Your search keyword '"Ostroff, Rachel"' showing total 239 results

1. Defining the serum proteomic signature of hepatic steatosis, inflammation, ballooning and fibrosis in non-alcoholic fatty liver disease

Author

Sanyal, Arun J, Williams, Stephen A, Lavine, Joel E, Neuschwander-Tetri, Brent A, Alexander, Leigh, Ostroff, Rachel, Biegel, Hannah, Kowdley, Kris V, Chalasani, Naga, Dasarathy, Srinivasan, Diehl, Anna Mae, Loomba, Rohit, Hameed, Bilal, Behling, Cynthia, Kleiner, David E, Karpen, Saul J, Williams, Jessica, Jia, Yi, Yates, Katherine P, and Tonascia, James

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Chronic Liver Disease and Cirrhosis, Prevention, Liver Disease, Biotechnology, Hepatitis, Digestive Diseases, 4.1 Discovery and preclinical testing of markers and technologies, Good Health and Well Being, Humans, Biopsy, Fibrosis, Inflammation, Liver, Liver Cirrhosis, Non-alcoholic Fatty Liver Disease, Pioglitazone, Proteomics, Vitamin E, Nonalcoholic fatty liver disease, Nonalcoholic steatohepatitis, NAFLD activity score, fibrosis stage, cirrhosis, stea-tohepatitis, steatosis, hepatocellular ballooning, lobular inflammation, fibrosis, proteomics, aptamers, steatohepatitis, Public Health and Health Services, Gastroenterology & Hepatology, Clinical sciences

Abstract

Background & aimsDespite recent progress, non-invasive tests for the diagnostic assessment and monitoring of non-alcoholic fatty liver disease (NAFLD) remain an unmet need. Herein, we aimed to identify diagnostic signatures of the key histological features of NAFLD.MethodsUsing modified-aptamer proteomics, we assayed 5,220 proteins in each of 2,852 single serum samples from 636 individuals with histologically confirmed NAFLD. We developed and validated dichotomized protein-phenotype models to identify clinically relevant severities of steatosis (grade 0 vs. 1-3), hepatocellular ballooning (0 vs. 1 or 2), lobular inflammation (0-1 vs. 2-3) and fibrosis (stages 0-1 vs. 2-4).ResultsThe AUCs of the four protein models, based on 37 analytes (18 not previously linked to NAFLD), for the diagnosis of their respective components (at a clinically relevant severity) in training/paired validation sets were: fibrosis (AUC 0.92/0.85); steatosis (AUC 0.95/0.79), inflammation (AUC 0.83/0.72), and ballooning (AUC 0.87/0.83). An additional outcome, at-risk NASH, defined as steatohepatitis with NAFLD activity score ≥4 (with a score of at least 1 for each of its components) and fibrosis stage ≥2, was predicted by multiplying the outputs of each individual component model (AUC 0.93/0.85). We further evaluated their ability to detect change in histology following treatment with placebo, pioglitazone, vitamin E or obeticholic acid. Component model scores significantly improved in the active therapies vs. placebo, and differential effects of vitamin E, pioglitazone, and obeticholic acid were identified.ConclusionsSerum protein scanning identified signatures corresponding to the key components of liver biopsy in NAFLD. The models developed were sufficiently sensitive to characterize the longitudinal change for three different drug interventions. These data support continued validation of these proteomic models to enable a "liquid biopsy"-based assessment of NAFLD.Clinical trial numberNot applicable.Impact and implicationsAn aptamer-based protein scan of serum proteins was performed to identify diagnostic signatures of the key histological features of non-alcoholic fatty liver disease (NAFLD), for which no approved non-invasive diagnostic tools are currently available. We also identified specific protein signatures related to the presence and severity of NAFLD and its histological components that were also sensitive to change over time. These are fundamental initial steps in establishing a serum proteome-based diagnostic signature of NASH and provide the rationale for using these signatures to test treatment response and to identify several novel targets for evaluation in the pathogenesis of NAFLD.

Published

2023

2. Biomarkers for staging fibrosis and non-alcoholic steatohepatitis in non-alcoholic fatty liver disease (the LITMUS project): a comparative diagnostic accuracy study

Author

Vali, Yasaman, Lee, Jenny, Boursier, Jerome, Petta, Salvatore, Wonders, Kristy, Tiniakos, Dina, Bedossa, Pierre, Geier, Andreas, Francque, Sven, Allison, Mike, Papatheodoridis, Georgios, Cortez-Pinto, Helena, Pais, Raluca, Dufour, Jean-Francois, Leeming, Diana Julie, Harrison, Stephen A, Chen, Yu, Cobbold, Jeremy F, Pavlides, Michael, Holleboom, Adriaan G, Yki-Jarvinen, Hannele, Crespo, Javier, Karsdal, Morten, Ostroff, Rachel, Zafarmand, Mohammad Hadi, Torstenson, Richard, Duffin, Kevin, Yunis, Carla, Brass, Clifford, Ekstedt, Mattias, Aithal, Guruprasad P, Schattenberg, Jörn M, Bugianesi, Elisabetta, Romero-Gomez, Manuel, Ratziu, Vlad, Anstee, Quentin M, and Bossuyt, Patrick M

Published

2023

3. Performance of non-invasive tests and histology for the prediction of clinical outcomes in patients with non-alcoholic fatty liver disease: an individual participant data meta-analysis

Author

Anstee, Quentin M, Daly, Ann K, Govaere, Olivier, Cockell, Simon, Tiniakos, Dina, Bedossa, Pierre, Burt, Alastair, Oakley, Fiona, Cordell, Heather J, Day, Christopher P, Wonders, Kristy, Missier, Paolo, McTeer, Matthew, Vale, Luke, Oluboyede, Yemi, Breckons, Matt, Bossuyt, Patrick M, Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Nieuwdorp, Max, Holleboom, Adriaan G, Verheij, Joanne, Ratziu, Vlad, Clément, Karine, Patino-Navarrete, Rafael, Pais, Raluca, Paradis, Valerie, Schuppan, Detlef, Schattenberg, Jörn M, Surabattula, Rambabu, Myneni, Sudha, Straub, Beate K, Vidal-Puig, Toni, Vacca, Michele, Rodrigues-Cuenca, Sergio, Allison, Mike, Kamzolas, Ioannis, Petsalaki, Evangelia, Campbell, Mark, Lelliott, Chris J, Davies, Susan, Orešič, Matej, Hyötyläinen, Tuulia, McGlinchey, Aiden, Mato, Jose M, Millet, Óscar, Dufour, Jean-François, Berzigotti, Annalisa, Masoodi, Mojgan, Pavlides, Michael, Harrison, Stephen, Neubauer, Stefan, Cobbold, Jeremy, Mozes, Ferenc, Akhtar, Salma, Olodo-Atitebi, Seliat, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Andersson, Anneli, Wigley, Ioan, Romero-Gómez, Manuel, Gómez-González, Emilio, Ampuero, Javier, Castell, Javier, Gallego-Durán, Rocío, Fernández, Isabel, Montero-Vallejo, Rocío, Karsdal, Morten, Rasmussen, Daniel Guldager Kring, Leeming, Diana Julie, Sinisi, Antonia, Musa, Kishwar, Sandt, Estelle, Tonini, Manuela, Bugianesi, Elisabetta, Rosso, Chiara, Armandi, Angelo, Marra, Fabio, Gastaldelli, Amalia, Svegliati, Gianluca, Boursier, Jérôme, Francque, Sven, Vonghia, Luisa, Driessen, Ann, Ekstedt, Mattias, Kechagias, Stergios, Yki-Järvinen, Hannele, Porthan, Kimmo, Arola, Johanna, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Rodrigues, Cecilia M P, Valenti, Luca, Pelusi, Serena, Petta, Salvatore, Pennisi, Grazia, Miele, Luca, Geier, Andreas, Trautwein, Christian, Reißing, Johanna, Aithal, Guruprasad P, Francis, Susan, Palaniyappan, Naaventhan, Bradley, Christopher, Hockings, Paul, Schneider, Moritz, Newsome, Philip, Hübscher, Stefan, Wenn, David, Rosenquist, Christian, Trylesinski, Aldo, Mayo, Rebeca, Alonso, Cristina, Duffin, Kevin, Perfield, James W, Chen, Yu, Yunis, Carla, Tuthill, Theresa, Harrington, Magdalena Alicia, Miller, Melissa, Chen, Yan, McLeod, Euan James, Ross, Trenton, Bernardo, Barbara, Schölch, Corinna, Ertle, Judith, Younes, Ramy, Oldenburger, Anouk, Coxson, Harvey, Ostroff, Rachel, Alexander, Leigh, Biegel, Hannah, Kjær, Mette Skalshøi, Harder, Lea Mørch, Davidsen, Peter, Ellegaard, Jens, Balp, Maria-Magdalena, Brass, Clifford, Jennings, Lori, Martic, Miljen, Löffler, Jürgen, Applegate, Douglas, Shankar, Sudha, Torstenson, Richard, Lindén, Daniel, Fournier-Poizat, Céline, Llorca, Anne, Kalutkiewicz, Michael, Pepin, Kay, Ehman, Richard, Horan, Gerald, Ho, Gideon, Tai, Dean, Chng, Elaine, Patterson, Scott D, Billin, Andrew, Doward, Lynda, Twiss, James, Thakker, Paresh, Derdak, Zoltan, Landgren, Henrik, Lackner, Carolin, Gouw, Annette, Hytiroglou, Prodromos, Mózes, Ferenc E, Lee, Jenny A, Alzoubi, Osama, Staufer, Katharina, Trauner, Michael, Paternostro, Rafael, Stauber, Rudolf E, van Dijk, Anne-Marieke, Mak, Anne Linde, de Saint Loup, Marc, Shima, Toshihide, Gaia, Silvia, Shalimar, Lupșor-Platon, Monica, Wong, Vincent Wai-Sun, Li, Guanlin, Wong, Grace Lai-Hung, Karlas, Thomas, Wiegand, Johannes, Sebastiani, Giada, Tsochatzis, Emmanuel, Liguori, Antonio, Yoneda, Masato, Nakajima, Atsushi, Hagström, Hannes, Akbari, Camilla, Hirooka, Masashi, Chan, Wah-Kheong, Mahadeva, Sanjiv, Rajaram, Ruveena, Zheng, Ming-Hua, George, Jacob, Eslam, Mohammed, Viganò, Mauro, Ridolfo, Sofia, Aithal, Guruprasad Padur, Lee, Dae Ho, Nasr, Patrik, Cassinotto, Christophe, de Lédinghen, Victor, Mendoza, Yuly P, Noureddin, Mazen, Truong, Emily, and Harrison, Stephen A

Published

2023

4. HFrEF subphenotypes based on 4210 repeatedly measured circulating proteins are driven by different biological mechanisms

Author

Petersen, Teun B., de Bakker, Marie, Asselbergs, Folkert W., Harakalova, Magdalena, Akkerhuis, K. Martijn, Brugts, Jasper J., van Ramshorst, Jan, Lumbers, R. Thomas, Ostroff, Rachel M., Katsikis, Peter D., van der Spek, Peter J., Umans, Victor A., Boersma, Eric, Rizopoulos, Dimitris, and Kardys, Isabella

Published

2023

5. Proteomic signatures for identification of impaired glucose tolerance

Author

Carrasco-Zanini, Julia, Pietzner, Maik, Lindbohm, Joni V., Wheeler, Eleanor, Oerton, Erin, Kerrison, Nicola, Simpson, Missy, Westacott, Matthew, Drolet, Dan, Kivimaki, Mika, Ostroff, Rachel, Williams, Stephen A., Wareham, Nicholas J., and Langenberg, Claudia

Published

2022

6. Plasma protein patterns as comprehensive indicators of health

Author

Williams, Stephen A, Kivimaki, Mika, Langenberg, Claudia, Hingorani, Aroon D, Casas, JP, Bouchard, Claude, Jonasson, Christian, Sarzynski, Mark A, Shipley, Martin J, Alexander, Leigh, Ash, Jessica, Bauer, Tim, Chadwick, Jessica, Datta, Gargi, DeLisle, Robert Kirk, Hagar, Yolanda, Hinterberg, Michael, Ostroff, Rachel, Weiss, Sophie, Ganz, Peter, and Wareham, Nicholas J

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Nutrition, Behavioral and Social Science, Obesity, Prevention, Heart Disease, Cardiovascular, Generic health relevance, Metabolic and endocrine, Good Health and Well Being, Adipose Tissue, Blood Proteins, Body Composition, Exercise, Female, Humans, Intra-Abdominal Fat, Life Style, Liver, Male, Precision Medicine, Risk Factors, Medical and Health Sciences, Immunology, Biomedical and clinical sciences, Health sciences

Abstract

Proteins are effector molecules that mediate the functions of genes1,2 and modulate comorbidities3-10, behaviors and drug treatments11. They represent an enormous potential resource for personalized, systemic and data-driven diagnosis, prevention, monitoring and treatment. However, the concept of using plasma proteins for individualized health assessment across many health conditions simultaneously has not been tested. Here, we show that plasma protein expression patterns strongly encode for multiple different health states, future disease risks and lifestyle behaviors. We developed and validated protein-phenotype models for 11 different health indicators: liver fat, kidney filtration, percentage body fat, visceral fat mass, lean body mass, cardiopulmonary fitness, physical activity, alcohol consumption, cigarette smoking, diabetes risk and primary cardiovascular event risk. The analyses were prospectively planned, documented and executed at scale on archived samples and clinical data, with a total of ~85 million protein measurements in 16,894 participants. Our proof-of-concept study demonstrates that protein expression patterns reliably encode for many different health issues, and that large-scale protein scanning12-16 coupled with machine learning is viable for the development and future simultaneous delivery of multiple measures of health. We anticipate that, with further validation and the addition of more protein-phenotype models, this approach could enable a single-source, individualized so-called liquid health check.

Published

2019

7. Increased serum miR-193a-5p during non-alcoholic fatty liver disease progression: Diagnostic and mechanistic relevance

Author

Clark, James, Cordell, Heather J., Darlay, Rebecca, Day, Christopher P., Hardy, Tim, Liu, Yang-Lin, Oakley, Fiona, Palmer, Jeremy, Queen, Rachel, Wonders, Kristy, Bossuyt, Patrick M., Holleboom, Adriaan G., Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Clement, Karine, Pais, Raluca, Schuppan, Detlef, Allison, Michael, Cuenca, Sergio Rodriguez, Pellegrinelli, Vanessa, Vacca, Michele, Vidal-Puig, Antonio, Hyötyläinen, Tuulia, McGlinchey, Aidan, Orešič, Matej, Sen, Partho, Mato, Jose, Millet, Óscar, Dufour, Jean-Francois, Harrison, Stephen, Neubauer, Stefan, Pavlides, Michael, Mozes, Ferenc, Akhtar, Salma, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Erpicum, Charlotte, Romero-Gomez, Manuel, Gallego-Durán, Rocío, Fernández, Isabel, Karsdal, Morten, Leeming, Diana, Fisker, Mette Juul, Erhardtsen, Elisabeth, Rasmussen, Daniel, Qvist, Per, Sinisi, Antonia, Sandt, Estelle, Tonini, Maria Manuela, Parola, Maurizio, Rosso, Chiara, Marra, Fabio, Gastaldelli, Amalia, Francque, Sven, Kechagias, Stergios, Yki-Järvinen, Hannele, Porthan, Kimmo, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Valenti, Luca, Petta, Salvatore, Miele, Luca, Geier, Andreas, Trautwein, Christian, Hockings, Paul, Newsome, Phil, Wenn, David, Pereira Rodrigues, Cecília Maria, Hanf, Rémy, Chaumat, Pierre, Rosenquist, Christian, Trylesinski, Aldo, Ortiz, Pablo, Duffin, Kevin, Yunis, Carla, Miller, Melissa, Tuthill, Theresa, Ertle, Judith, Younes, Ramy, Alexander, Leigh, Ostroff, Rachel, Kjær, Mette Skalshøi, Mikkelsen, Lars Friis, Brass, Clifford, Jennings, Lori, Balp, Maria-Magdalena, Martic, Miljen, Hanauer, Guido, Shankar, Sudha, Torstenson, Richard, Fournier, Céline, Ehman, Richard, Kalutkiewicz, Michael, Pepin, Kay, Myers, Joel, Shevell, Diane, Ho, Gideon, Landgren, Henrik, Myers, Rob, Doward, Lynda, Whalley, Diane, Twiss, James, Johnson, Katherine, Leary, Peter J., Govaere, Olivier, Barter, Matthew J., Charlton, Sarah H., Cockell, Simon J., Tiniakos, Dina, Zatorska, Michalina, Bedossa, Pierre, Brosnan, M. Julia, Cobbold, Jeremy F., Ekstedt, Mattias, Aithal, Guruprasad P., Clément, Karine, Schattenberg, Jörn M., Boursier, Jerome, Ratziu, Vlad, Bugianesi, Elisabetta, Anstee, Quentin M., and Daly, Ann K.

Published

2022

8. Serum Proteomics and Plasma Fibulin-3 in Differentiation of Mesothelioma From Asbestos-Exposed Controls and Patients With Other Pleural Diseases

Author

Tsim, Selina, Alexander, Laura, Kelly, Caroline, Shaw, Ann, Hinsley, Samantha, Clark, Stephen, Evison, Matthew, Holme, Jayne, Cameron, Euan J., Sharma, Davand, Wright, Angela, Grundy, Seamus, Grieve, Douglas, Ionescu, Alina, Breen, David P., Paramasivam, Elankumaran, Psallidas, Ioannis, Mukherjee, Dipak, Chetty, Mahendran, Cox, Giles, Hart-Thomas, Alan, Naseer, Rehan, Edwards, John, Daneshvar, Cyrus, Panchal, Rakesh, Munavvar, Mohammed, Ostroff, Rachel, Alexander, Leigh, Hall, Holly, Neilson, Matthew, Miller, Crispin, McCormick, Carol, Thomson, Fiona, Chalmers, Anthony J., Maskell, Nick A., and Blyth, Kevin G.

Published

2021

9. Diagnostic accuracy of elastography and magnetic resonance imaging in patients with NAFLD: A systematic review and meta-analysis

Author

Anstee, Quentin, Daly, Ann, Johnson, Katherine, Govaere, Olivier, Cockell, Simon, Tiniakos, Dina, Bedossa, Pierre, Oakley, Fiona, Cordell, Heather, Day, Chris, Wonders, Kristy, Bossuyt, Patrick, Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Ratziu, Vlad, Clement, Karine, Pais, Raluca, Schuppan, Detlef, Schattenberg, Jörn, Vidal-Puig, Toni, Vacca, Michele, Rodrigues-Cuenca, Sergio, Allison, Mike, Kamzolas, Ioannis, Petsalaki, Evangelia, Oresic, Matej, Hyötyläinen, Tuulia, McGlinchey, Aiden, Mato, Jose M., Millet, Oscar, Dufour, Jean-François, Berzigotti, Annalisa, Pavlides, Michael, Harrison, Stephen, Neubauer, Stefan, Cobbold, Jeremy, Mozes, Ferenc, Akhtar, Salma, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Erpicum, Charlotte, Romero-Gómez, Manuel, Gómez-González, Emilio, Ampuero, Javier, Castell, Javier, Gallego-Durán, Rocío, Fernández, Isabel, Montero-Vallejo, Rocío, Karsdal, Morten, Erhardtsen, Elisabeth, Rasmussen, Daniel, Leeming, Diana Julie, Fisker, Mette Juul, Sinisi, Antonia, Musa, Kishwar, Betsou, Fay, Sandt, Estelle, Tonini, Manuela, Bugianesi, Elisabetta, Rosso, Chiara, Armandi, Angelo, Marra, Fabio, Gastaldelli, Amalia, Svegliati, Gianluca, Boursier, Jérôme, Francque, Sven, Vonghia, Luisa, Ekstedt, Mattias, Kechagias, Stergios, Yki-Jarvinen, Hannele, Luukkonen, Panu, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Valenti, Luca, Petta, Salvatore, Miele, Luca, Geier, Andreas, Trautwein, Christian, Aithal, Guru, Hockings, Paul, Newsome, Philip, Wenn, David, Pereira Rodrigues, Cecília Maria, Chaumat, Pierre, Hanf, Rémy, Trylesinski, Aldo, Ortiz, Pablo, Duffin, Kevin, Brosnan, Julia, Tuthill, Theresa, McLeod, Euan, Ertle, Judith, Younes, Ramy, Ostroff, Rachel, Alexander, Leigh, Kjær, Mette Skalshøi, Mikkelsen, Lars Friis, Balp, Maria-Magdalena, Brass, Clifford, Jennings, Lori, Martic, Miljen, Loeffler, Juergen, Hanauer, Guido, Shankar, Sudha, Fournier, Céline, Pepin, Kay, Ehman, Richard, Myers, Joel, Ho, Gideon, Torstenson, Richard, Myers, Rob, Doward, Lynda, Selvaraj, Emmanuel Anandraj, Mózes, Ferenc Emil, Jayaswal, Arjun Narayan Ajmer, Zafarmand, Mohammad Hadi, Lee, Jenny A., Levick, Christina Kim, Young, Liam Arnold Joseph, Palaniyappan, Naaventhan, Liu, Chang-Hai, Aithal, Guruprasad Padur, Brosnan, M. Julia, Tuthill, Theresa A., Anstee, Quentin M., Harrison, Stephen A., and Bossuyt, Patrick M.

Published

2021

10. Improving Assessment of Drug Safety Through Proteomics

Author

Williams, Stephen A, Murthy, Ashwin C, DeLisle, Robert K, Hyde, Craig, Malarstig, Anders, Ostroff, Rachel, Weiss, Sophie J, Segal, Mark R, and Ganz, Peter

Subjects

Pharmacology and Pharmaceutical Sciences, Biomedical and Clinical Sciences, Heart Disease, Prevention, Clinical Trials and Supportive Activities, Aging, Cardiovascular, Clinical Research, Biotechnology, Good Health and Well Being, Aged, Aldosterone, Anticholesteremic Agents, Biomarkers, Pharmacological, Case-Control Studies, Cholesterol Ester Transfer Proteins, Drug-Related Side Effects and Adverse Reactions, Early Diagnosis, Female, Heart Failure, Humans, Male, Middle Aged, Myocardial Infarction, Prognosis, Prospective Studies, Proteomics, Quinolines, Stroke, Survival Analysis, aptamers, biomarkers, peptides, precision medicine, prescription drugs, proteins, proteomics, Cardiorespiratory Medicine and Haematology, Clinical Sciences, Public Health and Health Services, Cardiovascular System & Hematology, Cardiovascular medicine and haematology, Clinical sciences, Sports science and exercise

Abstract

BackgroundEarly detection of adverse effects of novel therapies and understanding of their mechanisms could improve the safety and efficiency of drug development. We have retrospectively applied large-scale proteomics to blood samples from ILLUMINATE (Investigation of Lipid Level Management to Understand its Impact in Atherosclerotic Events), a trial of torcetrapib (a cholesterol ester transfer protein inhibitor), that involved 15 067 participants at high cardiovascular risk. ILLUMINATE was terminated at a median of 550 days because of significant absolute increases of 1.2% in cardiovascular events and 0.4% in mortality with torcetrapib. The aims of our analysis were to determine whether a proteomic analysis might reveal biological mechanisms responsible for these harmful effects and whether harmful effects of torcetrapib could have been detected early in the ILLUMINATE trial with proteomics.MethodsA nested case-control analysis of paired plasma samples at baseline and at 3 months was performed in 249 participants assigned to torcetrapib plus atorvastatin and 223 participants assigned to atorvastatin only. Within each treatment arm, cases with events were matched to controls 1:1. Main outcomes were a survey of 1129 proteins for discovery of biological pathways altered by torcetrapib and a 9-protein risk score validated to predict myocardial infarction, stroke, heart failure, or death.ResultsPlasma concentrations of 200 proteins changed significantly with torcetrapib. Their pathway analysis revealed unexpected and widespread changes in immune and inflammatory functions, as well as changes in endocrine systems, including in aldosterone function and glycemic control. At baseline, 9-protein risk scores were similar in the 2 treatment arms and higher in participants with subsequent events. At 3 months, the absolute 9-protein derived risk increased in the torcetrapib plus atorvastatin arm compared with the atorvastatin-only arm by 1.08% (P=0.0004). Thirty-seven proteins changed in the direction of increased risk of 49 proteins previously associated with cardiovascular and mortality risk.ConclusionsHeretofore unknown effects of torcetrapib were revealed in immune and inflammatory functions. A protein-based risk score predicted harm from torcetrapib within just 3 months. A protein-based risk assessment embedded within a large proteomic survey may prove to be useful in the evaluation of therapies to prevent harm to patients.Clinical trial registrationURL: https://www.clinicaltrials.gov. Unique identifier: NCT00134264.

Published

2018

11. SOMAmer reagents and the SomaScan platform: Chemically modified aptamers and their applications in therapeutics, diagnostics, and proteomics

Author

Schneider, Daniel J., primary, Lynch, Sean A., additional, Gelinas, Amy D., additional, Ostroff, Rachel M., additional, Rohloff, John C., additional, Williams, Preston, additional, Janjic, Nebojsa, additional, and Drolet, Daniel W., additional

Published

2022

12. Contributors

Author

Alameh, Mohamad-Gabriel, primary, Alcantara, Marice, additional, Alluin, Jessica, additional, Amero, Paola, additional, Arechavala-Gomeza, Virginia, additional, Calin, George A., additional, Corey, David R., additional, Cramer, Hagen, additional, Dammes, Niels, additional, Drolet, Daniel W., additional, Frederiksen, James, additional, Gelinas, Amy D., additional, Habib, Nagy A., additional, Hazan-Halevy, Inbal, additional, Holm, Kevin, additional, Janjic, Nebojsa, additional, Johnson, Krystal C., additional, Johnson, Samantha T., additional, Kon, Edo, additional, Kortylewski, Marcin, additional, Landesman-Milo, Dalit, additional, Lemaitre, Marc M., additional, Lincoln, Christopher, additional, Lopez-Berestein, Gabriel, additional, Lynch, Sean A., additional, Oncul, Selin, additional, Ostroff, Rachel M., additional, Peer, Dan, additional, Rodriguez-Aguayo, Cristian, additional, Rohloff, John C., additional, Rossi, Daniel, additional, Rossi, John J., additional, Rupp, Thomas M., additional, Schneider, Daniel J., additional, Soblechero-Martín, Patricia, additional, Song, Min-Sun, additional, Sood, Anil K., additional, Su, Yu-Lin, additional, Sullenger, Bruce A., additional, Voutila, Jon, additional, Weissman, Drew, additional, Williams, Preston, additional, Yu, Chunsong, additional, Yu, Haixiang, additional, Zhang, Zhuoran, additional, and Zhou, Jiehua, additional

Published

2022

13. Abstract 12671: Weight Loss Improves Cardiometabolic Health as Measured by Plasma Proteins in Individuals With Type 2 Diabetes

Author

Sattar, Naveed, Taheri, Shahrad, Welsh, Paul, Astling, David, Chadwick, Jessica, Hinterberg, Michael, Troth, Emma, Ostroff, Rachel, Zaghloul, Hadeel, Chagoury, Odette, Taylor, Roy, Lean, Michael, and Williams, Stephen A

Published

2022

14. Abstract 12012: Subphenotypes of Heart Failure With Reduced Ejection Fraction Based on Repeated Measurements of 4210 Circulating Proteins Are Driven by Protein Subsets Reflecting Different Biological Mechanisms

Author

Petersen, Teun B, de Bakker, Marie, Asselbergs, Folkert W, Akkerhuis, K. Martijn, Brugts, Jasper J, van Ramshorst, Jan, Lumbers, Tom, Ostroff, Rachel, Katsikis, Peter D, van der Spek, Peter J, Umans, Victor A, Boersma, Eric, Rizopoulos, Dimitris, and Kardys, Isabella

Published

2022

15. Abstract 11650: Cardiometabolic Disease Protein Signatures and Response to GLP-1 Receptor Agonist in the EXSCEL Clinical Trial

Author

Ostroff, Rachel, Green, Jennifer, Mentz, Robert J, Chadwick, Jessica, Hinterberg, Michael, Kureshi, Natasha, Simpson, Missy, Williams, Stephen A, Hernandez, Adrian F, Holman, Rury, Sattar, Naveed, and Shah, Svati H

Published

2022

16. An unbiased ranking of murine dietary models based on their proximity to human metabolic dysfunction-associated steatotic liver disease (MASLD)

Author

Vacca, Michele, Kamzolas, Ioannis, Harder, Lea Morch, Oakley, Fiona, Trautwein, Christian, Hatting, Maximilian, Ross, Trenton, Bernardo, Barbara, Oldenburger, Anouk, Hjuler, Sara Toftegaard, Ksiazek, Iwona, Linden, Daniel, Schuppan, Detlef, Rodriguez-Cuenca, Sergio, Tonini, Maria Manuela, Castaneda, Tamara R., Kannt, Aimo, Rodrigues, Cecilia M. P., Cockell, Simon, Govaere, Olivier, Daly, Ann K., Allison, Michael, de Lichtenberg, Kristian Honnens, Kim, Yong Ook, Lindblom, Anna, Oldham, Stephanie, Andreasson, Anne-Christine, Schlerman, Franklin, Marioneaux, Jonathon, Sanyal, Arun, Afonso, Marta B., Younes, Ramy, Amano, Yuichiro, Friedman, Scott L., Wang, Shuang, Bhattacharya, Dipankar, Simon, Eric, Paradis, Valerie, Burt, Alastair, Grypari, Ioanna Maria, Davies, Susan, Driessen, Ann, Yashiro, Hiroaki, Pors, Susanne, Andersen, Maja Worm, Feigh, Michael, Yunis, Carla, Bedossa, Pierre, Stewart, Michelle, Cater, Heather L., Wells, Sara, Schattenberg, Joern M., Anstee, Quentin M., Tiniakos, Dina, Perfield, James W., Petsalaki, Evangelia, Davidsen, Peter, Vidal-Puig, Antonio, Cordell, Heather J., Day, Christopher P., Wonders, Kristy, Missier, Paolo, McTeer, Matthew, Vale, Luke, Oluboyede, Yemi, Breckons, Matt, Boyle, Jo, Bossuyt, Patrick M., Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Nieuwdorp, Max, Holleboom, Adriaan G., Angelakis, Athanasios, Verheij, Joanne, Ratziu, Vlad, Clement, Karine, Patino-Navarrete, Rafael, Pais, Raluca, Surabattula, Rambabu, Myneni, Sudha, Straub, Beate K., Rodrigues-Cuenca, Sergio, Allison, Mike, Campbell, Mark, Lelliott, Chris J., Oresic, Matej, Hyotylainen, Tuulia, McGlinchey, Aidan, Mato, Jose M., Millet, Oscar, Dufour, Jean-Francois, Berzigotti, Annalisa, Masoodi, Mojgan, Lange, Naomi F., Pavlides, Michael, Harrison, Stephen, Neubauer, Stefan, Cobbold, Jeremy, Mozes, Ferenc, Akhtar, Salma, Olodo-Atitebi, Seliat, Banerjee, Rajarshi, Shumbayawonda, Elizabeth, Dennis, Andrea, Andersson, Anneli, Wigley, Ioan, Romero-Gomez, Manuel, Gomez-Gonzalez, Emilio, Ampuero, Javier, Castell, Javier, Gallego-Duran, Rocio, Fernandez-Lizaranzu, Isabel, Montero-Vallejo, Rocio, Karsdal, Morten, Rasmussen, Daniel Guldager Kring, Leeming, Diana Julie, Sinisi, Antonia, Musa, Kishwar, Sandt, Estelle, Bugianesi, Elisabetta, Rosso, Chiara, Armandi, Angelo, Marra, Fabio, Gastaldelli, Amalia, Svegliati, Gianluca, Boursier, Jerome, Francque, Sven, Vonghia, Luisa, Verrijken, An, Dirinck, Eveline, Ekstedt, Mattias, Kechagias, Stergios, Yki-Jarvinen, Hannele, Porthan, Kimmo, Arola, Johanna, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Silva, Ana Paula, Valenti, Luca, Pelusi, Serena, Petta, Salvatore, Pennisi, Grazia, Miele, Luca, Liguori, Antonio, Geier, Andreas, Rau, Monika, Reissing, Johanna, Aithal, Guruprasad P., Francis, Susan, Palaniyappan, Naaventhan, Bradley, Christopher, Hockings, Paul, Schneider, Moritz, Newsome, Philip N., Hubscher, Stefan, Wenn, David, Magnanensi, Jeremy, Trylesinski, Aldo, Mayo, Rebeca, Alonso, Cristina, Duffin, Kevin, Chen, Yu, Hartman, Mark L., Miller, Melissa, Chen, Yan, McLeod, Euan James, Schoelch, Corinna, Ertle, Judith, Coxson, Harvey, Gogain, Joseph, Ostroff, Rachel, Alexander, Leigh, Biegel, Hannah, Kjaer, Mette Skalshoi, Al-Sari, Naba, Veidal, Sanne Skovgard, Ellegaard, Jens, Balp, Maria-Magdalena, Jennings, Lori, Martic, Miljen, Loffler, Jurgen, Applegate, Douglas, Torstenson, Richard, Fournier-Poizat, Celine, Llorca, Anne, Kalutkiewicz, Michael, Pepin, Kay, Ehman, Richard, Horan, Gerald, Ho, Gideon, Tai, Dean, Chng, Elaine, Xiao, Teng, Patterson, Scott D., Billin, Andrew, Doward, Lynda, Twiss, James, Thakker, Paresh, Derdak, Zoltan, Landgren, Henrik, Lackner, Carolin, Gouw, Annette, Hytiroglou, Prodromos, Brass, Clifford, Vacca, Michele, Kamzolas, Ioannis, Harder, Lea Morch, Oakley, Fiona, Trautwein, Christian, Hatting, Maximilian, Ross, Trenton, Bernardo, Barbara, Oldenburger, Anouk, Hjuler, Sara Toftegaard, Ksiazek, Iwona, Linden, Daniel, Schuppan, Detlef, Rodriguez-Cuenca, Sergio, Tonini, Maria Manuela, Castaneda, Tamara R., Kannt, Aimo, Rodrigues, Cecilia M. P., Cockell, Simon, Govaere, Olivier, Daly, Ann K., Allison, Michael, de Lichtenberg, Kristian Honnens, Kim, Yong Ook, Lindblom, Anna, Oldham, Stephanie, Andreasson, Anne-Christine, Schlerman, Franklin, Marioneaux, Jonathon, Sanyal, Arun, Afonso, Marta B., Younes, Ramy, Amano, Yuichiro, Friedman, Scott L., Wang, Shuang, Bhattacharya, Dipankar, Simon, Eric, Paradis, Valerie, Burt, Alastair, Grypari, Ioanna Maria, Davies, Susan, Driessen, Ann, Yashiro, Hiroaki, Pors, Susanne, Andersen, Maja Worm, Feigh, Michael, Yunis, Carla, Bedossa, Pierre, Stewart, Michelle, Cater, Heather L., Wells, Sara, Schattenberg, Joern M., Anstee, Quentin M., Tiniakos, Dina, Perfield, James W., Petsalaki, Evangelia, Davidsen, Peter, Vidal-Puig, Antonio, Cordell, Heather J., Day, Christopher P., Wonders, Kristy, Missier, Paolo, McTeer, Matthew, Vale, Luke, Oluboyede, Yemi, Breckons, Matt, Boyle, Jo, Bossuyt, Patrick M., Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Nieuwdorp, Max, Holleboom, Adriaan G., Angelakis, Athanasios, Verheij, Joanne, Ratziu, Vlad, Clement, Karine, Patino-Navarrete, Rafael, Pais, Raluca, Surabattula, Rambabu, Myneni, Sudha, Straub, Beate K., Rodrigues-Cuenca, Sergio, Allison, Mike, Campbell, Mark, Lelliott, Chris J., Oresic, Matej, Hyotylainen, Tuulia, McGlinchey, Aidan, Mato, Jose M., Millet, Oscar, Dufour, Jean-Francois, Berzigotti, Annalisa, Masoodi, Mojgan, Lange, Naomi F., Pavlides, Michael, Harrison, Stephen, Neubauer, Stefan, Cobbold, Jeremy, Mozes, Ferenc, Akhtar, Salma, Olodo-Atitebi, Seliat, Banerjee, Rajarshi, Shumbayawonda, Elizabeth, Dennis, Andrea, Andersson, Anneli, Wigley, Ioan, Romero-Gomez, Manuel, Gomez-Gonzalez, Emilio, Ampuero, Javier, Castell, Javier, Gallego-Duran, Rocio, Fernandez-Lizaranzu, Isabel, Montero-Vallejo, Rocio, Karsdal, Morten, Rasmussen, Daniel Guldager Kring, Leeming, Diana Julie, Sinisi, Antonia, Musa, Kishwar, Sandt, Estelle, Bugianesi, Elisabetta, Rosso, Chiara, Armandi, Angelo, Marra, Fabio, Gastaldelli, Amalia, Svegliati, Gianluca, Boursier, Jerome, Francque, Sven, Vonghia, Luisa, Verrijken, An, Dirinck, Eveline, Ekstedt, Mattias, Kechagias, Stergios, Yki-Jarvinen, Hannele, Porthan, Kimmo, Arola, Johanna, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Silva, Ana Paula, Valenti, Luca, Pelusi, Serena, Petta, Salvatore, Pennisi, Grazia, Miele, Luca, Liguori, Antonio, Geier, Andreas, Rau, Monika, Reissing, Johanna, Aithal, Guruprasad P., Francis, Susan, Palaniyappan, Naaventhan, Bradley, Christopher, Hockings, Paul, Schneider, Moritz, Newsome, Philip N., Hubscher, Stefan, Wenn, David, Magnanensi, Jeremy, Trylesinski, Aldo, Mayo, Rebeca, Alonso, Cristina, Duffin, Kevin, Chen, Yu, Hartman, Mark L., Miller, Melissa, Chen, Yan, McLeod, Euan James, Schoelch, Corinna, Ertle, Judith, Coxson, Harvey, Gogain, Joseph, Ostroff, Rachel, Alexander, Leigh, Biegel, Hannah, Kjaer, Mette Skalshoi, Al-Sari, Naba, Veidal, Sanne Skovgard, Ellegaard, Jens, Balp, Maria-Magdalena, Jennings, Lori, Martic, Miljen, Loffler, Jurgen, Applegate, Douglas, Torstenson, Richard, Fournier-Poizat, Celine, Llorca, Anne, Kalutkiewicz, Michael, Pepin, Kay, Ehman, Richard, Horan, Gerald, Ho, Gideon, Tai, Dean, Chng, Elaine, Xiao, Teng, Patterson, Scott D., Billin, Andrew, Doward, Lynda, Twiss, James, Thakker, Paresh, Derdak, Zoltan, Landgren, Henrik, Lackner, Carolin, Gouw, Annette, Hytiroglou, Prodromos, and Brass, Clifford

Abstract

Metabolic dysfunction-associated steatotic liver disease (MASLD), previously known as non-alcoholic fatty liver disease, encompasses steatosis and metabolic dysfunction-associated steatohepatitis (MASH), leading to cirrhosis and hepatocellular carcinoma. Preclinical MASLD research is mainly performed in rodents; however, the model that best recapitulates human disease is yet to be defined. We conducted a wide-ranging retrospective review (metabolic phenotype, liver histopathology, transcriptome benchmarked against humans) of murine models (mostly male) and ranked them using an unbiased MASLD 'human proximity score' to define their metabolic relevance and ability to induce MASH-fibrosis. Here, we show that Western diets align closely with human MASH; high cholesterol content, extended study duration and/or genetic manipulation of disease-promoting pathways are required to intensify liver damage and accelerate significant (F2+) fibrosis development. Choline- deficient models rapidly induce MASH-fibrosis while showing relatively poor translatability. Our ranking of commonly used MASLD models, based on their proximity to human MASLD, helps with the selection of appropriate in vivo models to accelerate preclinical research., Funding Agencies|multi-center study aiming to evaluate NAFLD biomarkers; Innovative Medicines Initiative 2 (IMI2) Joint Undertaking [777377]; European Union's Horizon 2020 research and innovation program; European Federation of Pharmaceutical Industries and Associations (EFPIA); European Bioinformatics Institute (EMBL-EBI); EMBL-EBI; Medical Research Council (MRC); University of Bari [S06-miRNASH]; Foundation for Liver Research; Associazione Italiana Ricerca sul Cancro [IG2022, 27521]; Ministry of University and Research on Next Generation EU Funds [P202222FCC, H53D23009960001, DD MUR 1366, 01-09-2023, H93C22000630001, DD MUR 1550, CN00000041, H93C22000430007, H93C22000450007]; MRC Metabolic Diseases Unit [(MC_UU_00014/5)]; UK MRC program [MR/K0019494/1, MR/R023026/1]; Fundacao para a Ciencia e Tecnologia [PTDC/MED-FAR/3492/2021]; La Caixa Foundation [LCF/PR/HR21/52410028]; Newcastle NIHR Biomedical Research Centre; National Institutes of Health (NIH) [NIH R01 DK128289, NCI 5P30CA196521-08, R01 DK136016]

Published

2024

17. Controlling the Precision-Recall Tradeoff in Differential Dependency Network Analysis

Author

Oyen, Diane, Niculescu-Mizil, Alexandru, Ostroff, Rachel, Stewart, Alex, and Clark, Vincent P.

Subjects

Statistics - Machine Learning, Computer Science - Learning

Abstract

Graphical models have gained a lot of attention recently as a tool for learning and representing dependencies among variables in multivariate data. Often, domain scientists are looking specifically for differences among the dependency networks of different conditions or populations (e.g. differences between regulatory networks of different species, or differences between dependency networks of diseased versus healthy populations). The standard method for finding these differences is to learn the dependency networks for each condition independently and compare them. We show that this approach is prone to high false discovery rates (low precision) that can render the analysis useless. We then show that by imposing a bias towards learning similar dependency networks for each condition the false discovery rates can be reduced to acceptable levels, at the cost of finding a reduced number of differences. Algorithms developed in the transfer learning literature can be used to vary the strength of the imposed similarity bias and provide a natural mechanism to smoothly adjust this differential precision-recall tradeoff to cater to the requirements of the analysis conducted. We present real case studies (oncological and neurological) where domain experts use the proposed technique to extract useful differential networks that shed light on the biological processes involved in cancer and brain function.

Published

2013

18. Cancer Diagnosis with QUIRE: QUadratic Interactions among infoRmative fEatures

Author

Chowdhury, Salim, Qi, Yanjun, Stewart, Alex, Ostroff, Rachel, and Min, Renqiang

Subjects

Quantitative Biology - Quantitative Methods

Abstract

Responsible for many complex human diseases including cancers, disrupted or abnormal gene interactions can be identified through their expression changes correlating with the progression of a disease. However, the examination of all possible combinatorial interactions between gene features in a genome-wide case-control study is computationally infeasible as the search space is exponential in nature. In this paper, we propose a novel computational approach, QUIRE, to identify discriminative complex interactions among informative gene features for cancer diagnosis. QUIRE works in two stages, where it first identifies functionally relevant feature groups for the disease and, then explores the search space capturing the combinatorial relationships among the genes from the selected informative groups. Using QUIRE, we explore the differential patterns and the interactions among informative gene features in three different types of cancers, Renal Cell Carcinoma(RCC), Ovarian Cancer(OVC) and Colorectal Cancer (CRC). Our experimental results show that QUIRE identifies gene-gene interactions that can better identify the different cancer stages of samples and can predict CRC recurrence and death from CRC more successfully, as compared to other state-of-the-art feature selection methods. A literature survey shows that many of the interactions identified by QUIRE play important roles in the development of cancer.

Published

2013

19. Author Correction: Genetic architecture of host proteins involved in SARS-CoV-2 infection

Author

Pietzner, Maik, Wheeler, Eleanor, Carrasco-Zanini, Julia, Raffler, Johannes, Kerrison, Nicola D., Oerton, Erin, Auyeung, Victoria P. W., Luan, Jian’an, Finan, Chris, Casas, Juan P., Ostroff, Rachel, Williams, Steve A., Kastenmüller, Gabi, Ralser, Markus, Gamazon, Eric R., Wareham, Nicholas J., Hingorani, Aroon D., and Langenberg, Claudia

Published

2021

20. Re‐calibration and performance of a proteomic prognostic test for 5‐year dementia risk

Author

Paterson, Clare, primary, Loupy, Kelsey, additional, Biegel, Hannah, additional, Hagar, Yolanda, additional, Ostroff, Rachel, additional, Sampson, Laura, additional, Bogren, Lori K, additional, and Williams, Stephen A, additional

Published

2023

21. Machine learning–based biomarker profile derived from 4210 serially measured proteins predicts clinical outcome of patients with heart failure

Author

de Bakker, Marie, primary, Petersen, Teun B, additional, Rueten-Budde, Anja J, additional, Akkerhuis, K Martijn, additional, Umans, Victor A, additional, Brugts, Jasper J, additional, Germans, Tjeerd, additional, Reinders, Marcel J T, additional, Katsikis, Peter D, additional, van der Spek, Peter J, additional, Ostroff, Rachel, additional, She, Ruicong, additional, Lanfear, David, additional, Asselbergs, Folkert W, additional, Boersma, Eric, additional, Rizopoulos, Dimitris, additional, and Kardys, Isabella, additional

Published

2023

22. Genetic architecture of host proteins involved in SARS-CoV-2 infection

Author

Pietzner, Maik, Wheeler, Eleanor, Carrasco-Zanini, Julia, Raffler, Johannes, Kerrison, Nicola D., Oerton, Erin, Auyeung, Victoria P. W., Luan, Jian’an, Finan, Chris, Casas, Juan P., Ostroff, Rachel, Williams, Steve A., Kastenmüller, Gabi, Ralser, Markus, Gamazon, Eric R., Wareham, Nicholas J., Hingorani, Aroon D., and Langenberg, Claudia

Published

2020

23. Development of a Protein Biomarker Panel to Detect Non–Small-Cell Lung Cancer in Korea

Author

Jung, Young Ju, Katilius, Evaldas, Ostroff, Rachel M., Kim, Youndong, Seok, Minkyoung, Lee, Sujin, Jang, Seongsoo, Kim, Woo Sung, and Choi, Chang-Min

Published

2017

24. Machine learning–based biomarker profile derived from 4210 serially measured proteins predicts clinical outcome of patients with heart failure

Author

de Bakker, Marie, Petersen, Teun B., Rueten-Budde, Anja J., Akkerhuis, K. Martijn, Umans, Victor A., Brugts, Jasper J., Germans, Tjeerd, Reinders, Marcel J.T., Katsikis, Peter D., van der Spek, Peter J., Ostroff, Rachel, She, Ruicong, Lanfear, David, Asselbergs, Folkert W., Boersma, Eric, Rizopoulos, Dimitris, Kardys, Isabella, de Bakker, Marie, Petersen, Teun B., Rueten-Budde, Anja J., Akkerhuis, K. Martijn, Umans, Victor A., Brugts, Jasper J., Germans, Tjeerd, Reinders, Marcel J.T., Katsikis, Peter D., van der Spek, Peter J., Ostroff, Rachel, She, Ruicong, Lanfear, David, Asselbergs, Folkert W., Boersma, Eric, Rizopoulos, Dimitris, and Kardys, Isabella

Abstract

Aims Risk assessment tools are needed for timely identification of patients with heart failure (HF) with reduced ejection fraction (HFrEF) who are at high risk of adverse events. In this study, we aim to derive a small set out of 4210 repeatedly measured proteins, which, along with clinical characteristics and established biomarkers, carry optimal prognostic capacity for adverse events, in patients with HFrEF. Methods and results In 382 patients, we performed repeated blood sampling (median follow-up: 2.1 years) and applied an aptamer-based multiplex proteomic approach. We used machine learning to select the optimal set of predictors for the primary endpoint (PEP: composite of cardiovascular death, heart transplantation, left ventricular assist device implantation, and HF hospitalization). The association between repeated measures of selected proteins and PEP was investigated by multivariable joint models. Internal validation (cross-validated c-index) and external validation (Henry Ford HF PharmacoGenomic Registry cohort) were performed. Nine proteins were selected in addition to the MAGGIC risk score, N-terminal pro-hormone B-type natriuretic peptide, and troponin T: suppression of tumourigenicity 2, tryptophanyl-tRNA synthetase cytoplasmic, histone H2A Type 3, angiotensinogen, deltex-1, thrombospondin-4, ADAMTS-like protein 2, anthrax toxin receptor 1, and cathepsin D. N-terminal pro-hormone B-type natriuretic peptide and angiotensinogen showed the strongest associations [hazard ratio (95% confidence interval): 1.96 (1.17–3.40) and 0.66 (0.49–0.88), respectively]. The multivariable model yielded a c-index of 0.85 upon internal validation and c-indices up to 0.80 upon external validation. The c-index was higher than that of a model containing established risk factors (P = 0.021). Conclusion Nine serially measured proteins captured the most essential prognostic information for the occurrence of adverse events in patients with HFrEF, and provided incremental value

Published

2023

25. Machine learning algorithm improves the detection of NASH (NAS-based) and at-risk NASH: A development and validation study

Author

Jenny, Lee, Max, Westphal, Yasaman, Vali, Jerome, Boursier, Salvatorre, Petta, Rachel, Ostroff, Leigh, Alexander, Yu, Chen, Celine, Fournier, Andreas, Geier, Sven, Francque, Kristy, Wonder, Dina, Tiniako, Pierre, Bedossa, Mike, Allison, Georgios, Papatheodoridi, Helena, Cortez-Pinto, Raluca, Pai, Jean-Francois, Dufour, Diana Julie, Leeming, Stephen, Harrison, Jeremy, Cobbold, Adriaan G, Holleboom, Hannele, Yki-Järvinen, Javier, Crespo, Mattias, Ekstedt, Guruprasad P, Aithal, Elisabetta, Bugianesi, Manuel, Romero-Gomez, Richard, Torstenson, Morten, Karsdal, Carla, Yuni, Jörn M, Schattenberg, Detlef, Schuppan, Vlad, Ratziu, Clifford, Bra, Kevin, Duffin, Koos, Zwinderman, Michael, Pavlide, Quentin M, Anstee, Patrick M, Bossuyt, Anstee, Quentin M., Daly, Ann K., Govaere, Olivier, Cockell, Simon, Tiniakos, Dina, Bedossa, Pierre, Burt, Alastair, Oakley, Fiona, Cordell, Heather J., Day, Christopher P., Wonders, Kristy, Missier, Paolo, Mcteer, Matthew, Vale, Luke, Oluboyede, Yemi, Breckons, Matt, Bossuyt, Patrick M., Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Nieuwdorp, Max, Holleboom, Adriaan G., Verheij, Joanne, Ratziu, Vlad, Clément, Karine, Patino-Navarrete, Rafael, Pais, Raluca, Paradis, Valerie, Schuppan, Detlef, Schattenberg, Jörn M., Surabattula, Rambabu, Myneni, Sudha, Straub, Beate K., Vidal-Puig, Toni, Vacca, Michele, Rodrigues-Cuenca, Sergio, Allison, Mike, Kamzolas, Ioanni, Petsalaki, Evangelia, Campbell, Mark, Lelliott, Chris J., Davies, Susan, Orešič, Matej, Hyötyläinen, Tuulia, Mcglinchey, Aiden, Mato, Jose M., Millet, Óscar, Dufour, Jean-Françoi, Berzigotti, Annalisa, Masoodi, Mojgan, Pavlides, Michael, Harrison, Stephen, Neubauer, Stefan, Cobbold, Jeremy, Mozes, Ferenc, Akhtar, Salma, Olodo-Atitebi, Seliat, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Andersson, Anneli, Wigley, Ioan, Romero-Gómez, Manuel, Gómez-González, Emilio, Ampuero, Javier, Castell, Javier, Gallego-Durán, Rocío, Fernández, Isabel, Montero-Vallejo, Rocío, Karsdal, Morten, Guldager Kring Rasmussen, Daniel, Leeming, Diana Julie, Sinisi, Antonia, Musa, Kishwar, Sandt, Estelle, Tonini, Manuela, Bugianesi, Elisabetta, Rosso, Chiara, Armandi, Angelo, Marra, Fabio, Gastaldelli, Amalia, Svegliati, Gianluca, Boursier, Jérôme, Francque, Sven, Vonghia, Luisa, Driessen, Ann, Ekstedt, Mattia, Kechagias, Stergio, Yki-Järvinen, Hannele, Porthan, Kimmo, Arola, Johanna, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Rodrigues, Cecilia M. P., Valenti, Luca, Pelusi, Serena, Petta, Salvatore, Pennisi, Grazia, Miele, Luca, Geier, Andrea, Trautwein, Christian, Aithal, Guruprasad P., Francis, Susan, Hockings, Paul, Schneider, Moritz, Newsome, Philip, Hübscher, Stefan, Wenn, David, Rosenquist, Christian, Trylesinski, Aldo, Mayo, Rebeca, Alonso, Cristina, Duffin, Kevin, Perfield, James W., Chen, Yu, Yunis, Carla, Tuthill, Theresa, Harrington, Magdalena Alicia, Miller, Melissa, Chen, Yan, Mcleod, Euan Jame, Ross, Trenton, Bernardo, Barbara, Schölch, Corinna, Ertle, Judith, Younes, Ramy, Oldenburger, Anouk, Ostroff, Rachel, Alexander, Leigh, Biegel, Hannah, Skalshøi Kjær, Mette, Mørch Harder, Lea, Davidsen, Peter, Mikkelsen, Lars Frii, Balp, Maria-Magdalena, Brass, Clifford, Jennings, Lori, Martic, Miljen, Löffler, Jürgen, Applegate, Dougla, Shankar, Sudha, Torstenson, Richard, Fournier-Poizat, Céline, Llorca, Anne, Kalutkiewicz, Michael, Pepin, Kay, Ehman, Richard, Horan, Gerald, Ho, Gideon, Tai, Dean, Chng, Elaine, Patterson, Scott D., Billin, Andrew, Doward, Lynda, Twiss, Jame, Thakker, Paresh, Landgren, Henrik, Lackner, Carolin, Gouw, Annette, Hytiroglou, Prodromos, Luca, Miele (ORCID:0000-0003-3464-0068), Jenny, Lee, Max, Westphal, Yasaman, Vali, Jerome, Boursier, Salvatorre, Petta, Rachel, Ostroff, Leigh, Alexander, Yu, Chen, Celine, Fournier, Andreas, Geier, Sven, Francque, Kristy, Wonder, Dina, Tiniako, Pierre, Bedossa, Mike, Allison, Georgios, Papatheodoridi, Helena, Cortez-Pinto, Raluca, Pai, Jean-Francois, Dufour, Diana Julie, Leeming, Stephen, Harrison, Jeremy, Cobbold, Adriaan G, Holleboom, Hannele, Yki-Järvinen, Javier, Crespo, Mattias, Ekstedt, Guruprasad P, Aithal, Elisabetta, Bugianesi, Manuel, Romero-Gomez, Richard, Torstenson, Morten, Karsdal, Carla, Yuni, Jörn M, Schattenberg, Detlef, Schuppan, Vlad, Ratziu, Clifford, Bra, Kevin, Duffin, Koos, Zwinderman, Michael, Pavlide, Quentin M, Anstee, Patrick M, Bossuyt, Anstee, Quentin M., Daly, Ann K., Govaere, Olivier, Cockell, Simon, Tiniakos, Dina, Bedossa, Pierre, Burt, Alastair, Oakley, Fiona, Cordell, Heather J., Day, Christopher P., Wonders, Kristy, Missier, Paolo, Mcteer, Matthew, Vale, Luke, Oluboyede, Yemi, Breckons, Matt, Bossuyt, Patrick M., Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Nieuwdorp, Max, Holleboom, Adriaan G., Verheij, Joanne, Ratziu, Vlad, Clément, Karine, Patino-Navarrete, Rafael, Pais, Raluca, Paradis, Valerie, Schuppan, Detlef, Schattenberg, Jörn M., Surabattula, Rambabu, Myneni, Sudha, Straub, Beate K., Vidal-Puig, Toni, Vacca, Michele, Rodrigues-Cuenca, Sergio, Allison, Mike, Kamzolas, Ioanni, Petsalaki, Evangelia, Campbell, Mark, Lelliott, Chris J., Davies, Susan, Orešič, Matej, Hyötyläinen, Tuulia, Mcglinchey, Aiden, Mato, Jose M., Millet, Óscar, Dufour, Jean-Françoi, Berzigotti, Annalisa, Masoodi, Mojgan, Pavlides, Michael, Harrison, Stephen, Neubauer, Stefan, Cobbold, Jeremy, Mozes, Ferenc, Akhtar, Salma, Olodo-Atitebi, Seliat, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Andersson, Anneli, Wigley, Ioan, Romero-Gómez, Manuel, Gómez-González, Emilio, Ampuero, Javier, Castell, Javier, Gallego-Durán, Rocío, Fernández, Isabel, Montero-Vallejo, Rocío, Karsdal, Morten, Guldager Kring Rasmussen, Daniel, Leeming, Diana Julie, Sinisi, Antonia, Musa, Kishwar, Sandt, Estelle, Tonini, Manuela, Bugianesi, Elisabetta, Rosso, Chiara, Armandi, Angelo, Marra, Fabio, Gastaldelli, Amalia, Svegliati, Gianluca, Boursier, Jérôme, Francque, Sven, Vonghia, Luisa, Driessen, Ann, Ekstedt, Mattia, Kechagias, Stergio, Yki-Järvinen, Hannele, Porthan, Kimmo, Arola, Johanna, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Rodrigues, Cecilia M. P., Valenti, Luca, Pelusi, Serena, Petta, Salvatore, Pennisi, Grazia, Miele, Luca, Geier, Andrea, Trautwein, Christian, Aithal, Guruprasad P., Francis, Susan, Hockings, Paul, Schneider, Moritz, Newsome, Philip, Hübscher, Stefan, Wenn, David, Rosenquist, Christian, Trylesinski, Aldo, Mayo, Rebeca, Alonso, Cristina, Duffin, Kevin, Perfield, James W., Chen, Yu, Yunis, Carla, Tuthill, Theresa, Harrington, Magdalena Alicia, Miller, Melissa, Chen, Yan, Mcleod, Euan Jame, Ross, Trenton, Bernardo, Barbara, Schölch, Corinna, Ertle, Judith, Younes, Ramy, Oldenburger, Anouk, Ostroff, Rachel, Alexander, Leigh, Biegel, Hannah, Skalshøi Kjær, Mette, Mørch Harder, Lea, Davidsen, Peter, Mikkelsen, Lars Frii, Balp, Maria-Magdalena, Brass, Clifford, Jennings, Lori, Martic, Miljen, Löffler, Jürgen, Applegate, Dougla, Shankar, Sudha, Torstenson, Richard, Fournier-Poizat, Céline, Llorca, Anne, Kalutkiewicz, Michael, Pepin, Kay, Ehman, Richard, Horan, Gerald, Ho, Gideon, Tai, Dean, Chng, Elaine, Patterson, Scott D., Billin, Andrew, Doward, Lynda, Twiss, Jame, Thakker, Paresh, Landgren, Henrik, Lackner, Carolin, Gouw, Annette, Hytiroglou, Prodromos, and Luca, Miele (ORCID:0000-0003-3464-0068)

Abstract

Background and aims: Detecting NASH remains challenging, while at-risk NASH (steatohepatitis and F≥ 2) tends to progress and is of interest for drug development and clinical application. We developed prediction models by supervised machine learning techniques, with clinical data and biomarkers to stage and grade patients with NAFLD. Approach and results: Learning data were collected in the Liver Investigation: Testing Marker Utility in Steatohepatitis metacohort (966 biopsy-proven NAFLD adults), staged and graded according to NASH CRN. Conditions of interest were the clinical trial definition of NASH (NAS ≥ 4;53%), at-risk NASH (NASH with F ≥ 2;35%), significant (F ≥ 2;47%), and advanced fibrosis (F ≥ 3;28%). Thirty-five predictors were included. Missing data were handled by multiple imputations. Data were randomly split into training/validation (75/25) sets. A gradient boosting machine was applied to develop 2 models for each condition: clinical versus extended (clinical and biomarkers). Two variants of the NASH and at-risk NASH models were constructed: direct and composite models.Clinical gradient boosting machine models for steatosis/inflammation/ballooning had AUCs of 0.94/0.79/0.72. There were no improvements when biomarkers were included. The direct NASH model produced AUCs (clinical/extended) of 0.61/0.65. The composite NASH model performed significantly better (0.71) for both variants. The composite at-risk NASH model had an AUC of 0.83 (clinical and extended), an improvement over the direct model. Significant fibrosis models had AUCs (clinical/extended) of 0.76/0.78. The extended advanced fibrosis model (0.86) performed significantly better than the clinical version (0.82). Conclusions: Detection of NASH and at-risk NASH can be improved by constructing independent machine learning models for each component, using only clinical predictors. Adding biomarkers only improved the accuracy of fibrosis.

Published

2023

26. Machine learning algorithm improves the detection of NASH (NAS-based) and at-risk NASH: A development and validation study

Author

Lee, Jenny, Westphal, Max, Vali, Yasaman, Boursier, Jerome, Petta, Salvatorre, Ostroff, Rachel, Alexander, Leigh, Chen, Yu, Fournier, Celine, Geier, Andreas, Francque, Sven, Wonders, Kristy, Tiniakos, Dina, Bedossa, Pierre, Allison, Mike, Papatheodoridis, Georgios, Cortez-Pinto, Helena, Pais, Raluca, Dufour, Jean-Francois, Leeming, Diana Julie, Harrison, Stephen, Cobbold, Jeremy, Holleboom, Adriaan G., Yki-Jarvinen, Hannele, Crespo, Javier, Ekstedt, Mattias, Aithal, Guruprasad P., Bugianesi, Elisabetta, Romero-Gomez, Manuel, Torstenson, Richard, Karsdal, Morten, Yunis, Carla, Schattenberg, Joern M., Schuppan, Detlef, Ratziu, Vlad, Brass, Clifford, Duffin, Kevin, Zwinderman, Koos, Pavlides, Michael, Anstee, Quentin M., Bossuyt, Patrick M., LITMUS Investigators, Lee, Jenny, Westphal, Max, Vali, Yasaman, Boursier, Jerome, Petta, Salvatorre, Ostroff, Rachel, Alexander, Leigh, Chen, Yu, Fournier, Celine, Geier, Andreas, Francque, Sven, Wonders, Kristy, Tiniakos, Dina, Bedossa, Pierre, Allison, Mike, Papatheodoridis, Georgios, Cortez-Pinto, Helena, Pais, Raluca, Dufour, Jean-Francois, Leeming, Diana Julie, Harrison, Stephen, Cobbold, Jeremy, Holleboom, Adriaan G., Yki-Jarvinen, Hannele, Crespo, Javier, Ekstedt, Mattias, Aithal, Guruprasad P., Bugianesi, Elisabetta, Romero-Gomez, Manuel, Torstenson, Richard, Karsdal, Morten, Yunis, Carla, Schattenberg, Joern M., Schuppan, Detlef, Ratziu, Vlad, Brass, Clifford, Duffin, Kevin, Zwinderman, Koos, Pavlides, Michael, Anstee, Quentin M., Bossuyt, Patrick M., and LITMUS Investigators

Abstract

Background and Aims: Detecting NASH remains challenging, while at-risk NASH (steatohepatitis and F >= 2) tends to progress and is of interest for drug development and clinical application. We developed prediction models by supervised machine learning techniques, with clinical data and biomarkers to stage and grade patients with NAFLD. Approach and Results: Learning data were collected in the Liver Investigation: Testing Marker Utility in Steatohepatitis metacohort (966 biopsy-proven NAFLD adults), staged and graded according to NASH CRN. Conditions of interest were the clinical trial definition of NASH (NAS >= 4;53%), at-risk NASH (NASH with F >= 2;35%), significant (F >= 2;47%), and advanced fibrosis (F >= 3;28%). Thirty-five predictors were included. Missing data were handled by multiple imputations. Data were randomly split into training/validation (75/25) sets. A gradient boosting machine was applied to develop 2 models for each condition: clinical versus extended (clinical and biomarkers). Two variants of the NASH and at-risk NASH models were constructed: direct and composite models.Clinical gradient boosting machine models for steatosis/inflammation/ballooning had AUCs of 0.94/0.79/0.72. There were no improvements when biomarkers were included. The direct NASH model produced AUCs (clinical/extended) of 0.61/0.65. The composite NASH model performed significantly better (0.71) for both variants. The composite at-risk NASH model had an AUC of 0.83 (clinical and extended), an improvement over the direct model. Significant fibrosis models had AUCs (clinical/extended) of 0.76/0.78. The extended advanced fibrosis model (0.86) performed significantly better than the clinical version (0.82). Conclusions: Detection of NASH and at-risk NASH can be improved by constructing independent machine learning models for each component, using only clinical predictors. Adding biomarkers only improved the accuracy of fibrosis., Funding Agencies|Jenny Lee, Quentin M. Anstee, and Pierre Bedossa conceptualized and designed the study; Jerome Boursier, Salvatore Petta, Kristy Wonders, Dina Tiniakos, Pierre Bedossa, Andreas Geier, Sven Francque, Mike Allison, Georgios Papatheodoridis, Helena Cortez-Pin

Published

2023

27. Machine learning algorithm improves the detection of NASH (NAS-based) and at-risk NASH: A development and validation study

Author

Innovative Medicines Initiative, European Commission, Research Foundation - Flanders, Lee, Jenny, Westphal, Max, Vali, Yasaman, Boursier, Jerome, Petta, Salvatorre, Ostroff, Rachel, Alexander, Leigh, Chen, Yu, Fournier, Celine, Geier, Andreas, Francque, Sven, Wonders, Kristy, Tiniakos, Dina, Bedossa, Pierre, Allison, Mike, Papatheodoridis, Georgios, Cortez-Pinto, Helena, Pais, Raluca, Dufour, Jean-François, Leeming, Diana Julie, Harrison, Stephen, Cobbold, Jeremy, Holleboom, Adriaan G., Yki-Järvinen, Hannele, Crespo, Javier, Ekstedt, Mattias, Aithal, Guruprasad P., Bugianesi, Elisabetta, Romero-Gómez, Manuel, Torstenson, Richard, Karsdal, Morten, Yunis, Carla27, Schattenberg, Jörn M., Schuppan, Detlef, Ratziu, Vlad, Brass, Clifford, Duffin, Kevin, Zwinderman, Koos, Pavlides, Michael, Anstee, Quentin M., Bossuyt, Patrick M., LITMUS investigators, Innovative Medicines Initiative, European Commission, Research Foundation - Flanders, Lee, Jenny, Westphal, Max, Vali, Yasaman, Boursier, Jerome, Petta, Salvatorre, Ostroff, Rachel, Alexander, Leigh, Chen, Yu, Fournier, Celine, Geier, Andreas, Francque, Sven, Wonders, Kristy, Tiniakos, Dina, Bedossa, Pierre, Allison, Mike, Papatheodoridis, Georgios, Cortez-Pinto, Helena, Pais, Raluca, Dufour, Jean-François, Leeming, Diana Julie, Harrison, Stephen, Cobbold, Jeremy, Holleboom, Adriaan G., Yki-Järvinen, Hannele, Crespo, Javier, Ekstedt, Mattias, Aithal, Guruprasad P., Bugianesi, Elisabetta, Romero-Gómez, Manuel, Torstenson, Richard, Karsdal, Morten, Yunis, Carla27, Schattenberg, Jörn M., Schuppan, Detlef, Ratziu, Vlad, Brass, Clifford, Duffin, Kevin, Zwinderman, Koos, Pavlides, Michael, Anstee, Quentin M., Bossuyt, Patrick M., and LITMUS investigators

Abstract

[Background and Aims] Detecting NASH remains challenging, while at-risk NASH (steatohepatitis and F≥ 2) tends to progress and is of interest for drug development and clinical application. We developed prediction models by supervised machine learning techniques, with clinical data and biomarkers to stage and grade patients with NAFLD., [Approach and Results] Learning data were collected in the Liver Investigation: Testing Marker Utility in Steatohepatitis metacohort (966 biopsy-proven NAFLD adults), staged and graded according to NASH CRN. Conditions of interest were the clinical trial definition of NASH (NAS ≥ 4;53%), at-risk NASH (NASH with F ≥ 2;35%), significant (F ≥ 2;47%), and advanced fibrosis (F ≥ 3;28%). Thirty-five predictors were included. Missing data were handled by multiple imputations. Data were randomly split into training/validation (75/25) sets. A gradient boosting machine was applied to develop 2 models for each condition: clinical versus extended (clinical and biomarkers). Two variants of the NASH and at-risk NASH models were constructed: direct and composite models. Clinical gradient boosting machine models for steatosis/inflammation/ballooning had AUCs of 0.94/0.79/0.72. There were no improvements when biomarkers were included. The direct NASH model produced AUCs (clinical/extended) of 0.61/0.65. The composite NASH model performed significantly better (0.71) for both variants. The composite at-risk NASH model had an AUC of 0.83 (clinical and extended), an improvement over the direct model. Significant fibrosis models had AUCs (clinical/extended) of 0.76/0.78. The extended advanced fibrosis model (0.86) performed significantly better than the clinical version (0.82)., [Conclusions] Detection of NASH and at-risk NASH can be improved by constructing independent machine learning models for each component, using only clinical predictors. Adding biomarkers only improved the accuracy of fibrosis.

Published

2023

28. Biomarkers for staging fibrosis and non-alcoholic steatohepatitis in non-alcoholic fatty liver disease (the LITMUS project): a comparative diagnostic accuracy study

Author

Innovative Medicines Initiative, European Commission, Vali, Yasaman, Lee, Jenny, Boursier, Jerome, Petta, Salvatore, Wonders, Kristy, Tiniakos, Dina, Bedossa, Pierre, Geier, Andreas, Francque, Sven, Allison, Mike, Papatheodoridis, Georgios, Cortez-Pinto, Helena, Pais, Raluca, Dufour, Jean-François, Leeming, Diana Julie, Harrison, Stephen A., Chen, Yu, Cobbold, Jeremy F., Pavlides, Michael, Holleboom, Adriaan G., Yki-Jarvinen, Hannele, Crespo, Javier, Karsdal, Morten, Ostroff, Rachel, Zafarmand, Mohammad Hadi, Torstenson, Richard, Duffin, Kevin, Yunis, Carla, Brass, Clifford, Ekstedt, Mattias, Aithal, Guruprasad P., Schattenberg, Jörn M., Bugianesi, Elisabetta, Romero-Gómez, Manuel, Ratziu, Vlad, Anstee, Quentin M., Bossuyt, Patrick M., on behalf of theLiver Investigation: Testing Marker Utility in Steatohepatitis (LITMUS) consortium investigators, Innovative Medicines Initiative, European Commission, Vali, Yasaman, Lee, Jenny, Boursier, Jerome, Petta, Salvatore, Wonders, Kristy, Tiniakos, Dina, Bedossa, Pierre, Geier, Andreas, Francque, Sven, Allison, Mike, Papatheodoridis, Georgios, Cortez-Pinto, Helena, Pais, Raluca, Dufour, Jean-François, Leeming, Diana Julie, Harrison, Stephen A., Chen, Yu, Cobbold, Jeremy F., Pavlides, Michael, Holleboom, Adriaan G., Yki-Jarvinen, Hannele, Crespo, Javier, Karsdal, Morten, Ostroff, Rachel, Zafarmand, Mohammad Hadi, Torstenson, Richard, Duffin, Kevin, Yunis, Carla, Brass, Clifford, Ekstedt, Mattias, Aithal, Guruprasad P., Schattenberg, Jörn M., Bugianesi, Elisabetta, Romero-Gómez, Manuel, Ratziu, Vlad, Anstee, Quentin M., Bossuyt, Patrick M., and on behalf of theLiver Investigation: Testing Marker Utility in Steatohepatitis (LITMUS) consortium investigators

Abstract

[Background] The reference standard for detecting non-alcoholic steatohepatitis (NASH) and staging fibrosis—liver biopsy—is invasive and resource intensive. Non-invasive biomarkers are urgently needed, but few studies have compared these biomarkers in a single cohort. As part of the Liver Investigation: Testing Marker Utility in Steatohepatitis (LITMUS) project, we aimed to evaluate the diagnostic accuracy of 17 biomarkers and multimarker scores in detecting NASH and clinically significant fibrosis in patients with non-alcoholic fatty liver disease (NAFLD) and identify their optimal cutoffs as screening tests in clinical trial recruitment., [Methods] This was a comparative diagnostic accuracy study in people with biopsy-confirmed NAFLD from 13 countries across Europe, recruited between Jan 6, 2010, and Dec 29, 2017, from the LITMUS metacohort of the prospective European NAFLD Registry. Adults (aged ≥18 years) with paired liver biopsy and serum samples were eligible; those with excessive alcohol consumption or evidence of other chronic liver diseases were excluded. The diagnostic accuracy of the biomarkers was expressed as the area under the receiver operating characteristic curve (AUC) with liver histology as the reference standard and compared with the Fibrosis-4 index for liver fibrosis (FIB-4) in the same subgroup. Target conditions were the presence of NASH with clinically significant fibrosis (ie, at-risk NASH; NAFLD Activity Score ≥4 and F≥2) or the presence of advanced fibrosis (F≥3), analysed in all participants with complete data. We identified thres holds for each biomarker for reducing the number of biopsy-based screen failures when recruiting people with both NASH and clinically significant fibrosis for future trials., [Findings] Of 1430 participants with NAFLD in the LITMUS metacohort with serum samples, 966 (403 women and 563 men) were included after all exclusion criteria had been applied. 335 (35%) of 966 participants had biopsy-confirmed NASH and clinically significant fibrosis and 271 (28%) had advanced fibrosis. For people with NASH and clinically significant fibrosis, no single biomarker or multimarker score significantly reached the predefined AUC 0·80 acceptability threshold (AUCs ranging from 0·61 [95% CI 0·54–0·67] for FibroScan controlled attenuation parameter to 0·81 [0·75–0·86] for SomaSignal), with accuracy mostly similar to FIB-4. Regarding detection of advanced fibrosis, SomaSignal (AUC 0·90 [95% CI 0·86–0·94]), ADAPT (0·85 [0·81–0·89]), and FibroScan liver stiffness measurement (0·83 [0·80–0·86]) reached acceptable accuracy. With 11 of 17 markers, histological screen failure rates could be reduced to 33% in trials if only people who were marker positive had a biopsy for evaluating eligibility. The best screening performance for NASH and clinically significant fibrosis was observed for SomaSignal (number needed to test [NNT] to find one true positive was four [95% CI 4–5]), then ADAPT (six [5–7]), MACK-3 (seven [6–8]), and PRO-C3 (nine [7–11])., [Interpretation] None of the single markers or multimarker scores achieved the predefined acceptable AUC for replacing biopsy in detecting people with both NASH and clinically significant fibrosis. However, several biomarkers could be applied in a prescreening strategy in clinical trial recruitment. The performance of promising markers will be further evaluated in the ongoing prospective LITMUS study cohort.

Published

2023

29. Abstract 5411: Efficient development of prognostic tests for detecting cancer risk using proteomic technology

Author

Hagar, Yolanda, primary, Alexander, Leigh, additional, Chadwick, Jessica, additional, Datta, Gargi, additional, Gogain, Joe, additional, Ostroff, Rachel, additional, Paterson, Clare, additional, Sampson, Laura, additional, Scheidel, Caleb, additional, Shrestha, Sama, additional, Zhang, Amy, additional, and Hinterberg, Michael, additional

Published

2023

30. Abstract 4361: The plasma proteome as a cardiovascular disease risk assessment tool in cancer survivors

Author

Troth, Emma V., primary, Ayala, Matthew, additional, Chadwick, Jessica, additional, Hales, Erin, additional, Hinterberg, Michael, additional, Kuzma, Jessica N., additional, Paterson, Clare, additional, Ostroff, Rachel, additional, Walter, Joan E., additional, Mueller, Christian, additional, and Coresh, Josef, additional

Published

2023

31. Improving Work Zones Every Days in Every Way: FHWA has Developer a comprehensive set of programs, strategies, and tools for the management of safer and more efficient temporary traffic control

Author

Paracha, Jawad and Ostroff, Rachel

Subjects

Company business management, Construction workers

Abstract

The addition of work zones on busy roadways is a formula for crashes and increased congestion. In 2015, more than 96,000 crashes related to work zones resulted in 35,000 people [...]

Published

2018

32. Highly Multiplexed Proteomic Platform for Biomarker Discovery, Diagnostics, and Therapeutics

Author

Mehan, Michael R., Ostroff, Rachel, Wilcox, Sheri K., Steele, Fintan, Schneider, Daniel, Jarvis, Thale C., Baird, Geoffrey S., Gold, Larry, Janjic, Nebojsa, Lambris, John D., editor, Holers, V. Michael, editor, and Ricklin, Daniel, editor

Published

2013

33. PREDICTING RISK OF FUTURE EVENTS IN INDIVIDUALS WITH CHRONIC CORONARY SYNDROMES

Author

Chadwick, Jessica, primary, Williams, Stephen A., additional, Astling, David, additional, Mueller, Christian, additional, Walter, Joan, additional, Ostroff, Rachel, additional, and Troth, Emma, additional

Published

2023

34. Development and validation of a blood‐based protein predictor of 20‐year dementia risk from middle age

Author

Paterson, Clare, primary, Zhang, Amy, additional, Ostroff, Rachel, additional, Hagar, Yolanda, additional, Loupy, Kelsey, additional, and Williams, Stephen, additional

Published

2022

35. Life's Simple Measures: Unlocking the Proteome

Author

Brody, Edward, Gold, Larry, Mehan, Mike, Ostroff, Rachel, Rohloff, John, Walker, Jeff, and Zichi, Dom

Published

2012

36. Increased serum miR-193a-5p during non-alcoholic fatty liver disease progression: Diagnostic and mechanistic relevance

Author

Katherine, Johnson, Peter J, Leary, Olivier, Govaere, Matthew J, Barter, Sarah H, Charlton, Simon J, Cockell, Dina, Tiniako, Michalina, Zatorska, Pierre, Bedossa, M Julia, Brosnan, Jeremy F, Cobbold, Mattias, Ekstedt, Guruprasad P, Aithal, Karine, Clément, Jörn M, Schattenberg, Jerome, Boursier, Vlad, Ratziu, Elisabetta, Bugianesi, Quentin M, Anstee, Ann K, Daly, Clark, Jame, Cordell, Heather J., Darlay, Rebecca, Day, Christopher P., Hardy, Tim, Liu, Yang-Lin, Oakley, Fiona, Palmer, Jeremy, Queen, Rachel, Wonders, Kristy, Bossuyt, Patrick M., Holleboom, Adriaan G., Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Clement, Karine, Pais, Raluca, Schuppan, Detlef, Allison, Michael, Rodriguez Cuenca, Sergio, Pellegrinelli, Vanessa, Vacca, Michele, Vidal-Puig, Antonio, Hyötyläinen, Tuulia, Mcglinchey, Aidan, Orešič, Matej, Sen, Partho, Mato, Jose, Millet, Óscar, Dufour, Jean-Francoi, Harrison, Stephen, Neubauer, Stefan, Pavlides, Michael, Mozes, Ferenc, Akhtar, Salma, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Erpicum, Charlotte, Romero-Gomez, Manuel, Gallego-Durán, Rocío, Fernández, Isabel, Karsdal, Morten, Leeming, Diana, Juul Fisker, Mette, Erhardtsen, Elisabeth, Rasmussen, Daniel, Qvist, Per, Sinisi, Antonia, Sandt, Estelle, Tonini, Maria Manuela, Parola, Maurizio, Rosso, Chiara, Marra, Fabio, Gastaldelli, Amalia, Francque, Sven, Kechagias, Stergio, Yki-Järvinen, Hannele, Porthan, Kimmo, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Valenti, Luca, Petta, Salvatore, Miele, Luca, Geier, Andrea, Trautwein, Christian, Hockings, Paul, Newsome, Phil, Wenn, David, Pereira Rodrigues, Cecília Maria, Hanf, Rémy, Chaumat, Pierre, Rosenquist, Christian, Trylesinski, Aldo, Ortiz, Pablo, Duffin, Kevin, Yunis, Carla, Miller, Melissa, Tuthill, Theresa, Ertle, Judith, Younes, Ramy, Alexander, Leigh, Ostroff, Rachel, Skalshøi Kjær, Mette, Friis Mikkelsen, Lar, Brass, Clifford, Jennings, Lori, Balp, Maria-Magdalena, Martic, Miljen, Hanauer, Guido, Shankar, Sudha, Torstenson, Richard, Fournier, Céline, Ehman, Richard, Kalutkiewicz, Michael, Pepin, Kay, Myers, Joel, Shevell, Diane, Ho, Gideon, Landgren, Henrik, Myers, Rob, Doward, Lynda, Whalley, Diane, Twiss, James, Luca, Miele (ORCID:0000-0003-3464-0068), Katherine, Johnson, Peter J, Leary, Olivier, Govaere, Matthew J, Barter, Sarah H, Charlton, Simon J, Cockell, Dina, Tiniako, Michalina, Zatorska, Pierre, Bedossa, M Julia, Brosnan, Jeremy F, Cobbold, Mattias, Ekstedt, Guruprasad P, Aithal, Karine, Clément, Jörn M, Schattenberg, Jerome, Boursier, Vlad, Ratziu, Elisabetta, Bugianesi, Quentin M, Anstee, Ann K, Daly, Clark, Jame, Cordell, Heather J., Darlay, Rebecca, Day, Christopher P., Hardy, Tim, Liu, Yang-Lin, Oakley, Fiona, Palmer, Jeremy, Queen, Rachel, Wonders, Kristy, Bossuyt, Patrick M., Holleboom, Adriaan G., Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Clement, Karine, Pais, Raluca, Schuppan, Detlef, Allison, Michael, Rodriguez Cuenca, Sergio, Pellegrinelli, Vanessa, Vacca, Michele, Vidal-Puig, Antonio, Hyötyläinen, Tuulia, Mcglinchey, Aidan, Orešič, Matej, Sen, Partho, Mato, Jose, Millet, Óscar, Dufour, Jean-Francoi, Harrison, Stephen, Neubauer, Stefan, Pavlides, Michael, Mozes, Ferenc, Akhtar, Salma, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Erpicum, Charlotte, Romero-Gomez, Manuel, Gallego-Durán, Rocío, Fernández, Isabel, Karsdal, Morten, Leeming, Diana, Juul Fisker, Mette, Erhardtsen, Elisabeth, Rasmussen, Daniel, Qvist, Per, Sinisi, Antonia, Sandt, Estelle, Tonini, Maria Manuela, Parola, Maurizio, Rosso, Chiara, Marra, Fabio, Gastaldelli, Amalia, Francque, Sven, Kechagias, Stergio, Yki-Järvinen, Hannele, Porthan, Kimmo, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Valenti, Luca, Petta, Salvatore, Miele, Luca, Geier, Andrea, Trautwein, Christian, Hockings, Paul, Newsome, Phil, Wenn, David, Pereira Rodrigues, Cecília Maria, Hanf, Rémy, Chaumat, Pierre, Rosenquist, Christian, Trylesinski, Aldo, Ortiz, Pablo, Duffin, Kevin, Yunis, Carla, Miller, Melissa, Tuthill, Theresa, Ertle, Judith, Younes, Ramy, Alexander, Leigh, Ostroff, Rachel, Skalshøi Kjær, Mette, Friis Mikkelsen, Lar, Brass, Clifford, Jennings, Lori, Balp, Maria-Magdalena, Martic, Miljen, Hanauer, Guido, Shankar, Sudha, Torstenson, Richard, Fournier, Céline, Ehman, Richard, Kalutkiewicz, Michael, Pepin, Kay, Myers, Joel, Shevell, Diane, Ho, Gideon, Landgren, Henrik, Myers, Rob, Doward, Lynda, Whalley, Diane, Twiss, James, and Luca, Miele (ORCID:0000-0003-3464-0068)

Abstract

Background & Aims: Serum microRNA (miRNA) levels are known to change in non-alcoholic fatty liver disease (NAFLD) and may serve as useful biomarkers. This study aimed to profile miRNAs comprehensively at all NAFLD stages.Methods: We profiled 2,083 serum miRNAs in a discovery cohort (183 cases with NAFLD representing the complete NAFLD spectrum and 10 population controls). miRNA libraries generated by HTG EdgeSeq were sequenced by Illumina NextSeq. Selected serum miRNAs were profiled in 372 additional cases with NAFLD and 15 population controls by quantitative reverse transcriptase PCR.Results: Levels of 275 miRNAs differed between cases and population controls. Fewer differences were seen within individual NAFLD stages, but miR-193a-5p consistently showed increased levels in all comparisons. Relative to NAFL/non-alcoholic steatohepatitis (NASH) with mild fibrosis (stage 0/1), 3 miRNAs (miR-193a-5p, miR-378d, and miR378d) were increased in cases with NASH and clinically significant fibrosis (stages 2-4), 7 (miR193a-5p, miR-378d, miR-378e, miR-320b, miR-320c, miR-320d, and miR-320e) increased in cases with NAFLD activity score (NAS) 5-8 compared with lower NAS, and 3 (miR-193a-5p, miR-378d, and miR-378e) increased but 1 (miR-19b-3p) decreased in steatosis, activity, and fibrosis (SAF) activity score 2-4 compared with lower SAF activity. The significant findings for miR-193a-5p were replicated in the additional cohort with NAFLD. Studies in Hep G2 cells showed that following palmitic acid treatment, miR-193a-5p expression decreased significantly. Gene targets for miR-193a-5p were investigated in liver RNAseq data for a case subgroup (n = 80); liver GPX8 levels correlated positively with serum miR-193a-5p.Conclusions: Serum miR-193a-5p levels correlate strongly with NAFLD activity grade and fibrosis stage. MiR-193a-5p may have a role in the hepatic response to oxidative stress and is a potential clinically tractable circulating biomarker for progressive NAFLD.Lay su

Published

2022

37. Chapter 8 - SOMAmer reagents and the SomaScan platform: Chemically modified aptamers and their applications in therapeutics, diagnostics, and proteomics

Author

Schneider, Daniel J., Lynch, Sean A., Gelinas, Amy D., Ostroff, Rachel M., Rohloff, John C., Williams, Preston, Janjic, Nebojsa, and Drolet, Daniel W.

Published

2022

38. Abstract LB515: Cardiovascular risk assessed by aptamer-based proteomics is increased in early breast cancer

Author

Omland, Torbjørn, primary, Chadwick, Jessica, additional, Røysland, Ragnhild, additional, Gulati, Geeta, additional, Astling, David, additional, Heck, Siri L., additional, Vinje, Victoria, additional, Ostroff, Rachel, additional, Ganz, Peter, additional, Geisler, Jürgen, additional, and Williams, Steve, additional

Published

2022

39. Abstract 2227: Development and validation of a blood-based protein-only predictor of 5-year lung cancer risk in ever smokers

Author

Paterson, Clare, primary, Alexander, Leigh, additional, Ostroff, Rachel, additional, Gogain, Joseph, additional, Hagar, Yolanda, additional, Biegel, Hannah, additional, and Williams, Stephen, additional

Published

2022

40. A proteomic surrogate for cardiovascular outcomes that is sensitive to multiple mechanisms of change in risk

Author

Williams, Stephen A., primary, Ostroff, Rachel, additional, Hinterberg, Michael A., additional, Coresh, Josef, additional, Ballantyne, Christie M., additional, Matsushita, Kunihiro, additional, Mueller, Christian E., additional, Walter, Joan, additional, Jonasson, Christian, additional, Holman, Rury R., additional, Shah, Svati H., additional, Sattar, Naveed, additional, Taylor, Roy, additional, Lean, Michael E., additional, Kato, Shintaro, additional, Shimokawa, Hiroaki, additional, Sakata, Yasuhiko, additional, Nochioka, Kotaro, additional, Parikh, Chirag R., additional, Coca, Steven G., additional, Omland, Torbjørn, additional, Chadwick, Jessica, additional, Astling, David, additional, Hagar, Yolanda, additional, Kureshi, Natasha, additional, Loupy, Kelsey, additional, Paterson, Clare, additional, Primus, Jeremy, additional, Simpson, Missy, additional, Trujillo, Nelson P., additional, and Ganz, Peter, additional

Published

2022

41. Increased serum miR-193a-5p during non-alcoholic fatty liver disease progression: Diagnostic and mechanistic relevance

Author

Johnson, Katherine, Leary, Peter J., Govaere, Olivier, Barter, Matthew J., Charlton, Sarah H., Cockell, Simon J., Tiniakos, Dina, Zatorska, Michalina, Bedossa, Pierre, Brosnan, M. Julia, Cobbold, Jeremy F., Ekstedt, Mattias, Aithal, Guruprasad P., Boursier, Jerome, Ratziu, Vlad, Bugianesi, Elisabetta, Anstee, Quentin M., Daly, Ann K., Clark, James, Cockell, Simon, Cordell, Heather J., Darlay, Rebecca, Day, Christopher P., Hardy, Tim, Liu, Yang-Lin, Oakley, Fiona, Palmer, Jeremy, Queen, Rachel, Wonders, Kristy, Bossuyt, Patrick M., Holleboom, Adriaan G., Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Clement, Karine, Pais, Raluca, Schuppan, Detlef, Allison, Michael, Cuenca, Sergio Rodriguez, Pellegrinelli, Vanessa, Vacca, Michele, Vidal-Puig, Antonio, McGlinchey, Aidan, Sen, Partho, Mato, Jose, Dufour, Jean-Francois, Harrison, Stephen, Neubauer, Stefan, Pavlides, Michael, Mozes, Ferenc, Akhtar, Salma, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Erpicum, Charlotte, Romero-Gomez, Manuel, Karsdal, Morten, Leeming, Diana, Fisker, Mette Juul, Erhardtsen, Elisabeth, Rasmussen, Daniel, Qvist, Per, Sinisi, Antonia, Sandt, Estelle, Tonini, Maria Manuela, Parola, Maurizio, Rosso, Chiara, Marra, Fabio, Gastaldelli, Amalia, Francque, Sven, Kechagias, Stergios, Porthan, Kimmo, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Valenti, Luca, Petta, Salvatore, Miele, Luca, Geier, Andreas, Trautwein, Christian, Hockings, Paul, Newsome, Phil, Wenn, David, Chaumat, Pierre, Rosenquist, Christian, Trylesinski, Aldo, Ortiz, Pablo, Duffin, Kevin, Yunis, Carla, Miller, Melissa, Tuthill, Theresa, Ertle, Judith, Younes, Ramy, Alexander, Leigh, Ostroff, Rachel, Mikkelsen, Lars Friis, Brass, Clifford, Jennings, Lori, Balp, Maria-Magdalena, Martic, Miljen, Hanauer, Guido, Shankar, Sudha, Torstenson, Richard, Ehman, Richard, Kalutkiewicz, Michael, Pepin, Kay, Myers, Joel, Shevell, Diane, Ho, Gideon, Landgren, Henrik, Myers, Rob, Doward, Lynda, Whalley, Diane, and Twiss, James

Subjects

Hepatology, Gastroenterology, Internal Medicine, Immunology and Allergy, digestive system diseases

Abstract

Background & Aims: Serum microRNA (miRNA) levels are known to change in non-alcoholic fatty liver disease (NAFLD) and may serve as useful biomarkers. This study aimed to profile miRNAs comprehensively at all NAFLD stages. Methods: We profiled 2,083 serum miRNAs in a discovery cohort (183 cases with NAFLD representing the complete NAFLD spectrum and 10 population controls). miRNA libraries generated by HTG EdgeSeq were sequenced by Illumina NextSeq. Selected serum miRNAs were profiled in 372 additional cases with NAFLD and 15 population controls by quantitative reverse transcriptase PCR. Results: Levels of 275 miRNAs differed between cases and population controls. Fewer differences were seen within individual NAFLD stages, but miR-193a-5p consistently showed increased levels in all comparisons. Relative to NAFL/non-alcoholic steatohepatitis (NASH) with mild fibrosis (stage 0/1), 3 miRNAs (miR-193a-5p, miR-378d, and miR378d) were increased in cases with NASH and clinically significant fibrosis (stages 2–4), 7 (miR193a-5p, miR-378d, miR-378e, miR-320b, miR-320c, miR-320d, and miR-320e) increased in cases with NAFLD activity score (NAS) 5–8 compared with lower NAS, and 3 (miR-193a-5p, miR-378d, and miR-378e) increased but 1 (miR-19b-3p) decreased in steatosis, activity, and fibrosis (SAF) activity score 2–4 compared with lower SAF activity. The significant findings for miR-193a-5p were replicated in the additional cohort with NAFLD. Studies in Hep G2 cells showed that following palmitic acid treatment, miR-193a-5p expression decreased significantly. Gene targets for miR-193a-5p were investigated in liver RNAseq data for a case subgroup (n = 80); liver GPX8 levels correlated positively with serum miR-193a-5p. Conclusions: Serum miR-193a-5p levels correlate strongly with NAFLD activity grade and fibrosis stage. MiR-193a-5p may have a role in the hepatic response to oxidative stress and is a potential clinically tractable circulating biomarker for progressive NAFLD. Lay summary: MicroRNAs (miRNAs) are small pieces of nucleic acid that may turn expression of genes on or off. These molecules can be detected in the blood circulation, and their levels in blood may change in liver disease including non-alcoholic fatty liver disease (NAFLD). To see if we could detect specific miRNA associated with advanced stages of NAFLD, we carried out miRNA sequencing in a group of 183 patients with NAFLD of varying severity together with 10 population controls. We found that a number of miRNAs showed changes, mainly increases, in serum levels but that 1 particular miRNA miR-193a-5p consistently increased. We confirmed this increase in a second group of cases with NAFLD. Measuring this miRNA in a blood sample may be a useful way to determine whether a patient has advanced NAFLD without an invasive liver biopsy.

Published

2022

42. The stability of the circulating human proteome to variations in sample collection and handling procedures measured with an aptamer-based proteomics array

Author

Ostroff, Rachel, Foreman, Trudi, Keeney, Tracy R., Stratford, Suzanne, Walker, Jeffrey J., and Zichi, Dom

Published

2010

43. Performance of non-invasive tests and histology for the prediction of clinical outcomes in patients with non-alcoholic fatty liver disease: an individual participant data meta-analysis

Author

Mózes, Ferenc E, Lee, Jenny A, Vali, Yasaman, Alzoubi, Osama, Staufer, Katharina, Trauner, Michael, Paternostro, Rafael, Stauber, Rudolf E, Holleboom, Adriaan G, van Dijk, Anne-Marieke, Mak, Anne Linde, Boursier, Jérôme, de Saint Loup, Marc, Shima, Toshihide, Bugianesi, Elisabetta, Gaia, Silvia, Armandi, Angelo, Shalimar, Lupșor-Platon, Monica, Wong, Vincent Wai-Sun, Li, Guanlin, Wong, Grace Lai-Hung, Cobbold, Jeremy, Karlas, Thomas, Wiegand, Johannes, Sebastiani, Giada, Tsochatzis, Emmanuel, Liguori, Antonio, Yoneda, Masato, Nakajima, Atsushi, Hagström, Hannes, Akbari, Camilla, Hirooka, Masashi, Chan, Wah-Kheong, Mahadeva, Sanjiv, Rajaram, Ruveena, Zheng, Ming-Hua, George, Jacob, Eslam, Mohammed, Petta, Salvatore, Pennisi, Grazia, Viganò, Mauro, Ridolfo, Sofia, Aithal, Guruprasad Padur, Palaniyappan, Naaventhan, Lee, Dae Ho, Ekstedt, Mattias, Nasr, Patrik, Cassinotto, Christophe, de Lédinghen, Victor, Berzigotti, Annalisa, Mendoza, Yuly P, Noureddin, Mazen, Truong, Emily, Fournier-Poizat, Céline, Geier, Andreas, Martic, Miljen, Tuthill, Theresa, Anstee, Quentin M, Harrison, Stephen A, Bossuyt, Patrick M, Pavlides, Michael, Anstee, Quentin M, Daly, Ann K, Govaere, Olivier, Cockell, Simon, Tiniakos, Dina, Bedossa, Pierre, Burt, Alastair, Oakley, Fiona, Cordell, Heather J, Day, Christopher P, Wonders, Kristy, Missier, Paolo, McTeer, Matthew, Vale, Luke, Oluboyede, Yemi, Breckons, Matt, Bossuyt, Patrick M, Zafarmand, Hadi, Vali, Yasaman, Lee, Jenny, Nieuwdorp, Max, Holleboom, Adriaan G, Verheij, Joanne, Ratziu, Vlad, Clément, Karine, Patino-Navarrete, Rafael, Pais, Raluca, Paradis, Valerie, Schuppan, Detlef, Schattenberg, Jörn M, Surabattula, Rambabu, Myneni, Sudha, Straub, Beate K, Vidal-Puig, Toni, Vacca, Michele, Rodrigues-Cuenca, Sergio, Allison, Mike, Kamzolas, Ioannis, Petsalaki, Evangelia, Campbell, Mark, Lelliott, Chris J, Davies, Susan, Orešič, Matej, Hyötyläinen, Tuulia, McGlinchey, Aiden, Mato, Jose M, Millet, Óscar, Dufour, Jean-François, Berzigotti, Annalisa, Masoodi, Mojgan, Pavlides, Michael, Harrison, Stephen, Neubauer, Stefan, Cobbold, Jeremy, Mozes, Ferenc, Akhtar, Salma, Olodo-Atitebi, Seliat, Banerjee, Rajarshi, Kelly, Matt, Shumbayawonda, Elizabeth, Dennis, Andrea, Andersson, Anneli, Wigley, Ioan, Romero-Gómez, Manuel, Gómez-González, Emilio, Ampuero, Javier, Castell, Javier, Gallego-Durán, Rocío, Fernández, Isabel, Montero-Vallejo, Rocío, Karsdal, Morten, Rasmussen, Daniel Guldager Kring, Leeming, Diana Julie, Sinisi, Antonia, Musa, Kishwar, Sandt, Estelle, Tonini, Manuela, Bugianesi, Elisabetta, Rosso, Chiara, Armandi, Angelo, Marra, Fabio, Gastaldelli, Amalia, Svegliati, Gianluca, Boursier, Jérôme, Francque, Sven, Vonghia, Luisa, Driessen, Ann, Ekstedt, Mattias, Kechagias, Stergios, Yki-Järvinen, Hannele, Porthan, Kimmo, Arola, Johanna, van Mil, Saskia, Papatheodoridis, George, Cortez-Pinto, Helena, Rodrigues, Cecilia M P, Valenti, Luca, Pelusi, Serena, Petta, Salvatore, Pennisi, Grazia, Miele, Luca, Geier, Andreas, Trautwein, Christian, Reißing, Johanna, Aithal, Guruprasad P, Francis, Susan, Palaniyappan, Naaventhan, Bradley, Christopher, Hockings, Paul, Schneider, Moritz, Newsome, Philip, Hübscher, Stefan, Wenn, David, Rosenquist, Christian, Trylesinski, Aldo, Mayo, Rebeca, Alonso, Cristina, Duffin, Kevin, Perfield, James W, Chen, Yu, Yunis, Carla, Tuthill, Theresa, Harrington, Magdalena Alicia, Miller, Melissa, Chen, Yan, McLeod, Euan James, Ross, Trenton, Bernardo, Barbara, Schölch, Corinna, Ertle, Judith, Younes, Ramy, Oldenburger, Anouk, Coxson, Harvey, Ostroff, Rachel, Alexander, Leigh, Biegel, Hannah, Kjær, Mette Skalshøi, Harder, Lea Mørch, Davidsen, Peter, Ellegaard, Jens, Balp, Maria-Magdalena, Brass, Clifford, Jennings, Lori, Martic, Miljen, Löffler, Jürgen, Applegate, Douglas, Shankar, Sudha, Torstenson, Richard, Lindén, Daniel, Fournier-Poizat, Céline, Llorca, Anne, Kalutkiewicz, Michael, Pepin, Kay, Ehman, Richard, Horan, Gerald, Ho, Gideon, Tai, Dean, Chng, Elaine, Patterson, Scott D, Billin, Andrew, Doward, Lynda, Twiss, James, Thakker, Paresh, Derdak, Zoltan, Landgren, Henrik, Lackner, Carolin, Gouw, Annette, and Hytiroglou, Prodromos

Abstract

Histologically assessed liver fibrosis stage has prognostic significance in patients with non-alcoholic fatty liver disease (NAFLD) and is accepted as a surrogate endpoint in clinical trials for non-cirrhotic NAFLD. Our aim was to compare the prognostic performance of non-invasive tests with liver histology in patients with NAFLD.

Published

2023

44. Abstract 11537: Progress Towards a Proteomic Surrogate Endpoint for Cardiovascular Outcomes

Author

Williams, Stephen A, primary, Ostroff, Rachel, additional, Hinterberg, Michael, additional, Coresh, Josef, additional, Ballantyne, Christie M, additional, Matsushita, Kunihiro, additional, Mueller, Christian, additional, Walter, Joan E, additional, Jonasson, Christian, additional, Holman, Rury H, additional, Shah, Svati H, additional, Sattar, Naveed, additional, Taylor, Roy, additional, Lean, Michael, additional, Kato, Shintaro, additional, Shimokawa, Hiroaki, additional, Sakata, Yasuhito, additional, Nochioka, Kotaro, additional, Parikh, Chirag, additional, Coca, Steven, additional, Omland, Torbjoern, additional, Chadwick, Jessica, additional, Astling, David, additional, Hagar, Yolanda, additional, Kurieski, Natasha, additional, Primus, Jeremy, additional, Simpson, Missy, additional, Trujillo, Nelson P, additional, and Ganz, Peter, additional

Published

2021

45. Diagnostic accuracy of elastography and magnetic resonance imaging in patients with NAFLD: A systematic review and meta-analysis

Author

Selvaraj, Emmanuel Anandraj, primary, Mózes, Ferenc Emil, additional, Jayaswal, Arjun Narayan Ajmer, additional, Zafarmand, Mohammad Hadi, additional, Vali, Yasaman, additional, Lee, Jenny A., additional, Levick, Christina Kim, additional, Young, Liam Arnold Joseph, additional, Palaniyappan, Naaventhan, additional, Liu, Chang-Hai, additional, Aithal, Guruprasad Padur, additional, Romero-Gómez, Manuel, additional, Brosnan, M. Julia, additional, Tuthill, Theresa A., additional, Anstee, Quentin M., additional, Neubauer, Stefan, additional, Harrison, Stephen A., additional, Bossuyt, Patrick M., additional, Pavlides, Michael, additional, Anstee, Quentin, additional, Daly, Ann, additional, Johnson, Katherine, additional, Govaere, Olivier, additional, Cockell, Simon, additional, Tiniakos, Dina, additional, Bedossa, Pierre, additional, Oakley, Fiona, additional, Cordell, Heather, additional, Day, Chris, additional, Wonders, Kristy, additional, Bossuyt, Patrick, additional, Zafarmand, Hadi, additional, Lee, Jenny, additional, Ratziu, Vlad, additional, Clement, Karine, additional, Pais, Raluca, additional, Schuppan, Detlef, additional, Schattenberg, Jörn, additional, Vidal-Puig, Toni, additional, Vacca, Michele, additional, Rodrigues-Cuenca, Sergio, additional, Allison, Mike, additional, Kamzolas, Ioannis, additional, Petsalaki, Evangelia, additional, Oresic, Matej, additional, Hyötyläinen, Tuulia, additional, McGlinchey, Aiden, additional, Mato, Jose M., additional, Millet, Oscar, additional, Dufour, Jean-François, additional, Berzigotti, Annalisa, additional, Harrison, Stephen, additional, Cobbold, Jeremy, additional, Mozes, Ferenc, additional, Akhtar, Salma, additional, Banerjee, Rajarshi, additional, Kelly, Matt, additional, Shumbayawonda, Elizabeth, additional, Dennis, Andrea, additional, Erpicum, Charlotte, additional, Gómez-González, Emilio, additional, Ampuero, Javier, additional, Castell, Javier, additional, Gallego-Durán, Rocío, additional, Fernández, Isabel, additional, Montero-Vallejo, Rocío, additional, Karsdal, Morten, additional, Erhardtsen, Elisabeth, additional, Rasmussen, Daniel, additional, Leeming, Diana Julie, additional, Fisker, Mette Juul, additional, Sinisi, Antonia, additional, Musa, Kishwar, additional, Betsou, Fay, additional, Sandt, Estelle, additional, Tonini, Manuela, additional, Bugianesi, Elisabetta, additional, Rosso, Chiara, additional, Armandi, Angelo, additional, Marra, Fabio, additional, Gastaldelli, Amalia, additional, Svegliati, Gianluca, additional, Boursier, Jérôme, additional, Francque, Sven, additional, Vonghia, Luisa, additional, Ekstedt, Mattias, additional, Kechagias, Stergios, additional, Yki-Jarvinen, Hannele, additional, Luukkonen, Panu, additional, van Mil, Saskia, additional, Papatheodoridis, George, additional, Cortez-Pinto, Helena, additional, Valenti, Luca, additional, Petta, Salvatore, additional, Miele, Luca, additional, Geier, Andreas, additional, Trautwein, Christian, additional, Aithal, Guru, additional, Hockings, Paul, additional, Newsome, Philip, additional, Wenn, David, additional, Pereira Rodrigues, Cecília Maria, additional, Chaumat, Pierre, additional, Hanf, Rémy, additional, Trylesinski, Aldo, additional, Ortiz, Pablo, additional, Duffin, Kevin, additional, Brosnan, Julia, additional, Tuthill, Theresa, additional, McLeod, Euan, additional, Ertle, Judith, additional, Younes, Ramy, additional, Ostroff, Rachel, additional, Alexander, Leigh, additional, Kjær, Mette Skalshøi, additional, Mikkelsen, Lars Friis, additional, Balp, Maria-Magdalena, additional, Brass, Clifford, additional, Jennings, Lori, additional, Martic, Miljen, additional, Loeffler, Juergen, additional, Hanauer, Guido, additional, Shankar, Sudha, additional, Fournier, Céline, additional, Pepin, Kay, additional, Ehman, Richard, additional, Myers, Joel, additional, Ho, Gideon, additional, Torstenson, Richard, additional, Myers, Rob, additional, and Doward, Lynda, additional

Published

2021

46. Mechanisms of sodium-glucose cotransporter-2 inhibition: Insights from Large-Scale Proteomics

Author

Ferrannini, Ele, Murthy, Ashwin C., Lee, Yong-ho, Muscelli, Elza, Weiss, Sophie, Ostroff, Rachel M., Sattar, Naveed, Williams, Stephen A., and Ganz, Peter

Abstract

Objective To assess the effects of empagliflozin, a selective SGLT2 inhibitor, on broad biological systems through proteomics.Research Design and Methods 3,713 proteins were quantified using aptamer-based proteomics in 144 paired plasma samples obtained from 72 participants across the spectrum of glucose tolerance, before and after 4 weeks of empagliflozin 25 mg/day. Biology of the plasma proteins significantly changed by empagliflozin (at false discovery rate-corrected pResults Empagliflozin significantly affected levels of 43 proteins, 6 related to cardiomyocyte function (fatty acid binding protein 3 and 4 (FABPA), neurotrophic receptor tyrosine kinase (NTRK2), renin, thrombospondin-4, and leptin receptor), 5 to iron handling (ferritin heavy chain 1, transferrin receptor protein 1 (TFRC), neogenin, growth differentiation factor 2 (GDF-2), and ß2-microglobulin) and 1 to spingosine/ceramide metabolism (neutral ceramidase), a known pathway of cardiovascular disease. Among the protein changes achieving the strongest statistical significance, insulin-like binding factor protein-1 (IGFBP-1), transgelin-2, FABPA, growth differentiation factor-15 (GDF15), and sulphydryl oxidase 2 precursor (QSOX2) were increased, while ferritin, thrombospondin-3, and REarranged during Transfection (RET) were decreased by empagliflozin administration Conclusion SGLT2 inhibition is associated, directly or indirectly, with multiple biological effects, including changes in markers of cardiomyocyte contraction/relaxation, iron handling, and other metabolic and renal targets. The most significant differences were detected in protein species (GDF15, ferritin, IGFBP-1 and FABP) potentially related to the clinical and metabolic changes that were actually measured in the same patients. These novel results may inform further studies, using targeted proteomics and a prospective design.

Published

2020

47. Highly Multiplexed Proteomic Platform for Biomarker Discovery, Diagnostics, and Therapeutics

Author

Mehan, Michael R., primary, Ostroff, Rachel, additional, Wilcox, Sheri K., additional, Steele, Fintan, additional, Schneider, Daniel, additional, Jarvis, Thale C., additional, Baird, Geoffrey S., additional, Gold, Larry, additional, and Janjic, Nebojsa, additional

Published

2012

48. Erratum. Coronary Artery Disease and Type 2 Diabetes: A Proteomic Study. Diabetes Care 2020;43:843–851

Author

Ferrannini, Giulia, primary, Manca, Maria Laura, additional, Magnoni, Marco, additional, Andreotti, Felicita, additional, Andreini, Daniele, additional, Latini, Roberto, additional, Maseri, Attilio, additional, Maggioni, Aldo P., additional, Ostroff, Rachel M., additional, Williams, Stephen A., additional, and Ferrannini, Ele, additional

Published

2021

49. Impact of Kidney Function on the Blood Proteome and on Protein Cardiovascular Risk Biomarkers in Patients With Stable Coronary Heart Disease

Author

Yang, Joseph, primary, Brody, Edward N., additional, Murthy, Ashwin C., additional, Mehler, Robert E., additional, Weiss, Sophie J., additional, DeLisle, Robert K., additional, Ostroff, Rachel, additional, Williams, Stephen A., additional, and Ganz, Peter, additional

Published

2020

50. Genetic architecture of host proteins interacting with SARS-CoV-2

Author

Pietzner, Maik, primary, Wheeler, Eleanor, additional, Carrasco-Zanini, Julia, additional, Raffler, Johannes, additional, Kerrison, Nicola D., additional, Oerton, Erin, additional, Auyeung, Victoria P.W., additional, Luan, Jian’an, additional, Finan, Chris, additional, Casas, Juan P., additional, Ostroff, Rachel, additional, Williams, Steve A., additional, Kastenmüller, Gabi, additional, Ralser, Markus, additional, Gamazon, Eric R., additional, Wareham, Nicholas J., additional, Hingorani, Aroon D., additional, and Langenberg, Claudia, additional

Published

2020