Your search keyword '"Simon Wengert"' showing total 3 results

1. Data-efficient machine learning for molecular crystal structure prediction†

Author

Gábor Csányi, Simon Wengert, Karsten Reuter, Johannes T. Margraf, Csányi, Gábor [0000-0002-8180-2034], Margraf, Johannes T [0000-0002-0862-5289], and Apollo - University of Cambridge Repository

Subjects

Structure (mathematical logic), 010304 chemical physics, 34 Chemical Sciences, business.industry, Context (language use), Bioengineering, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Machine learning, computer.software_genre, 01 natural sciences, Crystal structure prediction, Crystal (programming language), Reference data, Range (mathematics), 3407 Theoretical and Computational Chemistry, Chemistry, Tight binding, 0103 physical sciences, Artificial intelligence, 0210 nano-technology, business, computer, Quantum

Abstract

The combination of modern machine learning (ML) approaches with high-quality data from quantum mechanical (QM) calculations can yield models with an unrivalled accuracy/cost ratio. However, such methods are ultimately limited by the computational effort required to produce the reference data. In particular, reference calculations for periodic systems with many atoms can become prohibitively expensive for higher levels of theory. This trade-off is critical in the context of organic crystal structure prediction (CSP). Here, a data-efficient ML approach would be highly desirable, since screening a huge space of possible polymorphs in a narrow energy range requires the assessment of a large number of trial structures with high accuracy. In this contribution, we present tailored Δ-ML models that allow screening a wide range of crystal candidates while adequately describing the subtle interplay between intermolecular interactions such as H-bonding and many-body dispersion effects. This is achieved by enhancing a physics-based description of long-range interactions at the density functional tight binding (DFTB) level—for which an efficient implementation is available—with a short-range ML model trained on high-quality first-principles reference data. The presented workflow is broadly applicable to different molecular materials, without the need for a single periodic calculation at the reference level of theory. We show that this even allows the use of wavefunction methods in CSP., Using a cluster-based training scheme and a physical baseline, data efficient machine-learning models for crystal structure prediction are developed, enabling accurate structural relaxations of molecular crystals with unprecedented efficiency.

Published

2021

2. Vascular tissue specific mirna profiles reveal novel correlations with risk factors in coronary artery disease

Author

Katrīna Neiburga, Baiba Vilne, Sabine Bauer, Dario Bongiovanni, Tilman Ziegler, Mark Lachmann, Simon Wengert, Johann Hawe, Ulrich Güldener, Annie Westerlund, Ling Li, Shichao Pang, Chuhua Yang, Kathrin Saar, Norbert Huebner, Lars Maegdefessel, null DigiMed Bayern Consortium, Rüdiger Lange, Markus Krane, Heribert Schunkert, and Moritz von Scheidt

Subjects

medicine.medical_specialty, Arteria Mammaria Interna, Biomarker, Biosensor, Cardiovascular Disease, Coronary Artery Bypass Grafting, Coronary Artery Disease, Local Therapy, Micro Rna, Personalized Medicine, coronary artery bypass grafting, Disease, biosensor, Microbiology, Biochemistry, arteria mammaria interna, Article, Coronary artery disease, Risk Factors, cardiovascular disease, Internal medicine, Diabetes mellitus, Diabetes Mellitus, medicine, Humans, Myocardial infarction, Molecular Biology, business.industry, Heart, personalized medicine, medicine.disease, QR1-502, Biomarker (cell), local therapy, micro RNA, MicroRNAs, medicine.anatomical_structure, Cardiovascular and Metabolic Diseases, Cardiology, biomarker, Personalized medicine, business, Risk assessment, coronary artery disease, Artery

Abstract

Cardiovascular disease (CVD) is the leading cause of morbidity and mortality worldwide. Non-coding RNAs have already been linked to CVD development and progression. While microRNAs (miRs) have been well studied in blood samples, there is little data on tissue-specific miRs in cardiovascular relevant tissues and their relation to cardiovascular risk factors. Tissue-specific miRs derived from Arteria mammaria interna (IMA) from 192 coronary artery disease (CAD) patients undergoing coronary artery bypass grafting (CABG) were analyzed. The aims of the study were 1) to establish a reference atlas which can be utilized for identification of novel diagnostic biomarkers and potential therapeutic targets, and 2) to relate these miRs to cardiovascular risk factors. Overall, 393 individual miRs showed sufficient expression levels and passed quality control for further analysis. We identified 17 miRs–miR-10b-3p, miR-10-5p, miR-17-3p, miR-21-5p, miR-151a-5p, miR-181a-5p, miR-185-5p, miR-194-5p, miR-199a-3p, miR-199b-3p, miR-212-3p, miR-363-3p, miR-548d-5p, miR-744-5p, miR-3117-3p, miR-5683 and miR-5701–significantly correlated with cardiovascular risk factors (correlation coefficient &gt, 0.2 in both directions, p-value (p &lt, 0.006, false discovery rate (FDR) &lt, 0.05). Of particular interest, miR-5701 was positively correlated with hypertension, hypercholesterolemia, and diabetes. In addition, we found that miR-629-5p and miR-98-5p were significantly correlated with acute myocardial infarction. We provide a first atlas of miR profiles in IMA samples from CAD patients. In perspective, these miRs might play an important role in improved risk assessment, mechanistic disease understanding and local therapy of CAD.

Published

2021

3. Mapping Materials and Molecules

Author

Noam Bernstein, Volker L. Deringer, Tamas Stenczel, Gábor Csányi, Karsten Reuter, Bonan Zhu, Simon Wengert, Ryan-Rhys Griffiths, Bingqing Cheng, Johannes T. Margraf, Christian Kunkel, Cheng, Bingqing [0000-0002-3584-9632], Deringer, Volker L [0000-0001-6873-0278], Reuter, Karsten [0000-0001-8473-8659], and Apollo - University of Cambridge Repository

Subjects

Structure (mathematical logic), 34 Chemical Sciences, 010405 organic chemistry, business.industry, Big data, General Medicine, General Chemistry, Construct (python library), 010402 general chemistry, 01 natural sciences, Data science, 0104 chemical sciences, Variety (cybernetics), Visualization, Data point, Scatter plot, Generic health relevance, 3404 Medicinal and Biomolecular Chemistry, Representation (mathematics), business

Abstract

Conspectus The visualization of data is indispensable in scientific research, from the early stages when human insight forms to the final step of communicating results. In computational physics, chemistry and materials science, it can be as simple as making a scatter plot or as straightforward as looking through the snapshots of atomic positions manually. However, as a result of the “big data” revolution, these conventional approaches are often inadequate. The widespread adoption of high-throughput computation for materials discovery and the associated community-wide repositories have given rise to data sets that contain an enormous number of compounds and atomic configurations. A typical data set contains thousands to millions of atomic structures, along with a diverse range of properties such as formation energies, band gaps, or bioactivities. It would thus be desirable to have a data-driven and automated framework for visualizing and analyzing such structural data sets. The key idea is to construct a low-dimensional representation of the data, which facilitates navigation, reveals underlying patterns, and helps to identify data points with unusual attributes. Such data-intensive maps, often employing machine learning methods, are appearing more and more frequently in the literature. However, to the wider community, it is not always transparent how these maps are made and how they should be interpreted. Furthermore, while these maps undoubtedly serve a decorative purpose in academic publications, it is not always apparent what extra information can be garnered from reading or making them. This Account attempts to answer such questions. We start with a concise summary of the theory of representing chemical environments, followed by the introduction of a simple yet practical conceptual approach for generating structure maps in a generic and automated manner. Such analysis and mapping is made nearly effortless by employing the newly developed software tool ASAP. To showcase the applicability to a wide variety of systems in chemistry and materials science, we provide several illustrative examples, including crystalline and amorphous materials, interfaces, and organic molecules. In these examples, the maps not only help to sift through large data sets but also reveal hidden patterns that could be easily missed using conventional analyses. The explosion in the amount of computed information in chemistry and materials science has made visualization into a science in itself. Not only have we benefited from exploiting these visualization methods in previous works, we also believe that the automated mapping of data sets will in turn stimulate further creativity and exploration, as well as ultimately feed back into future advances in the respective fields.

Published

2020