Your search keyword '"Mangalmurti NS"' showing total 9 results

1. Banked RBCs Increase Endothelial Cell Oxidative Stress through Advanced Glycation Endproducts.

Author

Mangalmurti, NS, primary, Albelda, SM, additional, Choi, AM, additional, and Lee, JS, additional

Published

2009

2. Transfusion of Stored Red Cells during Endotoxemia Promotes Lung Injury.

Author

Mangalmurti, NS, primary, Hulver, M, additional, Ranganathan, M, additional, and Lee, JS, additional

Published

2009

3. ExRNA Takes a Toll in Sepsis-associated Lung Injury.

Author

Lam LKM and Mangalmurti NS

Subjects

Humans, Toll-Like Receptor 7 genetics, Lung Injury, MicroRNAs, Respiratory Distress Syndrome, Sepsis complications

Published

2022

4. Trefoil Factor Family: A Troika for Lung Repair and Regeneration.

Author

Rossi HL, Ortiz-Carpena JF, Tucker D, Vaughan AE, Mangalmurti NS, Cohen NA, and Herbert DR

Subjects

Animals, Lung metabolism, Mice, Peptides metabolism, Proteins, Trefoil Factor-2, Trefoil Factors

Abstract

Tissue damage in the upper and lower airways caused by mechanical abrasion, noxious chemicals, or pathogenic organisms must be followed by rapid restorative processes; otherwise, persistent immunopathology and disease may ensue. This review will discuss evidence for the important role served by trefoil factor (TFF) family members in healthy and diseased airways of humans and rodents. Collectively, these peptides serve to both maintain and restore homeostasis through their regulation of the mucous layer and their control of cell motility, cell differentiation, and immune function in the upper and lower airways. We will also discuss important differences in which trefoil member tracks with homeostasis and disease between humans and mice, which poses a challenge for research in this area. Moreover, we discuss new evidence supporting newly identified receptor binding partners in the leucine-rich repeat and immunoglobulin-like domain-containing NoGo (LINGO) family in mediating the biological effects of TFF proteins in mouse models of epithelial repair and infection. Recent advances in our knowledge regarding TFF peptides suggest that they may be reasonable therapeutic targets in the treatment of upper and lower airway diseases of diverse etiologies. Further work understanding their role in airway homeostasis, repair, and inflammation will benefit from these newly uncovered receptor-ligand interactions.

Published

2022

5. Update on the Features and Measurements of Experimental Acute Lung Injury in Animals: An Official American Thoracic Society Workshop Report.

Author

Kulkarni HS, Lee JS, Bastarache JA, Kuebler WM, Downey GP, Albaiceta GM, Altemeier WA, Artigas A, Bates JHT, Calfee CS, Dela Cruz CS, Dickson RP, Englert JA, Everitt JI, Fessler MB, Gelman AE, Gowdy KM, Groshong SD, Herold S, Homer RJ, Horowitz JC, Hsia CCW, Kurahashi K, Laubach VE, Looney MR, Lucas R, Mangalmurti NS, Manicone AM, Martin TR, Matalon S, Matthay MA, McAuley DF, McGrath-Morrow SA, Mizgerd JP, Montgomery SA, Moore BB, Noël A, Perlman CE, Reilly JP, Schmidt EP, Skerrett SJ, Suber TL, Summers C, Suratt BT, Takata M, Tuder R, Uhlig S, Witzenrath M, Zemans RL, and Matute-Bello G

Subjects

Acute Lung Injury immunology, Animals, Acute Lung Injury pathology, Inflammation physiopathology, Research Report trends

Abstract

Advancements in methods, technology, and our understanding of the pathobiology of lung injury have created the need to update the definition of experimental acute lung injury (ALI). We queried 50 participants with expertise in ALI and acute respiratory distress syndrome using a Delphi method composed of a series of electronic surveys and a virtual workshop. We propose that ALI presents as a "multidimensional entity" characterized by four "domains" that reflect the key pathophysiologic features and underlying biology of human acute respiratory distress syndrome. These domains are 1 ) histological evidence of tissue injury, 2 ) alteration of the alveolar-capillary barrier, 3 ) presence of an inflammatory response, and 4 ) physiologic dysfunction. For each domain, we present "relevant measurements," defined as those proposed by at least 30% of respondents. We propose that experimental ALI encompasses a continuum of models ranging from those focusing on gaining specific mechanistic insights to those primarily concerned with preclinical testing of novel therapeutics or interventions. We suggest that mechanistic studies may justifiably focus on a single domain of lung injury, but models must document alterations of at least three of the four domains to qualify as "experimental ALI." Finally, we propose that a time criterion defining "acute" in ALI remains relevant, but the actual time may vary based on the specific model and the aspect of injury being modeled. The continuum concept of ALI increases the flexibility and applicability of the definition to multiple models while increasing the likelihood of translating preclinical findings to critically ill patients.

Published

2022

6. COVID-19-associated Acute Respiratory Distress Syndrome Clarified: A Vascular Endotype?

Author

Mangalmurti NS, Reilly JP, Cines DB, Meyer NJ, Hunter CA, and Vaughan AE

Subjects

COVID-19, Coronavirus Infections epidemiology, Humans, Pandemics, Pneumonia, Viral epidemiology, Respiratory Distress Syndrome diagnosis, Respiratory Distress Syndrome physiopathology, SARS-CoV-2, Betacoronavirus, Coronavirus Infections complications, Pneumonia, Viral complications, Pulmonary Circulation physiology, Respiratory Distress Syndrome etiology

Published

2020

7. Red Blood Cells Homeostatically Bind Mitochondrial DNA through TLR9 to Maintain Quiescence and to Prevent Lung Injury.

Author

Hotz MJ, Qing D, Shashaty MGS, Zhang P, Faust H, Sondheimer N, Rivella S, Worthen GS, and Mangalmurti NS

Subjects

Adolescent, Adult, Aged, Animals, DNA, Mitochondrial immunology, Disease Models, Animal, Erythrocytes immunology, Female, Homeostasis, Humans, Lung Injury blood, Lung Injury etiology, Male, Mice, Middle Aged, Pneumonia blood, Pneumonia complications, Reference Values, Toll-Like Receptor 9 genetics, Toll-Like Receptor 9 immunology, Young Adult, DNA, Mitochondrial blood, Erythrocytes physiology, Lung Injury prevention & control, Pneumonia prevention & control, Toll-Like Receptor 9 blood

Abstract

Rationale: Potentially hazardous CpG-containing cell-free mitochondrial DNA (cf-mtDNA) is routinely released into the circulation and is associated with morbidity and mortality in critically ill patients. How the body avoids inappropriate innate immune activation by cf-mtDNA remains unknown. Because red blood cells (RBCs) modulate innate immune responses by scavenging chemokines, we hypothesized that RBCs may attenuate CpG-induced lung inflammation through direct scavenging of CpG-containing DNA., Objectives: To determine the mechanisms of CpG-DNA binding to RBCs and the effects of RBC-mediated DNA scavenging on lung inflammation., Methods: mtDNA on murine RBCs was measured under basal conditions and after systemic inflammation. mtDNA content on human RBCs from healthy control subjects and trauma patients was measured. Toll-like receptor 9 (TLR9) expression on RBCs and TLR9-dependent binding of CpG-DNA to RBCs were determined. A murine model of RBC transfusion after CpG-DNA-induced lung injury was used to investigate the role of RBC-mediated DNA scavenging in mitigating lung injury in vivo., Measurements and Main Results: Under basal conditions, RBCs bind CpG-DNA. The plasma-to-RBC mtDNA ratio is low in naive mice and in healthy volunteers but increases after systemic inflammation, demonstrating that the majority of cf-mtDNA is RBC-bound under homeostatic conditions and that the unbound fraction increases during inflammation. RBCs express TLR9 and bind CpG-DNA through TLR9. Loss of TLR9-dependent RBC-mediated CpG-DNA scavenging increased lung injury in vivo., Conclusions: RBCs homeostatically bind mtDNA, and RBC-mediated DNA scavenging is essential in mitigating lung injury after CpG-DNA. Our data suggest a role for RBCs in regulating lung inflammation during disease states where cf-mtDNA is elevated, such as sepsis and trauma.

Published

2018

8. Red blood cells induce necroptosis of lung endothelial cells and increase susceptibility to lung inflammation.

Author

Qing DY, Conegliano D, Shashaty MG, Seo J, Reilly JP, Worthen GS, Huh D, Meyer NJ, and Mangalmurti NS

Subjects

Animals, Critical Illness, Disease Models, Animal, HMGB1 Protein immunology, Humans, In Vitro Techniques, Mice, Middle Aged, Necrosis, Endothelial Cells pathology, Erythrocyte Transfusion adverse effects, HMGB1 Protein physiology, Lung pathology, Pneumonia etiology, Respiratory Distress Syndrome etiology

Abstract

Rationale: Red blood cell (RBC) transfusions are associated with increased risk of acute respiratory distress syndrome (ARDS) in the critically ill, yet the mechanisms for enhanced susceptibility to ARDS conferred by RBC transfusions remain unknown., Objectives: To determine the mechanisms of lung endothelial cell (EC) High Mobility Group Box 1 (HMGB1) release following exposure to RBCs and to determine whether RBC transfusion increases susceptibility to lung inflammation in vivo through release of the danger signal HMGB1., Methods: In vitro studies examining human lung EC viability and HMGB1 release following exposure to allogenic RBCs were conducted under static conditions and using a microengineered model of RBC perfusion. The plasma from transfused and nontransfused patients with severe sepsis was examined for markers of cellular injury. A murine model of RBC transfusion followed by LPS administration was used to determine the effects of RBC transfusion and HMGB1 release on LPS-induced lung inflammation., Measurements and Main Results: After incubation with RBCs, lung ECs underwent regulated necrotic cell death (necroptosis) and released the essential mediator of necroptosis, receptor-interacting serine/threonine-protein kinase 3 (RIP3), and HMGB1. RIP3 was detectable in the plasma of patients with severe sepsis, and was increased with blood transfusion and among nonsurvivors of sepsis. RBC transfusion sensitized mice to LPS-induced lung inflammation through release of the danger signal HMGB1., Conclusions: RBC transfusion enhances susceptibility to lung inflammation through release of HMGB1 and induces necroptosis of lung EC. Necroptosis and subsequent danger signal release is a novel mechanism of injury following transfusion that may account for the increased risk of ARDS in critically ill transfused patients.

Published

2014

9. Pharmacologic activation of the innate immune system to prevent respiratory viral infections.

Author

Cheng G, Wang LC, Fridlender ZG, Cheng GS, Chen B, Mangalmurti NS, Saloura V, Yu Z, Kapoor V, Mozdzanowska K, Moon E, Sun J, Kreindler JL, Cohen NA, Caton AJ, Erikson J, and Albelda SM

Subjects

Animals, Antineoplastic Agents pharmacology, Bronchi virology, Epithelial Cells virology, Female, Humans, Immune System, Immunity, Innate, Influenza A Virus, H1N1 Subtype immunology, Influenza, Human metabolism, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Respiratory Tract Infections immunology, Virus Diseases immunology, Xanthones pharmacology, Respiratory Tract Infections prevention & control, Respiratory Tract Infections virology, Virus Diseases prevention & control

Abstract

Drugs that can rapidly inhibit respiratory infection from influenza or other respiratory pathogens are needed. One approach is to engage primary innate immune defenses against viral infection, such as activating the IFN pathway. In this study, we report that a small, cell-permeable compound called 5,6-di-methylxanthenone-4-acetic acid (DMXAA) can induce protection against vesicular stomatitis virus in vitro and H1N1 influenza A virus in vitro and in vivo through innate immune activation. Using the mouse C10 bronchial epithelial cell line and primary cultures of nasal epithelial cells, we demonstrate DMXAA activates the IFN regulatory factor-3 pathway leading to production of IFN-β and subsequent high-level induction of IFN-β-dependent proteins, such as myxovirus resistance 1 (Mx1) and 2',5'-oligoadenylate synthetase 1 (OAS1). Mice treated with DMXAA intranasally elevate mRNA/protein expression of Mx1 and OAS1 in the nasal mucosa, trachea, and lung. When challenged intranasally with a lethal dose of H1N1 influenza A virus, DMXAA reduced viral titers in the lungs and protected 80% of mice from death, even when given at 24 hours before infection. These data show that agents, like DMXAA, that can directly activate innate immune pathways, such as the IFN regulatory factor-3/IFN-β system, in respiratory epithelial cells can be used to protect from influenza pneumonia and potentially in other respiratory viral infections. Development of this approach in humans could be valuable for protecting health care professionals and "first responders" in the early stages of viral pandemics or bioterror attacks.

Published

2011