Your search keyword '"Protsyuk, Ivan"' showing total 22 results

1. Boosting the interpretability of clinical risk scores with intervention predictions

Author

Loreaux, Eric, Yu, Ke, Kemp, Jonas, Seneviratne, Martin, Chen, Christina, Roy, Subhrajit, Protsyuk, Ivan, Harris, Natalie, D'Amour, Alexander, Yadlowsky, Steve, and Chen, Ming-Jun

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence

Abstract

Machine learning systems show significant promise for forecasting patient adverse events via risk scores. However, these risk scores implicitly encode assumptions about future interventions that the patient is likely to receive, based on the intervention policy present in the training data. Without this important context, predictions from such systems are less interpretable for clinicians. We propose a joint model of intervention policy and adverse event risk as a means to explicitly communicate the model's assumptions about future interventions. We develop such an intervention policy model on MIMIC-III, a real world de-identified ICU dataset, and discuss some use cases that highlight the utility of this approach. We show how combining typical risk scores, such as the likelihood of mortality, with future intervention probability scores leads to more interpretable clinical predictions., Comment: Accepted by DSHealth on KDD 2022

Published

2022

2. Concept-based model explanations for Electronic Health Records

Author

Mincu, Diana, Loreaux, Eric, Hou, Shaobo, Baur, Sebastien, Protsyuk, Ivan, Seneviratne, Martin G, Mottram, Anne, Tomasev, Nenad, Karthikesanlingam, Alan, and Schrouff, Jessica

Subjects

Computer Science - Machine Learning, Computer Science - Computers and Society

Abstract

Recurrent Neural Networks (RNNs) are often used for sequential modeling of adverse outcomes in electronic health records (EHRs) due to their ability to encode past clinical states. These deep, recurrent architectures have displayed increased performance compared to other modeling approaches in a number of tasks, fueling the interest in deploying deep models in clinical settings. One of the key elements in ensuring safe model deployment and building user trust is model explainability. Testing with Concept Activation Vectors (TCAV) has recently been introduced as a way of providing human-understandable explanations by comparing high-level concepts to the network's gradients. While the technique has shown promising results in real-world imaging applications, it has not been applied to structured temporal inputs. To enable an application of TCAV to sequential predictions in the EHR, we propose an extension of the method to time series data. We evaluate the proposed approach on an open EHR benchmark from the intensive care unit, as well as synthetic data where we are able to better isolate individual effects.

Published

2020

3. Feature-based molecular networking in the GNPS analysis environment.

Author

Nothias, Louis-Félix, Petras, Daniel, Schmid, Robin, Dührkop, Kai, Rainer, Johannes, Sarvepalli, Abinesh, Protsyuk, Ivan, Ernst, Madeleine, Tsugawa, Hiroshi, Fleischauer, Markus, Aicheler, Fabian, Aksenov, Alexander A, Alka, Oliver, Allard, Pierre-Marie, Barsch, Aiko, Cachet, Xavier, Caraballo-Rodriguez, Andres Mauricio, Da Silva, Ricardo R, Dang, Tam, Garg, Neha, Gauglitz, Julia M, Gurevich, Alexey, Isaac, Giorgis, Jarmusch, Alan K, Kameník, Zdeněk, Kang, Kyo Bin, Kessler, Nikolas, Koester, Irina, Korf, Ansgar, Le Gouellec, Audrey, Ludwig, Marcus, Martin H, Christian, McCall, Laura-Isobel, McSayles, Jonathan, Meyer, Sven W, Mohimani, Hosein, Morsy, Mustafa, Moyne, Oriane, Neumann, Steffen, Neuweger, Heiko, Nguyen, Ngoc Hung, Nothias-Esposito, Melissa, Paolini, Julien, Phelan, Vanessa V, Pluskal, Tomáš, Quinn, Robert A, Rogers, Simon, Shrestha, Bindesh, Tripathi, Anupriya, van der Hooft, Justin JJ, Vargas, Fernando, Weldon, Kelly C, Witting, Michael, Yang, Heejung, Zhang, Zheng, Zubeil, Florian, Kohlbacher, Oliver, Böcker, Sebastian, Alexandrov, Theodore, Bandeira, Nuno, Wang, Mingxun, and Dorrestein, Pieter C

Subjects

Biological Products, Computational Biology, Software, Databases, Factual, Mass Spectrometry, Metabolomics, Biological Sciences, Technology, Medical and Health Sciences, Developmental Biology

Abstract

Molecular networking has become a key method to visualize and annotate the chemical space in non-targeted mass spectrometry data. We present feature-based molecular networking (FBMN) as an analysis method in the Global Natural Products Social Molecular Networking (GNPS) infrastructure that builds on chromatographic feature detection and alignment tools. FBMN enables quantitative analysis and resolution of isomers, including from ion mobility spectrometry.

Published

2020

4. Molecular and Microbial Microenvironments in Chronically Diseased Lungs Associated with Cystic Fibrosis

Author

Melnik, Alexey V, Vázquez-Baeza, Yoshiki, Aksenov, Alexander A, Hyde, Embriette, McAvoy, Andrew C, Wang, Mingxun, da Silva, Ricardo R, Protsyuk, Ivan, Wu, Jason V, Bouslimani, Amina, Lim, Yan Wei, Luzzatto-Knaan, Tal, Comstock, William, Quinn, Robert A, Wong, Richard, Humphrey, Greg, Ackermann, Gail, Spivey, Timothy, Brouha, Sharon S, Bandeira, Nuno, Lin, Grace Y, Rohwer, Forest, Conrad, Douglas J, Alexandrov, Theodore, Knight, Rob, Dorrestein, Pieter C, and Garg, Neha

Subjects

Microbiology, Biological Sciences, Biomedical and Clinical Sciences, Lung, Cystic Fibrosis, Emerging Infectious Diseases, Rare Diseases, Infectious Diseases, Aetiology, 2.1 Biological and endogenous factors, 2.2 Factors relating to the physical environment, Infection, Good Health and Well Being, GNPS, Pseudomonas, spatial mapping, Stenotrophomonas, antibiotic distribution, cystic fibrosis, metabolomics, microbiome

Abstract

To visualize the personalized distributions of pathogens and chemical environments, including microbial metabolites, pharmaceuticals, and their metabolic products, within and between human lungs afflicted with cystic fibrosis (CF), we generated three-dimensional (3D) microbiome and metabolome maps of six explanted lungs from three cystic fibrosis patients. These 3D spatial maps revealed that the chemical environments differ between patients and within the lungs of each patient. Although the microbial ecosystems of the patients were defined by the dominant pathogen, their chemical diversity was not. Additionally, the chemical diversity between locales in the lungs of the same individual sometimes exceeded interindividual variation. Thus, the chemistry and microbiome of the explanted lungs appear to be not only personalized but also regiospecific. Previously undescribed analogs of microbial quinolones and antibiotic metabolites were also detected. Furthermore, mapping the chemical and microbial distributions allowed visualization of microbial community interactions, such as increased production of quorum sensing quinolones in locations where Pseudomonas was in contact with Staphylococcus and Granulicatella, consistent with in vitro observations of bacteria isolated from these patients. Visualization of microbe-metabolite associations within a host organ in early-stage CF disease in animal models will help elucidate the complex interplay between the presence of a given microbial structure, antibiotics, metabolism of antibiotics, microbial virulence factors, and host responses.IMPORTANCE Microbial infections are now recognized to be polymicrobial and personalized in nature. Comprehensive analysis and understanding of the factors underlying the polymicrobial and personalized nature of infections remain limited, especially in the context of the host. By visualizing microbiomes and metabolomes of diseased human lungs, we reveal how different the chemical environments are between hosts that are dominated by the same pathogen and how community interactions shape the chemical environment or vice versa. We highlight that three-dimensional organ mapping methods represent hypothesis-building tools that allow us to design mechanistic studies aimed at addressing microbial responses to other microbes, the host, and pharmaceutical drugs.

Published

2019

5. Creating a 3D microbial and chemical snapshot of a human habitat.

Author

Kapono, Clifford A, Morton, James T, Bouslimani, Amina, Melnik, Alexey V, Orlinsky, Kayla, Knaan, Tal Luzzatto, Garg, Neha, Vázquez-Baeza, Yoshiki, Protsyuk, Ivan, Janssen, Stefan, Zhu, Qiyun, Alexandrov, Theodore, Smarr, Larry, Knight, Rob, and Dorrestein, Pieter C

Subjects

Humans, Ecosystem, Air Pollution, Indoor, Mass Spectrometry, Microbiota

Abstract

One of the goals of forensic science is to identify individuals and their lifestyle by analyzing the trace signatures left behind in built environments. Here, microbiome and metabolomic methods were used to see how its occupants used an office and to also gain insights into the lifestyle characteristics such as diet, medications, and personal care products of the occupants. 3D molecular cartography, a molecular visualization technology, was used in combination with mass spectrometry and microbial inventories to highlight human-environmental interactions. Molecular signatures were correlated with the individuals as well as their interactions with this indoor environment. There are person-specific chemical and microbial signatures associated with this environment that directly relate who had touched objects such as computers, computer mice, cell phones, desk phone, table or desks. By combining molecular and microbial investigation forensic strategies, this study offers novel insights to investigators who value the reconstructing of human lifestyle and characterization of human environmental interaction.

Published

2018

6. Three-Dimensional Microbiome and Metabolome Cartography of a Diseased Human Lung

Author

Garg, Neha, Wang, Mingxun, Hyde, Embriette, da Silva, Ricardo R, Melnik, Alexey V, Protsyuk, Ivan, Bouslimani, Amina, Lim, Yan Wei, Wong, Richard, Humphrey, Greg, Ackermann, Gail, Spivey, Timothy, Brouha, Sharon S, Bandeira, Nuno, Lin, Grace Y, Rohwer, Forest, Conrad, Douglas J, Alexandrov, Theodore, Knight, Rob, and Dorrestein, Pieter C

Subjects

Microbiology, Biological Sciences, Biomedical and Clinical Sciences, Medical Biochemistry and Metabolomics, Lung, Human Genome, Lung Cancer, Cancer, Genetics, Adult, Base Sequence, Biodiversity, Cystic Fibrosis, DNA, Bacterial, Humans, Imaging, Three-Dimensional, Lung Diseases, Male, Mass Spectrometry, Metabolome, Metabolomics, Microbiota, RNA, Ribosomal, 16S, RNA, Ribosomal, 18S, Tomography Scanners, X-Ray Computed, Xenobiotics, cartography, cystic fibrosis, mass spectrometry, metabolomics, microbiome, molecular networking, Medical Microbiology, Immunology, Biochemistry and cell biology, Medical microbiology

Abstract

Our understanding of the spatial variation in the chemical and microbial makeup of an entire human organ remains limited, in part due to the size and heterogeneity of human organs and the complexity of the associated metabolome and microbiome. To address this challenge, we developed a workflow to enable the cartography of metabolomic and microbiome data onto a three-dimensional (3D) organ reconstruction built off radiological images. This enabled the direct visualization of the microbial and chemical makeup of a human lung from a cystic fibrosis patient. We detected host-derived molecules, microbial metabolites, medications, and region-specific metabolism of medications and placed it in the context of microbial distributions in the lung. Our tool further created browsable maps of a 3D microbiome/metabolome reconstruction map on a radiological image of a human lung and forms an interactive resource for the scientific community.

Published

2017

7. Use of deep learning to develop continuous-risk models for adverse event prediction from electronic health records

Author

Tomašev, Nenad, Harris, Natalie, Baur, Sebastien, Mottram, Anne, Glorot, Xavier, Rae, Jack W., Zielinski, Michal, Askham, Harry, Saraiva, Andre, Magliulo, Valerio, Meyer, Clemens, Ravuri, Suman, Protsyuk, Ivan, Connell, Alistair, Hughes, Cían O., Karthikesalingam, Alan, Cornebise, Julien, Montgomery, Hugh, Rees, Geraint, Laing, Chris, Baker, Clifton R., Osborne, Thomas F., Reeves, Ruth, Hassabis, Demis, King, Dominic, Suleyman, Mustafa, Back, Trevor, Nielson, Christopher, Seneviratne, Martin G., Ledsam, Joseph R., and Mohamed, Shakir

Published

2021

8. Mass Spectrometry-Based Visualization of Molecules Associated with Human Habitats

Author

Petras, Daniel, Nothias, Louis-Félix, Quinn, Robert A, Alexandrov, Theodore, Bandeira, Nuno, Bouslimani, Amina, Castro-Falcón, Gabriel, Chen, Liangyu, Dang, Tam, Floros, Dimitrios J, Hook, Vivian, Garg, Neha, Hoffner, Nicole, Jiang, Yike, Kapono, Clifford A, Koester, Irina, Knight, Rob, Leber, Christopher A, Ling, Tie-Jun, Luzzatto-Knaan, Tal, McCall, Laura-Isobel, McGrath, Aaron P, Meehan, Michael J, Merritt, Jonathan K, Mills, Robert H, Morton, Jamie, Podvin, Sonia, Protsyuk, Ivan, Purdy, Trevor, Satterfield, Kendall, Searles, Stephen, Shah, Sahil, Shires, Sarah, Steffen, Dana, White, Margot, Todoric, Jelena, Tuttle, Robert, Wojnicz, Aneta, Sapp, Valerie, Vargas, Fernando, Yang, Jin, Zhang, Chao, and Dorrestein, Pieter C

Subjects

Analytical Chemistry, Chemical Sciences, Chromatography, Liquid, Ecosystem, Humans, Ions, Mass Spectrometry, Organic Chemicals, Tandem Mass Spectrometry, Other Chemical Sciences, Medical biochemistry and metabolomics, Analytical chemistry, Chemical engineering

Abstract

The cars we drive, the homes we live in, the restaurants we visit, and the laboratories and offices we work in are all a part of the modern human habitat. Remarkably, little is known about the diversity of chemicals present in these environments and to what degree molecules from our bodies influence the built environment that surrounds us and vice versa. We therefore set out to visualize the chemical diversity of five built human habitats together with their occupants, to provide a snapshot of the various molecules to which humans are exposed on a daily basis. The molecular inventory was obtained through untargeted liquid chromatography-tandem mass spectrometry (LC-MS/MS) analysis of samples from each human habitat and from the people that occupy those habitats. Mapping MS-derived data onto 3D models of the environments showed that frequently touched surfaces, such as handles (e.g., door, bicycle), resemble the molecular fingerprint of the human skin more closely than other surfaces that are less frequently in direct contact with humans (e.g., wall, bicycle frame). Approximately 50% of the MS/MS spectra detected were shared between people and the environment. Personal care products, plasticizers, cleaning supplies, food, food additives, and even medications that were found to be a part of the human habitat. The annotations indicate that significant transfer of chemicals takes place between us and our built environment. The workflows applied here will lay the foundation for future studies of molecular distributions in medical, forensic, architectural, space exploration, and environmental applications.

Published

2016

9. A clinically applicable approach to continuous prediction of future acute kidney injury

Author

Tomašev, Nenad, Glorot, Xavier, Rae, Jack W., Zielinski, Michal, Askham, Harry, Saraiva, Andre, Mottram, Anne, Meyer, Clemens, Ravuri, Suman, Protsyuk, Ivan, Connell, Alistair, Hughes, Cían O., Karthikesalingam, Alan, Cornebise, Julien, Montgomery, Hugh, Rees, Geraint, Laing, Chris, Baker, Clifton R., Peterson, Kelly, Reeves, Ruth, Hassabis, Demis, King, Dominic, Suleyman, Mustafa, Back, Trevor, Nielson, Christopher, Ledsam, Joseph R., and Mohamed, Shakir

Published

2019

10. Meta-mass shift chemical profiling of metabolomes from coral reefs

Author

Hartmann, Aaron C., Petras, Daniel, Quinn, Robert A., Protsyuk, Ivan, Archer, Frederick I., Ransome, Emma, Williams, Gareth J., Bailey, Barbara A., Vermeij, Mark J. A., Alexandrov, Theodore, Dorrestein, Pieter C., and Rohwer, Forest L.

Published

2017

11. Shared Bioinformatics Databases within the Unipro UGENE Platform

Author

Protsyuk Ivan V., Grekhov German A., Tiunov Alexey V., and Fursov Mikhail Yu.

Subjects

Biotechnology, TP248.13-248.65

Abstract

Unipro UGENE is an open-source bioinformatics toolkit that integrates popular tools along with original instruments for molecular biologists within a unified user interface. Nowadays, most bioinformatics desktop applications, including UGENE, make use of a local data model while processing different types of data. Such an approach causes an inconvenience for scientists working cooperatively and relying on the same data. This refers to the need of making multiple copies of certain files for every workplace and maintaining synchronization between them in case of modifications. Therefore, we focused on delivering a collaborative work into the UGENE user experience. Currently, several UGENE installations can be connected to a designated shared database and users can interact with it simultaneously. Such databases can be created by UGENE users and be used at their discretion. Objects of each data type, supported by UGENE such as sequences, annotations, multiple alignments, etc., can now be easily imported from or exported to a remote storage. One of the main advantages of this system, compared to existing ones, is the almost simultaneous access of client applications to shared data regardless of their volume. Moreover, the system is capable of storing millions of objects. The storage itself is a regular database server so even an inexpert user is able to deploy it. Thus, UGENE may provide access to shared data for users located, for example, in the same laboratory or institution. UGENE is available at: http://ugene.net/download.html.

Published

2015

12. Multitask prediction of organ dysfunction in the intensive care unit using sequential subnetwork routing

Author

Roy, Subhrajit, primary, Mincu, Diana, additional, Loreaux, Eric, additional, Mottram, Anne, additional, Protsyuk, Ivan, additional, Harris, Natalie, additional, Xue, Yuan, additional, Schrouff, Jessica, additional, Montgomery, Hugh, additional, Connell, Alistair, additional, Tomasev, Nenad, additional, Karthikesalingam, Alan, additional, and Seneviratne, Martin, additional

Published

2021

13. Concept-based model explanations for electronic health records

Author

Mincu, Diana, primary, Loreaux, Eric, additional, Hou, Shaobo, additional, Baur, Sebastien, additional, Protsyuk, Ivan, additional, Seneviratne, Martin, additional, Mottram, Anne, additional, Tomasev, Nenad, additional, Karthikesalingam, Alan, additional, and Schrouff, Jessica, additional

Published

2021

14. Feature-based molecular networking in the GNPS analysis environment

Author

Nothias, Louis Félix, Petras, Daniel, Schmid, Robin, Dührkop, Kai, Rainer, Johannes, Sarvepalli, Abinesh, Protsyuk, Ivan, Ernst, Madeleine, Tsugawa, Hiroshi, Fleischauer, Markus, Aicheler, Fabian, Aksenov, Alexander A., Alka, Oliver, Allard, Pierre Marie, Barsch, Aiko, Cachet, Xavier, Caraballo-Rodriguez, Andres Mauricio, Da Silva, Ricardo R., Dang, Tam, Garg, Neha, Gauglitz, Julia M., Gurevich, Alexey, Isaac, Giorgis, Jarmusch, Alan K., Kameník, Zdeněk, Kang, Kyo Bin, Kessler, Nikolas, Koester, Irina, Korf, Ansgar, Le Gouellec, Audrey, Ludwig, Marcus, Martin H, Christian, McCall, Laura Isobel, McSayles, Jonathan, Meyer, Sven W., Mohimani, Hosein, Morsy, Mustafa, Moyne, Oriane, Neumann, Steffen, Neuweger, Heiko, Nguyen, Ngoc Hung, Nothias-Esposito, Melissa, Paolini, Julien, Phelan, Vanessa V., Pluskal, Tomáš, Quinn, Robert A., Rogers, Simon, Shrestha, Bindesh, Tripathi, Anupriya, van der Hooft, Justin J.J., Vargas, Fernando, Weldon, Kelly C., Witting, Michael, Yang, Heejung, Zhang, Zheng, Zubeil, Florian, Kohlbacher, Oliver, Böcker, Sebastian, Alexandrov, Theodore, Bandeira, Nuno, Wang, Mingxun, Dorrestein, Pieter C., Nothias, Louis Félix, Petras, Daniel, Schmid, Robin, Dührkop, Kai, Rainer, Johannes, Sarvepalli, Abinesh, Protsyuk, Ivan, Ernst, Madeleine, Tsugawa, Hiroshi, Fleischauer, Markus, Aicheler, Fabian, Aksenov, Alexander A., Alka, Oliver, Allard, Pierre Marie, Barsch, Aiko, Cachet, Xavier, Caraballo-Rodriguez, Andres Mauricio, Da Silva, Ricardo R., Dang, Tam, Garg, Neha, Gauglitz, Julia M., Gurevich, Alexey, Isaac, Giorgis, Jarmusch, Alan K., Kameník, Zdeněk, Kang, Kyo Bin, Kessler, Nikolas, Koester, Irina, Korf, Ansgar, Le Gouellec, Audrey, Ludwig, Marcus, Martin H, Christian, McCall, Laura Isobel, McSayles, Jonathan, Meyer, Sven W., Mohimani, Hosein, Morsy, Mustafa, Moyne, Oriane, Neumann, Steffen, Neuweger, Heiko, Nguyen, Ngoc Hung, Nothias-Esposito, Melissa, Paolini, Julien, Phelan, Vanessa V., Pluskal, Tomáš, Quinn, Robert A., Rogers, Simon, Shrestha, Bindesh, Tripathi, Anupriya, van der Hooft, Justin J.J., Vargas, Fernando, Weldon, Kelly C., Witting, Michael, Yang, Heejung, Zhang, Zheng, Zubeil, Florian, Kohlbacher, Oliver, Böcker, Sebastian, Alexandrov, Theodore, Bandeira, Nuno, Wang, Mingxun, and Dorrestein, Pieter C.

Abstract

Molecular networking has become a key method to visualize and annotate the chemical space in non-targeted mass spectrometry data. We present feature-based molecular networking (FBMN) as an analysis method in the Global Natural Products Social Molecular Networking (GNPS) infrastructure that builds on chromatographic feature detection and alignment tools. FBMN enables quantitative analysis and resolution of isomers, including from ion mobility spectrometry.

Published

2020

15. Feature-based Molecular Networking in the GNPS Analysis Environment

Author

Nothias, Louis Felix, primary, Petras, Daniel, additional, Schmid, Robin, additional, Dührkop, Kai, additional, Rainer, Johannes, additional, Sarvepalli, Abinesh, additional, Protsyuk, Ivan, additional, Ernst, Madeleine, additional, Tsugawa, Hiroshi, additional, Fleischauer, Markus, additional, Aicheler, Fabian, additional, Aksenov, Alexander, additional, Alka, Oliver, additional, Allard, Pierre-Marie, additional, Barsch, Aiko, additional, Cachet, Xavier, additional, Caraballo, Mauricio, additional, Da Silva, Ricardo R., additional, Dang, Tam, additional, Garg, Neha, additional, Gauglitz, Julia M., additional, Gurevich, Alexey, additional, Isaac, Giorgis, additional, Jarmusch, Alan K., additional, Kameník, Zdeněk, additional, Kang, Kyo Bin, additional, Kessler, Nikolas, additional, Koester, Irina, additional, Korf, Ansgar, additional, Gouellec, Audrey Le, additional, Ludwig, Marcus, additional, Christian, Martin H., additional, McCall, Laura-Isobel, additional, McSayles, Jonathan, additional, Meyer, Sven W., additional, Mohimani, Hosein, additional, Morsy, Mustafa, additional, Moyne, Oriane, additional, Neumann, Steffen, additional, Neuweger, Heiko, additional, Nguyen, Ngoc Hung, additional, Nothias-Esposito, Melissa, additional, Paolini, Julien, additional, Phelan, Vanessa V., additional, Pluskal, Tomáš, additional, Quinn, Robert A., additional, Rogers, Simon, additional, Shrestha, Bindesh, additional, Tripathi, Anupriya, additional, van der Hooft, Justin J.J., additional, Vargas, Fernando, additional, Weldon, Kelly C., additional, Witting, Michael, additional, Yang, Heejung, additional, Zhang, Zheng, additional, Zubeil, Florian, additional, Kohlbacher, Oliver, additional, Böcker, Sebastian, additional, Alexandrov, Theodore, additional, Bandeira, Nuno, additional, Wang, Mingxun, additional, and Dorrestein, Pieter C., additional

Published

2019

16. Developing Deep Learning Continuous Risk Models for Early Adverse Event Prediction in Electronic Health Records: an AKI Case Study

Author

Tomašev, Nenad, primary, Glorot, Xavier, additional, Rae, Jack W., additional, Zielinski, Michal, additional, Askham, Harry, additional, Saraiva, Andre, additional, Mottram, Anne, additional, Meyer, Clemens, additional, Ravuri, Suman, additional, Protsyuk, Ivan, additional, Connell, Alistair, additional, Hughes, Cían O., additional, Karthikesalingam, Alan, additional, Cornebise, Julien, additional, Montgomery, Hugh, additional, Rees, Geraint, additional, Laing, Chris, additional, Baker, Clifton R., additional, Peterson, Kelly, additional, Reeves, Ruth, additional, Hassabis, Demis, additional, King, Dominic, additional, Suleyman, Mustafa, additional, Back, Trevor, additional, Nielson, Christopher, additional, Ledsam, Joseph R., additional, and Mohamed, Shakir, additional

Published

2019

17. The Molecular and Microbial Microenvironments in Chronically Diseased Lungs

Author

Melnik, Alexey V., primary, Vázquez-Baeza, Yoshiki, additional, Aksenov, Alexander A., additional, Hyde, Embriette, additional, McAvoy, Andrew C, additional, Wang, Mingxun, additional, da Silva, Ricardo R., additional, Protsyuk, Ivan, additional, Wu, Jason V., additional, Bouslimani, Amina, additional, Lim, Yan Wei, additional, Luzzatto-Knaan, Tal, additional, Comstock, William, additional, Quinn, Robert A., additional, Wong, Richard, additional, Humphrey, Greg, additional, Ackermann, Gail, additional, Spivey, Timothy, additional, Brouha, Sharon S., additional, Bandeira, Nuno, additional, Lin, Grace Y., additional, Rohwer, Forest, additional, Conrad, Douglas J., additional, Alexandrov, Theodore, additional, Knight, Rob, additional, Dorrestein, Pieter C., additional, and Garg, Neha, additional

Published

2019

18. Bioactivity-Based Molecular Networking for the Discovery of Drug Leads in Natural Product Bioassay-Guided Fractionation

Author

Nothias, Louis-Félix, primary, Nothias-Esposito, Mélissa, additional, da Silva, Ricardo, additional, Wang, Mingxun, additional, Protsyuk, Ivan, additional, Zhang, Zheng, additional, Sarvepalli, Abi, additional, Leyssen, Pieter, additional, Touboul, David, additional, Costa, Jean, additional, Paolini, Julien, additional, Alexandrov, Theodore, additional, Litaudon, Marc, additional, and Dorrestein, Pieter C., additional

Published

2018

19. Three Dimensional Cartography of Microbiome and Metabolome Data onto Radiological Images of the Human Lung

Author

Garg, Neha, primary, Wang, Mingxun, additional, Hyde, Embriette, additional, da Silva, Ricardo, additional, Melnik, Alexey, additional, Protsyuk, Ivan, additional, Bouslimani, Amina, additional, Lim, Yan Wei, additional, Wong, Richard, additional, Humphrey, Greg, additional, Ackermann, Gail, additional, Spivey, Timothy, additional, Brouha, Sharon, additional, Bandeira, Nuno, additional, Lin, Grace, additional, Rohwer, Forest, additional, Conrad, Douglas, additional, Alexandrov, Theodore, additional, Knight, Rob, additional, and Dorrestein, Pieter, additional

Published

2018

20. 3D molecular cartography using LC–MS facilitated by Optimus and 'ili software

Author

Protsyuk, Ivan, primary, Melnik, Alexey V, additional, Nothias, Louis-Felix, additional, Rappez, Luca, additional, Phapale, Prasad, additional, Aksenov, Alexander A, additional, Bouslimani, Amina, additional, Ryazanov, Sergey, additional, Dorrestein, Pieter C, additional, and Alexandrov, Theodore, additional

Published

2017

21. Coupling Targeted and Untargeted Mass Spectrometry for Metabolome-Microbiome-Wide Association Studies of Human Fecal Samples

Author

Melnik, Alexey V., primary, da Silva, Ricardo R., additional, Hyde, Embriette R., additional, Aksenov, Alexander A., additional, Vargas, Fernando, additional, Bouslimani, Amina, additional, Protsyuk, Ivan, additional, Jarmusch, Alan K., additional, Tripathi, Anupriya, additional, Alexandrov, Theodore, additional, Knight, Rob, additional, and Dorrestein, Pieter C., additional

Published

2017

22. 3D molecular cartography using LC–MS facilitated by Optimus and 'ili software

Author

Protsyuk, Ivan, Melnik, Alexey V, Nothias, Louis-Felix, Rappez, Luca, Phapale, Prasad, Aksenov, Alexander A, Bouslimani, Amina, Ryazanov, Sergey, Dorrestein, Pieter C, and Alexandrov, Theodore

Abstract

Our skin, our belongings, the world surrounding us, and the environment we live in are covered with molecular traces. Detecting and characterizing these molecular traces is necessary to understand the environmental impact on human health and disease, and to decipher complex molecular interactions between humans and other species, particularly microbiota. We recently introduced 3D molecular cartography for mapping small organic molecules (including metabolites, lipids, and environmental molecules) found on various surfaces, including the human body. Here, we provide a protocol and open-source software for 3D molecular cartography. The protocol includes step-by-step procedures for sample collection and processing, liquid chromatography–mass spectrometry (LC–MS)-based metabolomics, quality control (QC), molecular identification using MS/MS, data processing, and visualization with 3D models of the sampled environment. The LC–MS method was optimized for a broad range of small organic molecules. We enable scientists to reproduce our previously obtained results, and illustrate the broad utility of our approach with molecular maps of a rosemary plant and an ATM keypad after a PIN code was entered. To promote reproducibility, we introduce cartographical snapshots: files that describe a particular map and visualization settings, and that can be shared and loaded to reproduce the visualization. The protocol enables molecular cartography to be performed in any mass spectrometry laboratory and, in principle, for any spatially mapped data. We anticipate applications, in particular, in medicine, ecology, agriculture, biotechnology, and forensics. The protocol takes 78 h for a molecular map of 100 spots, excluding the reagent setup.

Published

2018