Your search keyword '"Bauer, Denis C."' showing total 4 results

1. Privacy-hardened and hallucination-resistant synthetic data generation with logic-solvers

Author

Burgess, Mark A., Hosking, Brendan, Reguant, Roc, Kaphle, Anubhav, O'Brien, Mitchell J., Sng, Letitia M. F., Jain, Yatish, and Bauer, Denis C.

Subjects

Computer Science - Artificial Intelligence, Computer Science - Cryptography and Security, Computer Science - Computers and Society, Computer Science - Machine Learning

Abstract

Machine-generated data is a valuable resource for training Artificial Intelligence algorithms, evaluating rare workflows, and sharing data under stricter data legislations. The challenge is to generate data that is accurate and private. Current statistical and deep learning methods struggle with large data volumes, are prone to hallucinating scenarios incompatible with reality, and seldom quantify privacy meaningfully. Here we introduce Genomator, a logic solving approach (SAT solving), which efficiently produces private and realistic representations of the original data. We demonstrate the method on genomic data, which arguably is the most complex and private information. Synthetic genomes hold great potential for balancing underrepresented populations in medical research and advancing global data exchange. We benchmark Genomator against state-of-the-art methodologies (Markov generation, Restricted Boltzmann Machine, Generative Adversarial Network and Conditional Restricted Boltzmann Machines), demonstrating an 84-93% accuracy improvement and 95-98% higher privacy. Genomator is also 1000-1600 times more efficient, making it the only tested method that scales to whole genomes. We show the universal trade-off between privacy and accuracy, and use Genomator's tuning capability to cater to all applications along the spectrum, from provable private representations of sensitive cohorts, to datasets with indistinguishable pharmacogenomic profiles. Demonstrating the production-scale generation of tuneable synthetic data can increase trust and pave the way into the clinic.

Published

2024

2. AskBeacon -- Performing genomic data exchange and analytics with natural language

Author

Wickramarachchi, Anuradha, Tonni, Shakila, Majumdar, Sonali, Karimi, Sarvnaz, Kõks, Sulev, Hosking, Brendan, Rambla, Jordi, Twine, Natalie A., Jain, Yatish, and Bauer, Denis C.

Subjects

Computer Science - Artificial Intelligence, Computer Science - Computers and Society, Quantitative Biology - Genomics

Abstract

Enabling clinicians and researchers to directly interact with global genomic data resources by removing technological barriers is vital for medical genomics. AskBeacon enables Large Language Models to be applied to securely shared cohorts via the GA4GH Beacon protocol. By simply "asking" Beacon, actionable insights can be gained, analyzed and made publication-ready.

Published

2024

3. A Critical Review of the Impact of Candidate Copy Number Variants on Autism Spectrum Disorders

Author

Abedini, Seyedeh Sedigheh, Akhavan, Shiva, Heng, Julian, Alizadehsani, Roohallah, Dehzangi, Iman, Bauer, Denis C., and Rokny, Hamid

Subjects

Quantitative Biology - Genomics, Quantitative Biology - Neurons and Cognition

Abstract

Autism spectrum disorder (ASD) is a heterogeneous neurodevelopmental disorder (NDD) that is caused by genetic, epigenetic, and environmental factors. Recent advances in genomic analysis have uncovered numerous candidate genes with common and/or rare mutations that increase susceptibility to ASD. In addition, there is increasing evidence that copy number variations (CNVs), single nucleotide polymorphisms (SNPs), and unusual de novo variants negatively affect neurodevelopment pathways in various ways. The overall rate of copy number variants found in patients with autism is 10%-20%, of which 3%-7% can be detected cytogenetically. Although the role of submicroscopic CNVs in ASD has been studied recently, their association with genomic loci and genes has not been properly studied. In this review, we focus on 47 ASD-associated CNV regions and their related genes. Here, we identify 1,632 protein-coding genes and long non-coding RNAs (lncRNAs) within these regions. Among them, 552 are significantly expressed in the brain. Using a list of ASD-associated genes from SFARI, we detect 17 regions containing at least one known ASD-associated protein-coding genes. Of the remaining 30 regions, we identify 24 regions containing at least one protein-coding genes with brain-enriched expression and nervous system phenotype in mouse mutant and one lncRNAs with both brain-enriched expression and upregulation in iPSC to neuron differentiation. Our analyses highlight the diversity of genetic lesions of CNV regions that contribute to ASD and provide new genetic evidence that lncRNA genes may contribute to etiology of ASD. In addition, the discovered CNVs will be a valuable resource for diagnostic facilities, therapeutic strategies, and research in terms of variation priority.

Published

2023

4. Applying data technologies to combat AMR: current status, challenges, and opportunities on the way forward

Author

Chindelevitch, Leonid, Jauneikaite, Elita, Wheeler, Nicole E., Allel, Kasim, Ansiri-Asafoakaa, Bede Yaw, Awuah, Wireko A., Bauer, Denis C., Beisken, Stephan, Fan, Kara, Grant, Gary, Graz, Michael, Khalaf, Yara, Liyanapathirana, Veranja, Montefusco-Pereira, Carlos, Mugisha, Lawrence, Naik, Atharv, Nanono, Sylvia, Nguyen, Anthony, Rawson, Timothy, Reddy, Kessendri, Ruzante, Juliana M., Schmider, Anneke, Stocker, Roman, Unruh, Leonhardt, Waruingi, Daniel, Graz, Heather, and van Dongen, Maarten

Subjects

Computer Science - Computers and Society, Computer Science - Artificial Intelligence, Computer Science - Machine Learning, Statistics - Applications, I.2.1, J.3

Abstract

Antimicrobial resistance (AMR) is a growing public health threat, estimated to cause over 10 million deaths per year and cost the global economy 100 trillion USD by 2050 under status quo projections. These losses would mainly result from an increase in the morbidity and mortality from treatment failure, AMR infections during medical procedures, and a loss of quality of life attributed to AMR. Numerous interventions have been proposed to control the development of AMR and mitigate the risks posed by its spread. This paper reviews key aspects of bacterial AMR management and control which make essential use of data technologies such as artificial intelligence, machine learning, and mathematical and statistical modelling, fields that have seen rapid developments in this century. Although data technologies have become an integral part of biomedical research, their impact on AMR management has remained modest. We outline the use of data technologies to combat AMR, detailing recent advancements in four complementary categories: surveillance, prevention, diagnosis, and treatment. We provide an overview on current AMR control approaches using data technologies within biomedical research, clinical practice, and in the "One Health" context. We discuss the potential impact and challenges wider implementation of data technologies is facing in high-income as well as in low- and middle-income countries, and recommend concrete actions needed to allow these technologies to be more readily integrated within the healthcare and public health sectors., Comment: 65 pages, 3 figures

Published

2022