Key Points• In canine S aureus pneumonia, first randomized blinded trial showing blood transfused at end of storage period increases mortality.• Increased in vivo hemolysis, cell-free hemoglobin, pulmonary hypertension, tissue damage, and gas exchange abnormalities each contributed.Two-year-old purpose-bred beagles (n ؍ 24) infected with Staphylococcus aureus pneumonia were randomized in a blinded fashion for exchange transfusion with either 7-or 42-day-old canine universal donor blood (80 mL/kg in 4 divided doses). Older blood increased mortality (P ؍ .0005), the arterial alveolar oxygen gradient (24-48 hours after infection; P < .01), systemic and pulmonary pressures during transfusion (4-16 hours) and pulmonary pressures for ϳ 10 hours afterward (all P < .02). Further, older blood caused more severe lung damage, evidenced by increased necrosis, hemorrhage, and thrombosis (P ؍ .03) noted at the infection site postmortem. Plasma cell-free hemoglobin and nitric oxide (NO) consumption capability were elevated and haptoglobin levels were decreased with older blood during and for 32 hours after transfusion (all P < .03). The low haptoglobin (r ؍ 0.61; P ؍ .003) and high NO consumption levels at 24 hours (r ؍ ؊0.76; P < .0001) were associated with poor survival. Plasma nontransferrin-bound and labile iron were significantly elevated only during transfusion (both P ؍ .03) and not associated with survival (P ؍ NS). These data from canines indicate that older blood after transfusion has a propensity to hemolyze in vivo, releases vasoconstrictive cell-free hemoglobin over days, worsens pulmonary hypertension, gas exchange, and ischemic vascular damage in the infected lung, and thereby increases the risk of death from transfusion. (Blood. 2013;121(9):1663-1672) IntroductionTransfusion of red blood cells (RBCs) is one of the most commonly used, potentially lifesaving medical therapies. Each year, some 80.7 million units of blood are collected in 167 countries worldwide, and approximately 15 million units are collected and transfused in the United States alone. 1,2 RBCs can be stored for up to 42 days to meet inventory needs, and by standard practice the oldest blood is usually used first ("first in, first out"). Food and Drug Administration (FDA) regulations only stipulate that at the end of the storage period 75% of the cells remain in the circulation at 24 hours after transfusion and that hemolysis in the storage bag does not exceed 1%, 3 no other product specification of quality is required. Although 6-week-old stored blood meets current FDA standards, laboratory and clinical studies have raised concerns that "older" blood may not be as safe as blood stored for a shorter duration. [4][5][6][7][8] Refrigerated storage of blood results in a "storage lesion" characterized by rheologic changes, metabolic derangements, changes in oxygen affinity and delivery, oxidative injury to lipids and proteins, RBC shape change, loss of membrane carbohydrates, and reduced RBC lifespan. [8][9][10] The storage lesion resu...
Characterization of the gut microbiota in HT patients confirmed that HT patients have altered gut microbiota and that gut microbiota are correlated with clinical parameters, suggesting that microbiome composition data could be used for disease diagnosis. Further investigation is required to understand better the role of the gut microbiota in the pathogenesis of HT.
BackgroundMetagenomic next-generation sequencing (mNGS) is emerging as a promising technique for pathogens detection. However, reports on the application of mNGS in mixed pulmonary infection remain scarce.MethodsFrom July 2018 to March 2019, 55 cases were enrolled in this retrospective analysis. Cases were classified into mixed pulmonary infection (36 [65.5%]) and non-mixed pulmonary infection (19 [34.5%]) according to primary diagnoses. The performances of mNGS and conventional test on mixed pulmonary infection diagnosis and pathogen identification were compared.ResultsThe sensitivity of mNGS in mixed pulmonary infection diagnosis was much higher than that of conventional test (97.2% vs 13.9%; P < 0.01), but the specificity was the opposite (63.2% vs 94.7%; P = 0.07). The positive predictive value of mNGS was 83.3% (95% CI, 68.0–92.5%), and the negative predictive value was 92.3% (95% CI, 62.1–99.6%). A total of 5 (9.1%) cases were identified as mixed pulmonary infection by both conventional tests and mNGS, however, the pathogens identification results were consistent between these two methods in only 1 (1.8%) case. In summary, the pathogens detected by mNGS in 3 (5.5%) cases were consistent with those by conventional test, and only 1 (1.8%) case was mixed pulmonary infection. According to our data, mNGS had a broader spectrum for pathogen detection than conventional tests. In particular, application of mNGS improved the diagnosis of pulmonary fungal infections. Within the 55 cases, mNGS detected and identified fungi in 31 (56.4%) cases, of which only 10 (18.2%) cases were positive for the same fungi by conventional test. The most common pathogen detected by mNGS was Human cytomegalovirus in our study, which was identified in 19 (34.5%) cases of mixed pulmonary infection. Human cytomegalovirus and Pneumocystis jirovecii, which were detected in 7 (12.7%) cases, were the most common co-pathogens in the group of mixed pulmonary infection.ConclusionsmNGS is a promising technique to detect co-pathogens in mixed pulmonary infection, with potential benefits in speed and sensitivity.Trial registration(retrospectively registered): ChiCTR1900023727. Registrated 9 JUNE 2019.
• Washing older blood before transfusion reduces plasma iron, improving outcomes from established infection in canines.• In contrast, washing fresh blood before transfusion increases in vivo plasma CFH release, worsening outcomes.In a randomized controlled blinded trial, 2-year-old purpose-bred beagles (n 5 24), with Staphylococcus aureus pneumonia, were exchanged-transfused with either 7-or 42-dayold washed or unwashed canine universal donor blood (80 mL/kg in 4 divided doses). Washing red cells (RBC) before transfusion had a significantly different effect on canine survival, multiple organ injury, plasma iron, and cell-free hemoglobin (CFH) levels depending on the age of stored blood (all, P < .05 for interactions). Washing older units of blood improved survival rates, shock score, lung injury, cardiac performance and liver function, and reduced levels of non-transferrin bound iron and plasma labile iron. In contrast, washing fresh blood worsened all these same clinical parameters and increased CFH levels. Our data indicate that transfusion of fresh blood, which results in less hemolysis, CFH, and iron release, is less toxic than transfusion of older blood in critically ill infected subjects. However, washing older blood prevented elevations in plasma circulating iron and improved survival and multiple organ injury in animals with an established pulmonary infection. Our data suggest that fresh blood should not be washed routinely because, in a setting of established infection, washed RBC are prone to release CFH and result in worsened clinical outcomes. (Blood. 2014;123(9):1403-1411 IntroductionTransfusion of older stored canine universal donor blood in a canine model of experimental Staphylococcus aureus pneumonia results in markedly increased lung injury and mortality rates.1 Transfusion with older blood is also associated with increased levels of cell-free hemoglobin (CFH), transferrin bound iron (TBI), non-TBI (NTBI) and plasma labile iron (PLI). NTBI represents iron excess bound to proteins that do not normally handle circulating iron, and PLI is the toxic iron moiety in plasma. Whereas increased nitric oxide scavenging by CFH causing vasoconstriction and vascular injury and increased available iron promoting bacterial growth represent 2 candidate mechanisms of injury, multiple other biological changes have been documented with increasing blood storage interval.2,3 Some of these changes involve the release into the plasma of biologically active proteins, microvesicles, potassium, acid, and plasticizer, all of which can be reduced by means of standard red cell (RBC) washing procedures. [4][5][6][7][8][9][10] The clinical effect(s) of washing on the RBC storage lesion has not been studied.RBC washing has long been performed to reduce potassium levels in stored blood transfused to neonates, debris from RBCs recovered during surgery, cryoprotectant glycerol from cryopreserved RBCs, and plasma proteins from blood intended for patients who have been sensitized to those proteins.11-13 Automated cell washers cap...
Highlights d ZIKV preferentially infects glioblastoma stem cells (GSCs) rather than neural precursor cells d ZIKV kills SOX2 + cells from a diverse array of malignant brain tumors d SOX2 determines susceptibility to ZIKV infection with reduced antiviral responses d Integrin a v b 5 is a GSC marker and promotes Zika virus infection of GSCs
Although broad knowledge of influenza viral pneumonia has been established, the significance of non-influenza respiratory viruses in community-acquired pneumonia (CAP) and their impact on clinical outcomes remains unclear, especially in the non-immunocompromised adult population.Hospitalised immunocompetent patients with CAP were prospectively recruited from 34 hospitals in mainland China. Respiratory viruses were detected by molecular methods. Comparisons were conducted between influenza and non-influenza viral infection groups.In total, 915 out of 2336 adult patients with viral infection were enrolled in the analysis, with influenza virus (28.4%) the most frequently detected virus, followed by respiratory syncytial virus (3.6%), adenovirus (3.3%), human coronavirus (3.0%), parainfluenza virus (2.2%), human rhinovirus (1.8%) and human metapneumovirus (1.5%). Non-influenza viral infections accounted for 27.4% of viral pneumonia. Consolidation was more frequently observed in patients with adenovirus infection. The occurrence of complications such as sepsis (40.1% versus 39.6%; p=0.890) and hypoxaemia (40.1% versus 37.2%; p=0.449) during hospitalisation in the influenza viral infection group did not differ from that of the non-influenza viral infection group. Compared with influenza virus infection, the multivariable adjusted odds ratios of CURB-65 (confusion, urea >7 mmol·L−1, respiratory rate ≥30 breaths·min−1, blood pressure <90 mmHg (systolic) or ≤60 mmHg (diastolic), age ≥65 years) ≥3, arterial oxygen tension/inspiratory oxygen fraction <200 mmHg, and occurrence of sepsis and hypoxaemia for non-influenza respiratory virus infection were 0.87 (95% CI 0.26–2.84), 0.72 (95% CI 0.26–1.98), 1.00 (95% CI 0.63–1.58) and 1.05 (95% CI 0.66–1.65), respectively. The hazard ratio of 90-day mortality was 0.51 (95% CI 0.13–1.91).The high incidence of complications in non-influenza viral pneumonia and similar impact of non-influenza respiratory viruses relative to influenza virus on disease severity and outcomes suggest more attention should be given to CAP caused by non-influenza respiratory viruses.
The aim of this study was to evaluate the value of metagenomic next-generation sequencing (mNGS) in peripheral pulmonary infection management by comparing the diagnostic yield of mNGS and traditional pathogen detection methods on interventional specimens obtained by bronchoscopy. Patients and Methods: This study enrolled patients suspected with pulmonary infection who were admitted to Tianjin Medical University General Hospital from June 2018 to August 2019. Specimens were obtained from bronchoscopy for mNGS analysis and traditional pathogen detection (including bronchoalveolar lavage fluid microbial culture, smear microscopy, and lung biopsy histopathology), and the diagnostic yields were compared between mNGS and traditional methods to evaluate the diagnostic value of mNGS in peripheral pulmonary infection diagnosis. Results: In this study, by comparing mNGS with traditional pathogen detection, the results indicated that, first, mNGS identified at least one microbial species in almost 89% of the patients with pulmonary infection; second, mNGS detected microbes related to human diseases in 94.49% of samples from pulmonary infection patients who had received negative results from traditional pathogen detection; third, the accuracy and sensitivity of mNGS are higher than those of traditional pathogen detection; and, finally, mNGS could simultaneously detect and identify a large variety of pathogens. Conclusion: Metagenomic NGS analysis provided fast and precise pathogen detection and identification, contributing to prompt and accurate treatment of peripheral pulmonary infection.
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