multicenter, prospective cohort study with real-time reporting was active from March 2020 to December 2022. We evaluated longitudinal incident rates and risk factors for disease severity. RESULTS: We included 564 hospitalized children with acute COVID-19 (n = 375) or multisystem inflammatory syndrome in children (n = 189) from the Netherlands, Curaçao and Surinam. In COVID-19, 134/375 patients (36%) needed supplemental oxygen therapy and 35 (9.3%) required intensive care treatment. Age above 12 years and preexisting pulmonary conditions were predictors for severe COVID-19. During omicron, hospitalized children had milder disease. During population immunity, the incidence rate of pediatric COVID-19 infection declined for older children but was stable for children below 1 year. The incidence rate of multisystem inflammatory syndrome in children was highest during the delta wave and has decreased rapidly since omicron emerged. Real-time reporting of our data impacted national pediatric SARS-CoV-2 vaccination- and booster-policies. CONCLUSIONS: Our data supports the notion that similar to adults, prior immunity protects against severe sequelae of SARS-CoV-2 infections in children. Real-time reporting of accurate and high-quality data is feasible and impacts clinical and public health decision-making. The reporting framework of our consortium is readily accessible for future SARS-CoV-2 waves and other emerging infections.

Adjunctive interferon-γ immunotherapy in a pediatric case of Aspergillus terreus infection.

Aspergillus terreus causes invasive aspergillosis (IA) in immunocompromised patients. Treatment is complicated by intrinsic resistance to amphotericin B and thereby contributing to a high mortality. Therefore, we conducted in vitro studies to investigate the effectivity of adjunctive recombinant interferon-γ immunotherapy. We describe a pediatric patient with A. terreus IA who received adjunctive recombinant interferon-γ (rIFNγ) immunotherapy. In vitro studies were conducted to investigate the capacity of rIFNγ to improve antifungal host defense in terms of fungal killing ability and the release of pro-inflammatory cytokines in cells of the patient as well as healthy controls. An 8-year-old female pediatric patient with leukemia developed A. terreus IA. She clinically deteriorated and had high serum galactomannan levels despite broad antifungal therapy. Therefore, adjunctive immune stimulatory therapy with rIFNγ was initiated. After 3 weeks of treatment, galactomannan levels decreased and the patient clinically showed improvement. Addition of rIFNγ boosted the capacity of monocytes of healthy volunteers to mount TNFα and IL-1ß cytokine responses to Escherichia coli LPS, and increased TNFα response to both A. terreus and Aspergillus fumigatus. Monocytes isolated from the patient's blood demonstrated a similar augmented cytokine induction in response to rIFNγ. In addition, rIFNγ increased the capacity of monocytes from healthy volunteers as well as monocytes from the patient to kill A. terreus spores. Adjuvant immunotherapy with rIFNγ might be a promising additional treatment strategy that could be used to improve outcome in patients with refractory invasive A. terreus infections or other resistant invasive Aspergillus infections.

Aspergillosis due to voriconazole highly resistant Aspergillus fumigatus and recovery of genetically related resistant isolates from domiciles.

BACKGROUND: Azole resistance is an emerging problem in Aspergillus fumigatus and complicates the management of patients with Aspergillus-related diseases. Selection of azole resistance may occur through exposure to azole fungicides in the environment. In the Netherlands a surveillance network was used to investigate the epidemiology of resistance selection in A. fumigatus. METHODS: Clinical A. fumigatus isolates were screened for azole resistance in 8 university hospitals using azole agar dilution plates. Patient information was collected using an online questionnaire and azole-resistant A. fumigatus isolates were analyzed using gene sequencing, susceptibility testing, and genotyping. Air sampling was performed to investigate the presence of resistant isolates in hospitals and domiciles. RESULTS: Between December 2009 and January 2011, 1315 A. fumigatus isolates from 921 patients were screened. A new cyp51A-mediated resistance mechanism (TR46/Y121F/T289A) was observed in 21 azole-resistant isolates from 15 patients in 6 hospitals. TR46/Y121F/T289A isolates were highly resistant to voriconazole (minimum inhibitory concentration ≥16 mg/L). Eight patients presented with invasive aspergillosis due to TR46/Y121F/T289A, and treatment failed in all 5 patients receiving primary therapy with voriconazole. TR46/Y121F/T289A Aspergillus fumigatus was recovered from 6 of 10 sampled environmental sites. CONCLUSIONS: We describe the emergence and geographical migration of a voriconazole highly resistant A. fumigatus that was associated with voriconazole treatment failure in patients with invasive aspergillosis. Recovery of TR46/Y121F/T289A from the environment suggests an environmental route of resistance selection. Exposure of A. fumigatus to azole fungicides may facilitate the emergence of new resistance mechanisms over time, thereby compromising the use of azoles in the management of Aspergillus-related diseases.

Rapid induction of multiple resistance mechanisms in Aspergillus fumigatus during azole therapy: a case study and review of the literature.

Nine consecutive isogenic Aspergillus fumigatus isolates cultured from a patient with aspergilloma were investigated for azole resistance. The first cultured isolate showed a wild-type phenotype, but four azole-resistant phenotypes were observed in the subsequent eight isolates. Four mutations were found in the cyp51A gene of these isolates, leading to the substitutions A9T, G54E, P216L, and F219I. Only G54 substitutions were previously proved to be associated with azole resistance. Using a Cyp51A homology model and recombination experiments in which the mutations were introduced into a susceptible isolate, we show that the substitutions at codons P216 and F219 were both associated with resistance to itraconazole and posaconazole. A9T was also present in the wild-type isolate and thus considered a Cyp51A polymorphism. Isolates harboring F219I evolved further into a pan-azole-resistant phenotype, indicating an additional acquisition of a non-Cyp51A-mediated resistance mechanism. Review of the literature showed that in patients who develop azole resistance during therapy, multiple resistance mechanisms commonly emerge. Furthermore, the median time between the last cultured wild-type isolate and the first azole-resistant isolate was 4 months (range, 3 weeks to 23 months), indicating a rapid induction of resistance.

Clinical implications of azole resistance in Aspergillus fumigatus, The Netherlands, 2007-2009.

The prevalence and spread of azole resistance in clinical Aspergillus fumigatus isolates in the Netherlands are currently unknown. Therefore, we performed a prospective nationwide multicenter surveillance study to determine the effects of resistance on patient management strategies and public health. From June 2007 through January 2009, all clinical Aspergillus spp. isolates were screened for itraconazole resistance. In total, 2,062 isolates from 1,385 patients were screened; the prevalence of itraconazole resistance in A. fumigatus in our patient cohort was 5.3% (range 0.8%-9.5%). Patients with a hematologic or oncologic disease were more likely to harbor an azole-resistant isolate than were other patient groups (p<0.05). Most patients (64.0%) from whom a resistant isolate was identified were azole naive, and the case-fatality rate of patients with azole-resistant invasive aspergillosis was 88.0%. Our study found that multiazole resistance in A. fumigatus is widespread in the Netherlands and is associated with a high death rate for patients with invasive aspergillosis.

Aspergillus species intrinsically resistant to antifungal agents.

Polyphasic taxonomy has had a major impact on the species concept of the genus Aspergillus. New sibling species have been described that exhibit in vitro susceptibility profiles that differ significantly from that of Aspergillus fumigatus. While acquired resistance is an emerging problem in A. fumigatus, non-A. fumigatus Aspergillus species may be intrinsically resistant to specific classes of antifungal agents. Minimum inhibitory concentrations of amphotericin B and azoles for some of the non-A. fumigatus Aspergillus species are elevated compared to A. fumigatus. Furthermore, the clinical presentation and evolution of invasive infections caused by these species may differ from that commonly observed for A. fumigatus. As the role of the newly identified Aspergillus species in causing invasive aspergillosis remains unclear, surveillance networks that incorporate sequence-based identification of clinical isolates are needed to determine the species distribution, the clinical disease and outcome of patients with invasive aspergillosis. Preclinical and clinical studies are needed to further improve the methods for in vitro susceptibility testing and to investigate the impact of elevated MICs on antifungal drug efficacy.

Impact of therapeutic drug monitoring of voriconazole in a pediatric population.

Voriconazole trough concentrations more than 1 mg/L are associated with a higher likelihood of success. It is unknown whether these trough concentrations are reached with the current recommended pediatric dosing schedule. We retrospectively analyzed the results of our therapeutic drug monitoring service for voriconazole in 18 children treated at our children's hospital. Thirty-nine voriconazole plasma concentrations were measured. In 44% of patients, the first voriconazole concentration was below the target. Dose adjustment eventually resulted in plasma concentrations within the predefined target range in all patients. Given the high proportion of patients with subtherapeutic concentrations, monitoring plasma concentrations should be performed routinely in pediatric patients receiving voriconazole.

Rapid diagnosis of azole-resistant aspergillosis by direct PCR using tissue specimens.

We report the use of PCR techniques on a formalin-fixed and paraffin-embedded tissue specimen for direct detection of one dominant azole resistance mechanism in a case of disseminated invasive aspergillosis. Rapid detection of mutations associated with azole resistance directly in tissue significantly reduces diagnostic delay.

Azole-resistant central nervous system aspergillosis.

Three patients with central nervous system aspergillosis due to azole-resistant Aspergillus fumigatus (associated with a leucine substitution for histidine at codon 98 [L98H] and a 34-base pair repeat in tandem in the promoter region) are described. The patients were treated with combination therapy or with polyenes, but all patients died. Azole resistance significantly complicates the management of aspergillosis by delaying the initiation of adequate therapy and because effective alternative antifungal drugs are lacking.

[Azole-resistant invasive aspergillosis]. / Azoolresistente invasieve aspergillose.

Invasive aspergillosis caused by medical triazole-resistant Aspergillus fumigatus is described in two patients. A 31-year-old male with chronic granulomatous disease developed pulmonary aspergillosis despite itraconazole prophylaxis. A. fumigatus was cultured from the lung and was found to be azole-resistant. The patient was successfully treated with caspofungin. The second patient was a 13-year-old boy with acute lymphoid leukaemia. He developed pulmonary aspergillosis that failed to respond to voriconazole therapy. The infection spread to the brain and an azole-resistant isolate was cultured from a lung biopsy. Despite a switch to liposomal amphotericin B in combination with caspofungin, the infection progressed and the patient died. Azole-resistance has emerged in A. fumigatus and may develop through the treatment of patients. However, there is evidence that in the Netherlands, resistance might be emerging through fungal exposure to azole fungicides. Azole resistance further complicates the management of invasive aspergillosis and should be considered as cause for treatment failure.