Bacterial and fungal superinfections are detected at higher frequency in critically ill patients affected by SARS CoV-2 infection than negative patients and are associated to a worse outcome.

Patients with viral infections are at higher risk to acquire bacterial and fungal superinfections associated with a worse prognosis. We explored this critical point in the setting of patients with severe COVID-19 disease. The study included 1911 patients admitted to intensive care unit (ICU) during a 2-year study period (March 2020-March 2022). Of them, 713 (37.3%) were infected with SARS-CoV-2 and 1198 were negative (62.7%). Regression analysis was performed to determine risk factors associated with the presence of bacterial and/or fungal superinfections in SARS-CoV-2 patients and to evaluate predictors of ICU mortality. Of the 713 patients with SARS-CoV-2 infection, 473 (66.3%) had respiratory and/or bloodstream bacterial and/or fungal superinfections, while of the 1198 COVID-19-negative patients, only 369 (30%) showed respiratory and/or bloodstream bacterial and/or fungal superinfections (p < 0.0001). Baseline characteristics of COVID-19 patients included a median age of 66 (interquartile range [IQR], 58-73), a predominance of males (72.7%), and the presence of a BMI higher than 24 (median 26; IQR, 24.5-30.4). Seventy-four percent (527, 73.9%) had one or more comorbidities and 135 (18.9%) of them had received previous antibiotic therapy. Furthermore, most of them (473, 66.3%) exhibited severe radiological pictures and needed invasive mechanical ventilation. Multivariate logistic regression analysis showed that 1 unit increment in BMI rises the risk of bacterial and/or fungal superinfections acquisition by 3% and 1-day increment in ICU stays rises the risk of bacterial and/or fungal superinfections acquisition by 11%. Furthermore, 1-day increment in mechanical ventilation rises the risk of bacterial and/or fungal superinfection acquisition by 2.7 times. Furthermore, patients with both bacterial and fungal infections had a significantly higher mortality rate than patients without superinfections (45.8% vs. 26.2%, p < 0.0001). Therefore, bacterial and fungal superinfections are frequent in COVID-19 patients admitted to ICU and their presence is associated with a worse outcome. This is an important consideration for targeted therapies in critically ill SARS-CoV-2 infected patients to improve their clinical course.

Etiological factors of bloodstream infections in oncological patients, who was hospitalized at the National Institute of Maria Sklodowska-Curie - National Research Institute in Warsaw in 2020-2022.

Aim of the study: The purpose of the study was the microbiological analysis of bloodstream infections in patients hospitalized at the National Institute of Oncology, Maria Sklodowska-Curie - National Research Institute in the period from 01/01/2020 to 31/10/2022. Material and methods: In the period from 01/01/2020 to 31/10/2022, 18,420 blood cultures obtained from patients hospitalized at the NIO-PIB were analysed in the Department of Clinical Microbiology (total for the presence of bacteria and fungi). Culture for the presence of bacteria was carried out in the BactAlert automatic system by bioMerieux, and for fungi in the Bactec FX automatic system by Becton Dickinson. Results: 1,184 strains of bacteria and 32 strains of fungi considered to be the etiological factor of the infection were cultured from clinical samples. Gram-positive bacteria accounted for 61.57%, while Gram-negative bacteria accounted for 32.26% of all isolated bacterial strains. The most frequently cultured strains were Escherichia coli - 13.77% (including 22.1% of ESBL strains), Klebsiella penumoniae - 4.6% (44.4% of ESBL strains, 1.85% of NDM strains), Enterobacter cloacae - 2 .7% (including 40.6% of multi-resistant strains: ESBL (15.6%) or with AmpC derepression (25%), among the non-fermenting bacilli, Pseudomonas aeruginosa was the most frequently cultured - 4.18% (including 3.8% MBL) and Acinetobacter baumannii - 0.8% (including CRAB strains 50%, MBL 10%). Anaerobic microorganisms were responsible for 3.46% of blood infection cases. Yeast- like fungi were a factor in 2.7% of all fungemia cases. From blood samples taken Staphylococci were more frequently isolated directly from a vein or through a central venous catheter than aerobic Gram-negative bacilli (44.7% and 25.3% and 55.6% and 12.5%, respectively). The opposite situation occurred in the case of samples taken simultaneously directly from vein and through a central venous catheter, in which a higher share of aerobic Gram-negative bacilli (46.6%) than staphylococci (32.8%) in causing blood infections was observed. Conclusions: Gram-positive bacteria are the major contributors to bloodstream infections in cancer patients. There is a growing tendency to develop BSI caused by multi-resistant strains.

Whole-Genome Analysis of Extensively Drug-Resistant Enterobacter hormaechei Isolated from a Patient with Non-Hodgkin's Lymphoma.

BACKGROUND: Currently, the Enterobacteriaceae species are responsible for a variety of serious infections and are already considered a global public health problem, especially in underdeveloped countries, where surveillance and monitoring programs are still scarce and limited. Analyses were performed on the complete genome of an extensively antibiotic-resistant strain of Enterobater hormaechei, which was isolated from a patient with non-Hodgkin's lymphoma, who had been admitted to a hospital in the city of Manaus, Brazil. METHODS: Phenotypical identification and susceptibility tests were performed in automated equipment. Total DNA extraction was performed using the PureLink genomic DNA mini-Kit. The genomic DNA library was prepared with Illumina Microbial Amplicon Prep and sequenced in the MiSeq Illumina Platform. The assembly of the whole-genome and individual analyses of specific resistance genes extracted were carried out using online tools and the Geneious Prime software. RESULTS: The analyses identified an extensively resistant ST90 clone of E. hormaechei carrying different genes, including blaCTX-M-15, blaGES-2, blaTEM-1A, blaACT-15, blaOXA-1 and blaNDM-1, [aac(3)-IIa, aac(6')-Ian, ant(2″)-Ia], [aac(6')-Ib-cr, (qnrB1)], dfrA25, sul1 and sul2, catB3, fosA, and qnrB, in addition to resistance to chlorhexidine, which is widely used in patient antisepsis. CONCLUSIONS: These findings highlight the need for actions to control and monitor these pathogens in the hospital environment.

A high-speed microscopy system based on deep learning to detect yeast-like fungi cells in blood.

Background: Blood-invasive fungal infections can cause the death of patients, while diagnosis of fungal infections is challenging. Methods: A high-speed microscopy detection system was constructed that included a microfluidic system, a microscope connected to a high-speed camera and a deep learning analysis section. Results: For training data, the sensitivity and specificity of the convolutional neural network model were 93.5% (92.7-94.2%) and 99.5% (99.1-99.5%), respectively. For validating data, the sensitivity and specificity were 81.3% (80.0-82.5%) and 99.4% (99.2-99.6%), respectively. Cryptococcal cells were found in 22.07% of blood samples. Conclusion: This high-speed microscopy system can analyze fungal pathogens in blood samples rapidly with high sensitivity and specificity and can help dramatically accelerate the diagnosis of fungal infectious diseases.

Blood-invasive fungal infections can be lethal and their diagnosis is challenging. The existing detection methods have shortcomings such as having unsatisfactory sensitivity, being time-consuming and having detection limitations. In this study, a high-speed microscopy system was constructed based on deep learning. With this system, fungal cells in the blood can be detected and quantified directly with much higher sensitivity than traditional microscopes. Also, the effect of antifungal treatment can be monitored.

Microbiology and Clinical Outcome of Bloodstream Infections in Patients After Hematopoietic Stem Cell Transplantation.

Purpose: Patients after hematopoietic stem cell transplantation (HSCT) are often followed by bloodstream infections (BSIs). BSI is an important cause of non-relapse mortality (NRM) in HSCT patients. Methods: We conducted a retrospective cohort study of patients (aged >14 years) who underwent HSCT at our hospital from 2017 to 2021. Population characteristics, BSI microbiology, resistance to common antibiotics, and 30-day all-cause mortality were analyzed. Results: Of 3054 patients, 169 (5.5%) had BSIs after HSCT. Male, not in complete remission at transplantation and longer duration of neutropenia were risk factors for the development of BSI after HSCT. These BSIs were Gram-negative bacterial (n=123, 69.49%), Gram-positive bacterial (n=27, 15.25%), fungal (n=11, 6.36%), and polymicrobial (n=16, 9.25%). Among the Gram-negative bacteria, the proportions of isolates resistant to ceftazidime, cefepime, and piperacillin-tazobactam were similar (72.93%, 74.80%, and 77.42%, respectively). The overall drug resistance rates of amikacin and imipenem were 16.13% and 43.90%, respectively. Staphylococcus isolates were methicillin-resistant. In Enterococcus isolates, the penicillin resistance rate was 84.62%. Eleven isolates of Candida tropicalis were resistant to fluconazole and were sensitive to amphotericin B and flucytosine. The 30-day all-cause mortality rate of the 169 patients with BSIs was 8.88%. The 30-day all-cause mortality of patients with Gram-negative bacterial BSIs was 7.32%, 25.00% for polymicrobial BSIs, and 36.36% for fungal BSIs. The 30-day all-cause mortality of patients with fungal BSIs was significantly higher than that of patients with Gram-negative (P=0.0023) and Gram-positive bacteria (P=0.0023). Fungal BSI and non-Hodgkin's lymphoma (NHL) were associated with higher 30-day mortality. Conclusion: Our study reveals the microbiological characteristics and 30-day all-cause mortality in patients with bloodstream infections after HSCT. Our data provides strong support for empirical antimicrobial therapy and infection prevention strategies for patients with BSIs after HSCT.

Application of High-Throughput Sequencing Technology in the Pathogen Identification of Diverse Infectious Diseases in Nephrology Departments.

Objective: The purpose of this study was to explore the clinical applications of high-throughput sequencing (HTS) in the identification of pathogens in patients with urinary tract infection (UTI), peritoneal dialysis-associated peritonitis (PDAP), central venous catheter related blood infections (CRBIs), and lung infections in the nephrology department. Methods: Midstream urine samples from 112 patients with UTI, peritoneal fluid samples from 67 patients with PDAP, blood samples from 15 patients with CRBI, and sputum specimens from 53 patients with lung infection were collected. The HTS and ordinary culture methods were carried out in parallel to identify the pathogens in each sample. Pathogen detection positive rate and efficacy were compared between the two methods. Results: The pathogen positive detection rates of HTS in UTI, PDAP, CRBI, and lung infection were strikingly higher than those of the culture method (84.8% vs. 35.7, 71.6% vs. 23.9%, 75% vs. 46.7%, 84.9% vs. 5.7%, p < 0.05, respectively). HTS was superior to the culture method in the sensitivity of detecting bacteria, fungi, atypical pathogens, and mixed microorganisms in those infections. In patients who had empirically used antibiotics before the test being conducted, HTS still exhibited a considerably higher positive rate than the culture method (81.6% vs. 39.0%, 68.1% vs. 14.9%, 72.7% vs. 36.4%, 83.3% vs. 4.2%, p < 0.05, respectively). Conclusions: HTS is remarkably more efficient than the culture method in detecting pathogens in diverse infectious diseases in nephrology, and is particularly potential in identifying the pathogens that are unable to be identified by the common culture method, such as in cases of complex infection with specific pathogens or subclinical infection due to preemptive use of antibiotics.

Frequency of isolation and drug susceptibility of bacterial strains isolated from child oncohematological patients 2011-2014: A single center study.

BACKGROUND: Infections in pediatric patients with oncohematological diseases pose a huge therapeutic and diagnostic problem. OBJECTIVES: The aim of the study was to investigate the etiology of bacteremia and the antibiotic susceptibility of pathogenic and colonizing bacterial strains in pediatric oncohematological patients. MATERIAL AND METHODS: In the period 2011-2014, 17,209 positive test results, including 1,129 positive blood cultures, were subjected to a detailed analysis. The assessment of drug susceptibility was conducted in accordance with the CLSI (American), EUCAST (European), and KORLD (Polish) recommendations. RESULTS: A high percentage (86-91%) of negative blood culture results was demonstrated. A predominance of Gram-positive bacteria was seen in all years (60-70%) in contrast to Gram-negative strains (30-40%). Coagulase-negative staphylococci (CNS) were the strains most frequently isolated from blood (41-47%) among all bacterial strains. Susceptibility to linezolid and vancomycin was 96-100%, and to teicoplanin 82-96%. Methicyllin-resistant coagulase-negative Staphylococcus (MRCNS) were isolated in 77-86%. All Staphylococcus aureus (S. aureus) strains were susceptible to glycopeptides and linezolid, while Enterococcus spp. was susceptible to linezolid. Apart from the year 2014, no methicillin-resistant S. aureus (MRSA) were isolated. Enterobacteriaceae (EN) were the most susceptible to imipenem and meropenem (91-100%) as well as to amikacin (77-93%). From 2013 to 2014, non-fermentative rods (NF) isolated from blood were less susceptible to imipenem and meropenem (71% and 67-71%, respectively) than to other antibiotics. It has been shown that strains isolated from blood have a statistically significantly different susceptibility to antibiotics (CNS and EN are less and NF is more susceptible) than those existing as colonizing flora. CONCLUSIONS: Our results show that choosing appropriate antibiotics for treating infection in children with oncohematological diseases based on antibiograms for colonizing flora may be difficult because they may not take into account the more resistant strains. According to the antibiotic susceptibility of the strains isolated from blood in our center, the most viable active empirical and carbapenem-saving therapy could be conducted with piperacillin/tazobactam or cefepime.

Nitric oxide releasing vascular catheters for eradicating bacterial infection.

The interaction of blood proteins with an implant surface is not only a fundamental phenomenon but is also key to several important medical complications. Plasma proteins binding on the surface of intravascular catheters can promote bacterial adhesion leading to the risk of local and systemic complications such as catheter-related blood infections (CRBIs). The incidences of CRBIs in the United States amount to more than 250,000 cases/year with an attributable mortality of up to 35% and an annual healthcare expenditure of $2.3 billion approximately. This demands the development of truly nonthrombogenic and antimicrobial catheters. In the present study, catheters were fabricated by incorporating a nitric oxide (NO) donor molecule, S-nitroso-N-acetyl-penicillamine (SNAP) in a hydrophobic medical grade polymer, Elasteon-E2As. NO offers antithrombotic and antibacterial attributes without promoting drug resistance and cytotoxicity. E2As-SNAP catheters were first coated with fibrinogen, a blood plasma protein plays a key role in clot formation and eventual bacterial adhesion to the implant surface. The suitability of the catheters for biomedical applications was tested in vitro for contact angle, NO release kinetics, inhibition of bacteria, and absence of cytotoxicity toward mammalian cells. The highly hydrophobic catheters released NO in the physiological range that inhibited >99% bacterial viability on fibrinogen-coated catheters in a 24 h study. No toxic response of E2As-SNAP catheters leachate was observed using a standard cytotoxicity assay with mouse fibroblast cells. Overall, the results showed that the E2As-SNAP catheters can inhibit viable bacteria even in the presence of blood proteins without causing a cytotoxic response. The fundamentals of this study are applicable to other blood-contacting medical devices as well. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 106B: 2849-2857, 2018.

Improved treatment of systemic blood infections using antibiotics with extracorporeal opsonin hemoadsorption.

Here we describe development of an extracorporeal hemoadsorption device for sepsis therapy that employs commercially available polysulfone or polyethersulfone hollow fiber filters similar to those used clinically for hemodialysis, covalently coated with a genetically engineered form of the human opsonin Mannose Binding Lectin linked to an Fc domain (FcMBL) that can cleanse a broad range of pathogens and endotoxin from flowing blood without having to first determine their identity. When tested with human whole blood in vitro, the FcMBL hemoadsorption filter (FcMBL-HF) produced efficient (90-99%) removal of Gram negative (Escherichia coli) and positive (Staphylococcus aureus) bacteria, fungi (Candida albicans) and lipopolysaccharide (LPS)-endotoxin. When tested in rats, extracorporeal therapy with the FcMBL-HF device reduced circulating pathogen and endotoxin levels by more than 99%, and prevented pathogen engraftment and inflammatory cell recruitment in the spleen, lung, liver and kidney when compared to controls. Studies in rats revealed that treatment with bacteriocidal antibiotics resulted in a major increase in the release of microbial fragments or 'pathogen-associated molecular patterns' (PAMPs) in vivo, and that these PAMPs were efficiently removed from blood within 2 h using the FcMBL-HF; in contrast, they remained at high levels in animals treated with antibiotics alone. Importantly, cleansing of PAMPs from the blood of antibiotic-treated animals with the FcMBL-hemoadsorbent device resulted in reduced organ pathogen and endotoxin loads, suppressed inflammatory responses, and resulted in more stable vital signs compared to treatment with antibiotics alone. As PAMPs trigger the cytokine cascades that lead to development of systemic inflammatory response syndrome and contribute to septic shock and death, co-administration of FcMBL-hemoadsorption with antibiotics could offer a more effective approach to sepsis therapy.