Your search keyword '"Suchard, Marc A."' showing total 2,197 results

1. Variational Bayesian Phylogenetic Inference with Semi-implicit Branch Length Distributions

Author

Xie, Tianyu, Matsen IV, Frederick A., Suchard, Marc A., and Zhang, Cheng

Subjects

Statistics - Machine Learning, Computer Science - Machine Learning

Abstract

Reconstructing the evolutionary history relating a collection of molecular sequences is the main subject of modern Bayesian phylogenetic inference. However, the commonly used Markov chain Monte Carlo methods can be inefficient due to the complicated space of phylogenetic trees, especially when the number of sequences is large. An alternative approach is variational Bayesian phylogenetic inference (VBPI) which transforms the inference problem into an optimization problem. While effective, the default diagonal lognormal approximation for the branch lengths of the tree used in VBPI is often insufficient to capture the complexity of the exact posterior. In this work, we propose a more flexible family of branch length variational posteriors based on semi-implicit hierarchical distributions using graph neural networks. We show that this semi-implicit construction emits straightforward permutation equivariant distributions, and therefore can handle the non-Euclidean branch length space across different tree topologies with ease. To deal with the intractable marginal probability of semi-implicit variational distributions, we develop several alternative lower bounds for stochastic optimization. We demonstrate the effectiveness of our proposed method over baseline methods on benchmark data examples, in terms of both marginal likelihood estimation and branch length posterior approximation., Comment: 26 pages, 7 figures

Published

2024

2. Scaling Hawkes processes to one million COVID-19 cases

Author

Ko, Seyoon, Suchard, Marc A., and Holbrook, Andrew J.

Subjects

Statistics - Computation, Statistics - Applications

Abstract

Hawkes stochastic point process models have emerged as valuable statistical tools for analyzing viral contagion. The spatiotemporal Hawkes process characterizes the speeds at which viruses spread within human populations. Unfortunately, likelihood-based inference using these models requires $O(N^2)$ floating-point operations, for $N$ the number of observed cases. Recent work responds to the Hawkes likelihood's computational burden by developing efficient graphics processing unit (GPU)-based routines that enable Bayesian analysis of tens-of-thousands of observations. We build on this work and develop a high-performance computing (HPC) strategy that divides 30 Markov chains between 4 GPU nodes, each of which uses multiple GPUs to accelerate its chain's likelihood computations. We use this framework to apply two spatiotemporal Hawkes models to the analysis of one million COVID-19 cases in the United States between March 2020 and June 2023. In addition to brute-force HPC, we advocate for two simple strategies as scalable alternatives to successful approaches proposed for small data settings. First, we use known county-specific population densities to build a spatially varying triggering kernel in a manner that avoids computationally costly nearest neighbors search. Second, we use a cut-posterior inference routine that accounts for infections' spatial location uncertainty by iteratively sampling latent locations uniformly within their respective counties of occurrence, thereby avoiding full-blown latent variable inference for 1,000,000 infection locations.

Published

2024

3. Torchtree: flexible phylogenetic model development and inference using PyTorch

Author

Fourment, Mathieu, Macaulay, Matthew, Swanepoel, Christiaan J, Ji, Xiang, Suchard, Marc A, and Matsen IV, Frederick A

Subjects

Quantitative Biology - Populations and Evolution, Statistics - Computation

Abstract

Bayesian inference has predominantly relied on the Markov chain Monte Carlo (MCMC) algorithm for many years. However, MCMC is computationally laborious, especially for complex phylogenetic models of time trees. This bottleneck has led to the search for alternatives, such as variational Bayes, which can scale better to large datasets. In this paper, we introduce torchtree, a framework written in Python that allows developers to easily implement rich phylogenetic models and algorithms using a fixed tree topology. One can either use automatic differentiation, or leverage torchtree's plug-in system to compute gradients analytically for model components for which automatic differentiation is slow. We demonstrate that the torchtree variational inference framework performs similarly to BEAST in terms of speed and approximation accuracy. Furthermore, we explore the use of the forward KL divergence as an optimizing criterion for variational inference, which can handle discontinuous and non-differentiable models. Our experiments show that inference using the forward KL divergence tends to be faster per iteration compared to the evidence lower bound (ELBO) criterion, although the ELBO-based inference may converge faster in some cases. Overall, torchtree provides a flexible and efficient framework for phylogenetic model development and inference using PyTorch., Comment: 23 pages, 3 tables, and 4 figures in main text, plus supplementary materials

Published

2024

4. Comparing penalization methods for linear models on large observational health data.

Author

Fridgeirsson, Egill, Williams, Ross, Rijnbeek, Peter, Suchard, Marc, and Reps, Jenna

Subjects

calibration, discrimination, electronic health records, logistic regression, regularization, Humans, Logistic Models, Depressive Disorder, Major, Electronic Health Records, Linear Models, Databases, Factual, United States

Abstract

OBJECTIVE: This study evaluates regularization variants in logistic regression (L1, L2, ElasticNet, Adaptive L1, Adaptive ElasticNet, Broken adaptive ridge [BAR], and Iterative hard thresholding [IHT]) for discrimination and calibration performance, focusing on both internal and external validation. MATERIALS AND METHODS: We use data from 5 US claims and electronic health record databases and develop models for various outcomes in a major depressive disorder patient population. We externally validate all models in the other databases. We use a train-test split of 75%/25% and evaluate performance with discrimination and calibration. Statistical analysis for difference in performance uses Friedmans test and critical difference diagrams. RESULTS: Of the 840 models we develop, L1 and ElasticNet emerge as superior in both internal and external discrimination, with a notable AUC difference. BAR and IHT show the best internal calibration, without a clear external calibration leader. ElasticNet typically has larger model sizes than L1. Methods like IHT and BAR, while slightly less discriminative, significantly reduce model complexity. CONCLUSION: L1 and ElasticNet offer the best discriminative performance in logistic regression for healthcare predictions, maintaining robustness across validations. For simpler, more interpretable models, L0-based methods (IHT and BAR) are advantageous, providing greater parsimony and calibration with fewer features. This study aids in selecting suitable regularization techniques for healthcare prediction models, balancing performance, complexity, and interpretability.

Published

2024

5. Evaluating the impact of instrumental variables in propensity score models using synthetic and negative control experiments

Author

Tian, Yuxi, Pratt, Nicole, Hester, Laura L, Hripcsak, George, Schuemie, Martijn J, and Suchard, Marc A

Subjects

Statistics - Methodology, Statistics - Applications

Abstract

In pharmacoepidemiology research, instrumental variables (IVs) are variables that strongly predict treatment but have no causal effect on the outcome of interest except through the treatment. There remain concerns about the inclusion of IVs in propensity score (PS) models amplifying estimation bias and reducing precision. Some PS modeling approaches attempt to address the potential effects of IVs, including selecting only covariates for the PS model that are strongly associated to the outcome of interest, thus screening out IVs. We conduct a study utilizing simulations and negative control experiments to evaluate the effect of IVs on PS model performance and to uncover best PS practices for real-world studies. We find that simulated IVs have a weak effect on bias and precision in both simulations and negative control experiments based on real-world data. In simulation experiments, PS methods that utilize outcome data, including the high-dimensional propensity score, produce the least estimation bias. However, in real-world settings underlying causal structures are unknown, and negative control experiments can illustrate a PS model's ability to minimize systematic bias. We find that large-scale, regularized regression based PS models in this case provide the most centered negative control distributions, suggesting superior performance in real-world scenarios.

Published

2024

6. Farmed fur animals harbour viruses with zoonotic spillover potential

Author

Zhao, Jin, Wan, Wenbo, Yu, Kang, Lemey, Philippe, Pettersson, John H.-O., Bi, Yuhai, Lu, Meng, Li, Xinxin, Chen, Zhuohang, Zheng, Mengdi, Yan, Ge, Dai, JianJun, Li, Yuxing, Haerheng, Ayidana, He, Na, Tu, Changchun, Suchard, Marc A., Holmes, Edward C., He, Wan-Ting, and Su, Shuo

Published

2024

7. On the importance of assessing topological convergence in Bayesian phylogenetic inference

Author

Brusselmans, Marius, Carvalho, Luiz Max, Hong, Samuel L., Gao, Jiansi, Matsen IV, Frederick A., Rambaut, Andrew, Lemey, Philippe, Suchard, Marc A., Dudas, Gytis, and Baele, Guy

Subjects

Quantitative Biology - Populations and Evolution, Quantitative Biology - Genomics, Quantitative Biology - Quantitative Methods

Abstract

Modern phylogenetics research is often performed within a Bayesian framework, using sampling algorithms such as Markov chain Monte Carlo (MCMC) to approximate the posterior distribution. These algorithms require careful evaluation of the quality of the generated samples. Within the field of phylogenetics, one frequently adopted diagnostic approach is to evaluate the effective sample size (ESS) and to investigate trace graphs of the sampled parameters. A major limitation of these approaches is that they are developed for continuous parameters and therefore incompatible with a crucial parameter in these inferences: the tree topology. Several recent advancements have aimed at extending these diagnostics to topological space. In this reflection paper, we present two case studies - one on Ebola virus and one on HIV - illustrating how these topological diagnostics can contain information not found in standard diagnostics, and how decisions regarding which of these diagnostics to compute can impact inferences regarding MCMC convergence and mixing. Our results show the importance of running multiple replicate analyses and of carefully assessing topological convergence using the output of these replicate analyses. To this end, we illustrate different ways of assessing and visualizing the topological convergence of these replicates. Given the major importance of detecting convergence and mixing issues in Bayesian phylogenetic analyses, the lack of a unified approach to this problem warrants further action, especially now that additional tools are becoming available to researchers.

Published

2024

8. The genomic evolutionary dynamics and global circulation patterns of respiratory syncytial virus.

Author

Langedijk, Annefleur, Vrancken, Bram, Lebbink, Robert, Wilkins, Deidre, Kelly, Elizabeth, Baraldi, Eugenio, Mascareñas de Los Santos, Abiel, Danilenko, Daria, Choi, Eun, Palomino, María, Chi, Hsin, Keller, Christian, Cohen, Robert, Papenburg, Jesse, Pernica, Jeffrey, Greenough, Anne, Richmond, Peter, Martinón-Torres, Federico, Heikkinen, Terho, Stein, Renato, Hosoya, Mitsuaki, Nunes, Marta, Verwey, Charl, Evers, Anouk, Kragten-Tabatabaie, Leyla, Suchard, Marc, Kosakovsky Pond, Sergei, Poletto, Chiara, Colizza, Vittoria, Lemey, Philippe, and Bont, Louis

Subjects

Infant, Child, Humans, Child, Preschool, Respiratory Syncytial Virus Infections, Phylogeny, Respiratory Syncytial Virus, Human, Genomics, Respiratory Tract Infections

Abstract

Respiratory syncytial virus (RSV) is a leading cause of acute lower respiratory tract infection in young children and the second leading cause of infant death worldwide. While global circulation has been extensively studied for respiratory viruses such as seasonal influenza, and more recently also in great detail for SARS-CoV-2, a lack of global multi-annual sampling of complete RSV genomes limits our understanding of RSV molecular epidemiology. Here, we capitalise on the genomic surveillance by the INFORM-RSV study and apply phylodynamic approaches to uncover how selection and neutral epidemiological processes shape RSV diversity. Using complete viral genome sequences, we show similar patterns of site-specific diversifying selection among RSVA and RSVB and recover the imprint of non-neutral epidemic processes on their genealogies. Using a phylogeographic approach, we provide evidence for air travel governing the global patterns of RSVA and RSVB spread, which results in a considerable degree of phylogenetic mixing across countries. Our findings highlight the potential of systematic global RSV genomic surveillance for transforming our understanding of global RSV spread.

Published

2024

9. Scalable gradients enable Hamiltonian Monte Carlo sampling for phylodynamic inference under episodic birth-death-sampling models.

Author

Shao, Yucai, Magee, Andrew, Suchard, Marc, and Vasylyeva, Tetyana

Subjects

Humans, Influenza A Virus, H3N2 Subtype, Algorithms, Influenza, Human, Epidemics, Hemorrhagic Fever, Ebola, Monte Carlo Method

Abstract

Birth-death models play a key role in phylodynamic analysis for their interpretation in terms of key epidemiological parameters. In particular, models with piecewise-constant rates varying at different epochs in time, to which we refer as episodic birth-death-sampling (EBDS) models, are valuable for their reflection of changing transmission dynamics over time. A challenge, however, that persists with current time-varying model inference procedures is their lack of computational efficiency. This limitation hinders the full utilization of these models in large-scale phylodynamic analyses, especially when dealing with high-dimensional parameter vectors that exhibit strong correlations. We present here a linear-time algorithm to compute the gradient of the birth-death model sampling density with respect to all time-varying parameters, and we implement this algorithm within a gradient-based Hamiltonian Monte Carlo (HMC) sampler to alleviate the computational burden of conducting inference under a wide variety of structures of, as well as priors for, EBDS processes. We assess this approach using three different real world data examples, including the HIV epidemic in Odesa, Ukraine, seasonal influenza A/H3N2 virus dynamics in New York state, America, and Ebola outbreak in West Africa. HMC sampling exhibits a substantial efficiency boost, delivering a 10- to 200-fold increase in minimum effective sample size per unit-time, in comparison to a Metropolis-Hastings-based approach. Additionally, we show the robustness of our implementation in both allowing for flexible prior choices and in modeling the transmission dynamics of various pathogens by accurately capturing the changing trend of viral effective reproductive number.

Published

2024

10. More Quantum Speedups for Multiproposal MCMC

Author

Lin, Chin-Yi, Chen, Kuo-Chin, Lemey, Philippe, Suchard, Marc A., Holbrook, Andrew J., and Hsieh, Min-Hsiu

Subjects

Quantum Physics

Abstract

Multiproposal Markov chain Monte Carlo (MCMC) algorithms choose from multiple proposals at each iteration in order to sample from challenging target distributions more efficiently. Recent work demonstrates the possibility of quadratic quantum speedups for one such multiproposal MCMC algorithm. Using $P$ proposals, this quantum parallel MCMC QPMCMC algorithm requires only $\mathcal{O}(\sqrt{P})$ target evaluations at each step. Here, we present a fast new quantum multiproposal MCMC strategy, QPMCMC2, that only requires $\mathcal{O}(1)$ target evaluations and $\mathcal{O}(\log P)$ qubits. Unlike its slower predecessor, the QPMCMC2 Markov kernel (1) maintains detailed balance exactly and (2) is fully explicit for a large class of graphical models. We demonstrate this flexibility by applying QPMCMC2 to novel Ising-type models built on bacterial evolutionary networks and obtain significant speedups for Bayesian ancestral trait reconstruction for 248 observed salmonella bacteria.

Published

2023

11. Efficient GPU-accelerated fitting of observational health-scaled stratified and time-varying Cox models

Author

Yang, Jianxiao, Schuemie, Martijn J., and Suchard, Marc A.

Subjects

Statistics - Computation

Abstract

The Cox proportional hazards model stands as a widely-used semi-parametric approach for survival analysis in medical research and many other fields. Numerous extensions of the Cox model have further expanded its versatility. Statistical computing challenges arise, however, when applying many of these extensions with the increasing complexity and volume of modern observational health datasets. To address these challenges, we demonstrate how to employ massive parallelization through graphics processing units (GPU) to enhance the scalability of the stratified Cox model, the Cox model with time-varying covariates, and the Cox model with time-varying coefficients. First we establish how the Cox model with time-varying coefficients can be transformed into the Cox model with time-varying covariates when using discrete time-to-event data. We then demonstrate how to recast both of these into a stratified Cox model and identify their shared computational bottleneck that results when evaluating the now segmented partial likelihood and its gradient with respect to regression coefficients at scale. These computations mirror a highly transformed segmented scan operation. While this bottleneck is not an immediately obvious target for multi-core parallelization, we convert it into an un-segmented operation to leverage the efficient many-core parallel scan algorithm. Our massively parallel implementation significantly accelerates model fitting on large-scale and high-dimensional Cox models with stratification or time-varying effect, delivering an order of magnitude speedup over traditional central processing unit-based implementations.

Published

2023

12. Many-core algorithms for high-dimensional gradients on phylogenetic trees.

Author

Gangavarapu, Karthik, Ji, Xiang, Baele, Guy, Fourment, Mathieu, Lemey, Philippe, Matsen, Frederick, and Suchard, Marc

Subjects

Phylogeny, Software, Bayes Theorem, Algorithms, Codon, Nucleotides

Abstract

MOTIVATION: Advancements in high-throughput genomic sequencing are delivering genomic pathogen data at an unprecedented rate, positioning statistical phylogenetics as a critical tool to monitor infectious diseases globally. This rapid growth spurs the need for efficient inference techniques, such as Hamiltonian Monte Carlo (HMC) in a Bayesian framework, to estimate parameters of these phylogenetic models where the dimensions of the parameters increase with the number of sequences N. HMC requires repeated calculation of the gradient of the data log-likelihood with respect to (wrt) all branch-length-specific (BLS) parameters that traditionally takes O(N2) operations using the standard pruning algorithm. A recent study proposes an approach to calculate this gradient in O(N), enabling researchers to take advantage of gradient-based samplers such as HMC. The CPU implementation of this approach makes the calculation of the gradient computationally tractable for nucleotide-based models but falls short in performance for larger state-space size models, such as Markov-modulated and codon models. Here, we describe novel massively parallel algorithms to calculate the gradient of the log-likelihood wrt all BLS parameters that take advantage of graphics processing units (GPUs) and result in many fold higher speedups over previous CPU implementations. RESULTS: We benchmark these GPU algorithms on three computing systems using three evolutionary inference examples exploring complete genomes from 997 dengue viruses, 62 carnivore mitochondria and 49 yeasts, and observe a >128-fold speedup over the CPU implementation for codon-based models and >8-fold speedup for nucleotide-based models. As a practical demonstration, we also estimate the timing of the first introduction of West Nile virus into the continental Unites States under a codon model with a relaxed molecular clock from 104 full viral genomes, an inference task previously intractable. AVAILABILITY AND IMPLEMENTATION: We provide an implementation of our GPU algorithms in BEAGLE v4.0.0 (https://github.com/beagle-dev/beagle-lib), an open-source library for statistical phylogenetics that enables parallel calculations on multi-core CPUs and GPUs. We employ a BEAGLE-implementation using the Bayesian phylogenetics framework BEAST (https://github.com/beast-dev/beast-mcmc).

Published

2024

13. Evaluating the impact of alternative phenotype definitions on incidence rates across a global data network.

Author

Makadia, Rupa, Shoaibi, Azza, Rao, Gowtham, Ostropolets, Anna, Rijnbeek, Peter, Voss, Erica, Duarte-Salles, Talita, Ramírez-Anguita, Juan, Mayer, Miguel, Maljković, Filip, Denaxas, Spiros, Nyberg, Fredrik, Papez, Vaclav, Sena, Anthony, Alshammari, Thamir, Lai, Lana, Haynes, Kevin, Hripcsak, George, Ryan, Patrick, and Suchard, Marc

Subjects

algorithms, electronic health record, incidence study, phenotype

Abstract

OBJECTIVE: Developing accurate phenotype definitions is critical in obtaining reliable and reproducible background rates in safety research. This study aims to illustrate the differences in background incidence rates by comparing definitions for a given outcome. MATERIALS AND METHODS: We used 16 data sources to systematically generate and evaluate outcomes for 13 adverse events and their overall background rates. We examined the effect of different modifications (inpatient setting, standardization of code set, and code set changes) to the computable phenotype on background incidence rates. RESULTS: Rate ratios (RRs) of the incidence rates from each computable phenotype definition varied across outcomes, with inpatient restriction showing the highest variation from 1 to 11.93. Standardization of code set RRs ranges from 1 to 1.64, and code set changes range from 1 to 2.52. DISCUSSION: The modification that has the highest impact is requiring inpatient place of service, leading to at least a 2-fold higher incidence rate in the base definition. Standardization showed almost no change when using source code variations. The strength of the effect in the inpatient restriction is highly dependent on the outcome. Changing definitions from broad to narrow showed the most variability by age/gender/database across phenotypes and less than a 2-fold increase in rate compared to the base definition. CONCLUSION: Characterization of outcomes across a network of databases yields insights into sensitivity and specificity trade-offs when definitions are altered. Outcomes should be thoroughly evaluated prior to use for background rates for their plausibility for use across a global network.

Published

2023

14. On the surprising effectiveness of a simple matrix exponential derivative approximation, with application to global SARS-CoV-2

Author

Didier, Gustavo, Glatt-Holtz, Nathan E., Holbrook, Andrew J., Magee, Andrew F., and Suchard, Marc A.

Subjects

Statistics - Computation, Mathematics - Probability

Abstract

The continuous-time Markov chain (CTMC) is the mathematical workhorse of evolutionary biology. Learning CTMC model parameters using modern, gradient-based methods requires the derivative of the matrix exponential evaluated at the CTMC's infinitesimal generator (rate) matrix. Motivated by the derivative's extreme computational complexity as a function of state space cardinality, recent work demonstrates the surprising effectiveness of a naive, first-order approximation for a host of problems in computational biology. In response to this empirical success, we obtain rigorous deterministic and probabilistic bounds for the error accrued by the naive approximation and establish a "blessing of dimensionality" result that is universal for a large class of rate matrices with random entries. Finally, we apply the first-order approximation within surrogate-trajectory Hamiltonian Monte Carlo for the analysis of the early spread of SARS-CoV-2 across 44 geographic regions that comprise a state space of unprecedented dimensionality for unstructured (flexible) CTMC models within evolutionary biology., Comment: To appear in the Proceedings of the National Academy of Sciences

Published

2023

15. APOBEC3 deaminase editing in mpox virus as evidence for sustained human transmission since at least 2016.

Author

OToole, Áine, Neher, Richard, Ndodo, Nnaemeka, Borges, Vitor, Gannon, Ben, Gomes, João, Groves, Natalie, King, David, Maloney, Daniel, Lemey, Philippe, Lewandowski, Kuiama, Loman, Nicholas, Myers, Richard, Omah, Ifeanyi, Worobey, Michael, Chand, Meera, Ihekweazu, Chikwe, Ulaeto, David, Adetifa, Ifedayo, Rambaut, Andrew, and Suchard, Marc

Subjects

Animals, Humans, Africa, Central, Africa, Western, APOBEC Deaminases, Disease Outbreaks, Mpox (monkeypox), Monkeypox virus, Mutation, Phylogeny, Viral Zoonoses, RNA Editing

Abstract

Historically, mpox has been characterized as an endemic zoonotic disease that transmits through contact with the reservoir rodent host in West and Central Africa. However, in May 2022, human cases of mpox were detected spreading internationally beyond countries with known endemic reservoirs. When the first cases from 2022 were sequenced, they shared 42 nucleotide differences from the closest mpox virus (MPXV) previously sampled. Nearly all these mutations are characteristic of the action of APOBEC3 deaminases, host enzymes with antiviral function. Assuming APOBEC3 editing is characteristic of human MPXV infection, we developed a dual-process phylogenetic molecular clock that-inferring a rate of ~6 APOBEC3 mutations per year-estimates that MPXV has been circulating in humans since 2016. These observations of sustained MPXV transmission present a fundamental shift to the perceived paradigm of MPXV epidemiology as a zoonosis and highlight the need for revising public health messaging around MPXV as well as outbreak management and control.

Published

2023

16. Shrinkage-based Random Local Clocks with Scalable Inference.

Author

Fisher, Alexander, Ji, Xiang, Nishimura, Akihiko, Baele, Guy, Lemey, Philippe, and Suchard, Marc

Subjects

Bayesian phylogenetics, Hamiltonian Monte Carlo, divergence time estimation, random local clock, shrinkage clock, Animals, Phylogeny, Bayes Theorem, Evolution, Molecular, Mammals, Time Factors, Models, Genetic

Abstract

Molecular clock models undergird modern methods of divergence-time estimation. Local clock models propose that the rate of molecular evolution is constant within phylogenetic subtrees. Current local clock inference procedures exhibit one or more weaknesses, namely they achieve limited scalability to trees with large numbers of taxa, impose model misspecification, or require a priori knowledge of the existence and location of clocks. To overcome these challenges, we present an autocorrelated, Bayesian model of heritable clock rate evolution that leverages heavy-tailed priors with mean zero to shrink increments of change between branch-specific clocks. We further develop an efficient Hamiltonian Monte Carlo sampler that exploits closed form gradient computations to scale our model to large trees. Inference under our shrinkage clock exhibits a speed-up compared to the popular random local clock when estimating branch-specific clock rates on a variety of simulated datasets. This speed-up increases with the size of the problem. We further show our shrinkage clock recovers known local clocks within a rodent and mammalian phylogeny. Finally, in a problem that once appeared computationally impractical, we investigate the heritable clock structure of various surface glycoproteins of influenza A virus in the absence of prior knowledge about clock placement. We implement our shrinkage clock and make it publicly available in the BEAST software package.

Published

2023

17. Scalable Bayesian Divergence Time Estimation With Ratio Transformations.

Author

Ji, Xiang, Fisher, Alexander, Su, Shuo, Thorne, Jeffrey, Potter, Barney, Lemey, Philippe, Baele, Guy, and Suchard, Marc

Subjects

Bayesian inference, Hamiltonian Monte Carlo, divergence time estimation, effective sample size, pathogens, phylogenetics, ratio transformation, Phylogeny, Bayes Theorem, Algorithms, Time Factors, Monte Carlo Method

Abstract

Divergence time estimation is crucial to provide temporal signals for dating biologically important events from species divergence to viral transmissions in space and time. With the advent of high-throughput sequencing, recent Bayesian phylogenetic studies have analyzed hundreds to thousands of sequences. Such large-scale analyses challenge divergence time reconstruction by requiring inference on highly correlated internal node heights that often become computationally infeasible. To overcome this limitation, we explore a ratio transformation that maps the original $N-1$ internal node heights into a space of one height parameter and $N-2$ ratio parameters. To make the analyses scalable, we develop a collection of linear-time algorithms to compute the gradient and Jacobian-associated terms of the log-likelihood with respect to these ratios. We then apply Hamiltonian Monte Carlo sampling with the ratio transform in a Bayesian framework to learn the divergence times in 4 pathogenic viruses (West Nile virus, rabies virus, Lassa virus, and Ebola virus) and the coralline red algae. Our method both resolves a mixing issue in the West Nile virus example and improves inference efficiency by at least 5-fold for the Lassa and rabies virus examples as well as for the algae example. Our method now also makes it computationally feasible to incorporate mixed-effects molecular clock models for the Ebola virus example, confirms the findings from the original study, and reveals clearer multimodal distributions of the divergence times of some clades of interest.

Published

2023

18. Padé approximant meets federated learning: A nearly lossless, one-shot algorithm for evidence synthesis in distributed research networks with rare outcomes.

Author

Wu, Qiong, Schuemie, Martijn, Suchard, Marc, Ryan, Patrick, Hripcsak, George, Rohde, Charles, and Chen, Yong

Subjects

Distributed algorithm, Distributed research networks, Evidence synthesis, Padé approximants, Rare outcomes, Algorithms, Computer Simulation, Meta-Analysis as Topic, Machine Learning

Abstract

OBJECTIVE: We developed and evaluated a novel one-shot distributed algorithm for evidence synthesis in distributed research networks with rare outcomes. MATERIALS AND METHODS: Fed-Padé, motivated by a classic mathematical tool, Padé approximants, reconstructs the multi-site data likelihood via Padé approximant whose key parameters can be computed distributively. Thanks to the simplicity of [2,2] Padé approximant, Fed-Padé requests an extremely simple task and low communication cost for data partners. Specifically, each data partner only needs to compute and share the log-likelihood and its first 4 gradients evaluated at an initial estimator. We evaluated the performance of our algorithm with extensive simulation studies and four observational healthcare databases. RESULTS: Our simulation studies revealed that a [2,2]-Padé approximant can well reconstruct the multi-site likelihood so that Fed-Padé produces nearly identical estimates to the pooled analysis. Across all simulation scenarios considered, the median of relative bias and rate of instability of our Fed-Padé are both

Published

2023

19. Quantitative bias analysis for outcome phenotype error correction in comparative effect estimation: an empirical and synthetic evaluation

Author

Weaver, James, Ryan, Patrick B., Strauss, Victoria Y., Suchard, Marc A., Swerdel, Joel, and Prieto-Alhambra, Daniel

Subjects

Statistics - Applications, Statistics - Methodology

Abstract

Outcome phenotype measurement error is rarely corrected in comparative effect estimation studies in observational pharmacoepidemiology. Quantitative bias analysis (QBA) is a misclassification correction method that algebraically adjusts person counts in exposure-outcome contingency tables to reflect the magnitude of misclassification. The extent QBA minimizes bias is unclear because few systematic evaluations have been reported. We empirically evaluated QBA impact on odds ratios (OR) in several comparative effect estimation scenarios. We estimated non-differential and differential phenotype errors with internal validation studies using a probabilistic reference. Further, we synthesized an analytic space defined by outcome incidence, uncorrected ORs, and phenotype errors to identify which combinations produce invalid results indicative of input errors. We evaluated impact with relative bias [(OR-ORQBA)]/OR*100%]. Results were considered invalid if any contingency table cell was corrected to a negative number. Empirical bias correction was greatest in lower incidence scenarios where uncorrected ORs were larger. Similarly, synthetic bias correction was greater in lower incidence settings with larger uncorrected estimates. The invalid proportion of synthetic scenarios increased as uncorrected estimates increased. Results were invalid in common, low incidence scenarios indicating problematic inputs. This demonstrates the importance of accurately and precisely estimating phenotype errors before implementing QBA in comparative effect estimation studies., Comment: 31 pages, 8 tables, 4 figures including appendix. Interactive web application: https://data.ohdsi.org/QbaEvaluation/

Published

2023

20. Bayesian Safety Surveillance with Adaptive Bias Correction

Author

Bu, Fan, Schuemie, Martijn J., Nishimura, Akihiko, Smith, Louisa H., Kostka, Kristin, Falconer, Thomas, McLeggon, Jody-Ann, Ryan, Patrick B., Hripcsak, George, and Suchard, Marc A.

Subjects

Statistics - Methodology, Statistics - Applications

Abstract

Post-market safety surveillance is an integral part of mass vaccination programs. Typically relying on sequential analysis of real-world health data as they accrue, safety surveillance is challenged by the difficulty of sequential multiple testing and by biases induced by residual confounding. The current standard approach based on the maximized sequential probability ratio test (MaxSPRT) fails to satisfactorily address these practical challenges and it remains a rigid framework that requires pre-specification of the surveillance schedule. We develop an alternative Bayesian surveillance procedure that addresses both challenges using a more flexible framework. We adopt a joint statistical modeling approach to sequentially estimate the effect of vaccine exposure on the adverse event of interest and correct for estimation bias by simultaneously analyzing a large set of negative control outcomes through a Bayesian hierarchical model. We then compute a posterior probability of the alternative hypothesis via Markov chain Monte Carlo sampling and use it for sequential detection of safety signals. Through an empirical evaluation using six US observational healthcare databases covering more than 360 million patients, we benchmark the proposed procedure against MaxSPRT on testing errors and estimation accuracy, under two epidemiological designs, the historical comparator and the self-controlled case series. We demonstrate that our procedure substantially reduces Type 1 error rates, maintains high statistical power, delivers fast signal detection, and provides considerably more accurate estimation. As an effort to promote open science, we present all empirical results in an R ShinyApp and provide full implementation of our method in the R package EvidenceSynthesis.

Published

2023

21. Random-effects substitution models for phylogenetics via scalable gradient approximations

Author

Magee, Andrew F., Holbrook, Andrew J., Pekar, Jonathan E., Caviedes-Solis, Itzue W., Matsen IV, Fredrick A., Baele, Guy, Wertheim, Joel O., Ji, Xiang, Lemey, Philippe, and Suchard, Marc A.

Subjects

Quantitative Biology - Populations and Evolution, Statistics - Computation

Abstract

Phylogenetic and discrete-trait evolutionary inference depend heavily on an appropriate characterization of the underlying character substitution process. In this paper, we present random-effects substitution models that extend common continuous-time Markov chain models into a richer class of processes capable of capturing a wider variety of substitution dynamics. As these random-effects substitution models often require many more parameters than their usual counterparts, inference can be both statistically and computationally challenging. Thus, we also propose an efficient approach to compute an approximation to the gradient of the data likelihood with respect to all unknown substitution model parameters. We demonstrate that this approximate gradient enables scaling of sampling-based inference, namely Bayesian inference via Hamiltonian Monte Carlo, under random-effects substitution models across large trees and state-spaces. Applied to a dataset of 583 SARS-CoV-2 sequences, an HKY model with random-effects shows strong signals of nonreversibility in the substitution process, and posterior predictive model checks clearly show that it is a more adequate model than a reversible model. When analyzing the pattern of phylogeographic spread of 1441 influenza A virus (H3N2) sequences between 14 regions, a random-effects phylogeographic substitution model infers that air travel volume adequately predicts almost all dispersal rates. A random-effects state-dependent substitution model reveals no evidence for an effect of arboreality on the swimming mode in the tree frog subfamily Hylinae. Simulations reveal that random-effects substitution models can accommodate both negligible and radical departures from the underlying base substitution model. We show that our gradient-based inference approach is over an order of magnitude more time efficient than conventional approaches.

Published

2023

22. Many-core algorithms for high-dimensional gradients on phylogenetic trees

Author

Gangavarapu, Karthik, Ji, Xiang, Baele, Guy, Fourment, Mathieu, Lemey, Philippe, Matsen IV, Frederick A., and Suchard, Marc A.

Subjects

Statistics - Computation, Quantitative Biology - Populations and Evolution

Abstract

The rapid growth in genomic pathogen data spurs the need for efficient inference techniques, such as Hamiltonian Monte Carlo (HMC) in a Bayesian framework, to estimate parameters of these phylogenetic models where the dimensions of the parameters increase with the number of sequences $N$. HMC requires repeated calculation of the gradient of the data log-likelihood with respect to (wrt) all branch-length-specific (BLS) parameters that traditionally takes $\mathcal{O}(N^2)$ operations using the standard pruning algorithm. A recent study proposes an approach to calculate this gradient in $\mathcal{O}(N)$, enabling researchers to take advantage of gradient-based samplers such as HMC. The CPU implementation of this approach makes the calculation of the gradient computationally tractable for nucleotide-based models but falls short in performance for larger state-space size models, such as codon models. Here, we describe novel massively parallel algorithms to calculate the gradient of the log-likelihood wrt all BLS parameters that take advantage of graphics processing units (GPUs) and result in many fold higher speedups over previous CPU implementations. We benchmark these GPU algorithms on three computing systems using three evolutionary inference examples: carnivores, dengue and yeast, and observe a greater than 128-fold speedup over the CPU implementation for codon-based models and greater than 8-fold speedup for nucleotide-based models. As a practical demonstration, we also estimate the timing of the first introduction of West Nile virus into the continental Unites States under a codon model with a relaxed molecular clock from 104 full viral genomes, an inference task previously intractable. We provide an implementation of our GPU algorithms in BEAGLE v4.0.0, an open source library for statistical phylogenetics that enables parallel calculations on multi-core CPUs and GPUs.

Published

2023

23. Accelerated evolution of SARS-CoV-2 in free-ranging white-tailed deer.

Author

McBride, Dillon, Garushyants, Sofya, Franks, John, Magee, Andrew, Overend, Steven, Huey, Devra, Williams, Amanda, Faith, Seth, Kandeil, Ahmed, Trifkovic, Sanja, Miller, Lance, Jeevan, Trushar, Patel, Anami, Nolting, Jacqueline, Tonkovich, Michael, Genders, J, Montoney, Andrew, Kasnyik, Kevin, Linder, Timothy, Bevins, Sarah, Lenoch, Julianna, Chandler, Jeffrey, DeLiberto, Thomas, Koonin, Eugene, Suchard, Marc, Lemey, Philippe, Webby, Richard, Nelson, Martha, and Bowman, Andrew

Subjects

Animals, Humans, SARS-CoV-2, COVID-19, Bayes Theorem, Deer, Pandemics, Phylogeny

Abstract

The zoonotic origin of the COVID-19 pandemic virus highlights the need to fill the vast gaps in our knowledge of SARS-CoV-2 ecology and evolution in non-human hosts. Here, we detected that SARS-CoV-2 was introduced from humans into white-tailed deer more than 30 times in Ohio, USA during November 2021-March 2022. Subsequently, deer-to-deer transmission persisted for 2-8 months, disseminating across hundreds of kilometers. Newly developed Bayesian phylogenetic methods quantified how SARS-CoV-2 evolution is not only three-times faster in white-tailed deer compared to the rate observed in humans but also driven by different mutational biases and selection pressures. The long-term effect of this accelerated evolutionary rate remains to be seen as no critical phenotypic changes were observed in our animal models using white-tailed deer origin viruses. Still, SARS-CoV-2 has transmitted in white-tailed deer populations for a relatively short duration, and the risk of future changes may have serious consequences for humans and livestock.

Published

2023

24. Serially Combining Epidemiological Designs Does Not Improve Overall Signal Detection in Vaccine Safety Surveillance.

Author

Arshad, Faaizah, Schuemie, Martijn, Bu, Fan, Minty, Evan, Alshammari, Thamir, Lai, Lana, Duarte-Salles, Talita, Fortin, Stephen, Nyberg, Fredrik, Ryan, Patrick, Hripcsak, George, Prieto-Alhambra, Daniel, and Suchard, Marc

Subjects

Humans, Vaccines, Sensitivity and Specificity, Research Design, Databases, Factual, Electronic Health Records

Abstract

INTRODUCTION: Vaccine safety surveillance commonly includes a serial testing approach with a sensitive method for signal generation and specific method for signal validation. The extent to which serial testing in real-world studies improves or hinders overall performance in terms of sensitivity and specificity remains unknown. METHODS: We assessed the overall performance of serial testing using three administrative claims and one electronic health record database. We compared type I and II errors before and after empirical calibration for historical comparator, self-controlled case series (SCCS), and the serial combination of those designs against six vaccine exposure groups with 93 negative control and 279 imputed positive control outcomes. RESULTS: The historical comparator design mostly had fewer type II errors than SCCS. SCCS had fewer type I errors than the historical comparator. Before empirical calibration, the serial combination increased specificity and decreased sensitivity. Type II errors mostly exceeded 50%. After empirical calibration, type I errors returned to nominal; sensitivity was lowest when the methods were combined. CONCLUSION: While serial combination produced fewer false-positive signals compared with the most specific method, it generated more false-negative signals compared with the most sensitive method. Using a historical comparator design followed by an SCCS analysis yielded decreased sensitivity in evaluating safety signals relative to a one-stage SCCS approach. While the current use of serial testing in vaccine surveillance may provide a practical paradigm for signal identification and triage, single epidemiological designs should be explored as valuable approaches to detecting signals.

Published

2023

25. Accelerating Bayesian inference of dependency between mixed-type biological traits.

Author

Zhang, Zhenyu, Nishimura, Akihiko, Trovão, Nídia, Cherry, Joshua, Holbrook, Andrew, Ji, Xiang, Lemey, Philippe, and Suchard, Marc

Subjects

Bayes Theorem, Influenza A Virus, H1N1 Subtype, Phylogeny, Flowers, Glycosylation

Abstract

Inferring dependencies between mixed-type biological traits while accounting for evolutionary relationships between specimens is of great scientific interest yet remains infeasible when trait and specimen counts grow large. The state-of-the-art approach uses a phylogenetic multivariate probit model to accommodate binary and continuous traits via a latent variable framework, and utilizes an efficient bouncy particle sampler (BPS) to tackle the computational bottleneck-integrating many latent variables from a high-dimensional truncated normal distribution. This approach breaks down as the number of specimens grows and fails to reliably characterize conditional dependencies between traits. Here, we propose an inference pipeline for phylogenetic probit models that greatly outperforms BPS. The novelty lies in 1) a combination of the recent Zigzag Hamiltonian Monte Carlo (Zigzag-HMC) with linear-time gradient evaluations and 2) a joint sampling scheme for highly correlated latent variables and correlation matrix elements. In an application exploring HIV-1 evolution from 535 viruses, the inference requires joint sampling from an 11,235-dimensional truncated normal and a 24-dimensional covariance matrix. Our method yields a 5-fold speedup compared to BPS and makes it possible to learn partial correlations between candidate viral mutations and virulence. Computational speedup now enables us to tackle even larger problems: we study the evolution of influenza H1N1 glycosylations on around 900 viruses. For broader applicability, we extend the phylogenetic probit model to incorporate categorical traits, and demonstrate its use to study Aquilegia flower and pollinator co-evolution.

Published

2023

26. Genomic assessment of invasion dynamics of SARS-CoV-2 Omicron BA.1.

Author

Tsui, Joseph, McCrone, John, Lambert, Ben, Bajaj, Sumali, Inward, Rhys, Bosetti, Paolo, Pena, Rosario, Tegally, Houriiyah, Hill, Verity, Zarebski, Alexander, Peacock, Thomas, Liu, Luyang, Wu, Neo, Davis, Megan, Bogoch, Isaac, Khan, Kamran, Kall, Meaghan, Abdul Aziz, Nurin, Colquhoun, Rachel, OToole, Áine, Jackson, Ben, Dasgupta, Abhishek, Wilkinson, Eduan, de Oliveira, Tulio, Connor, Thomas, Loman, Nicholas, Colizza, Vittoria, Fraser, Christophe, Volz, Erik, Ji, Xiang, Gutierrez, Bernardo, Chand, Meera, Dellicour, Simon, Cauchemez, Simon, Raghwani, Jayna, Suchard, Marc, Lemey, Philippe, Rambaut, Andrew, Pybus, Oliver, and Kraemer, Moritz

Subjects

Humans, Africa, Southern, COVID-19, Genomics, SARS-CoV-2, Phylogeny

Abstract

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) variants of concern (VOCs) now arise in the context of heterogeneous human connectivity and population immunity. Through a large-scale phylodynamic analysis of 115,622 Omicron BA.1 genomes, we identified >6,000 introductions of the antigenically distinct VOC into England and analyzed their local transmission and dispersal history. We find that six of the eight largest English Omicron lineages were already transmitting when Omicron was first reported in southern Africa (22 November 2021). Multiple datasets show that importation of Omicron continued despite subsequent restrictions on travel from southern Africa as a result of export from well-connected secondary locations. Initiation and dispersal of Omicron transmission lineages in England was a two-stage process that can be explained by models of the countrys human geography and hierarchical travel network. Our results enable a comparison of the processes that drive the invasion of Omicron and other VOCs across multiple spatial scales.

Published

2023

27. Persistence on Novel Cardioprotective Antihyperglycemic Therapies in the United States.

Author

Nargesi, Arash, Clark, Callahan, Aminorroaya, Arya, Chen, Lian, Liu, Mengni, Reddy, Abraham, Amodeo, Samuel, Oikonomou, Evangelos, McGuire, Darren, Lin, Zhenqiu, Inzucchi, Silvio, Khera, Rohan, and Suchard, Marc

Subjects

Aged, Humans, United States, Hypoglycemic Agents, Diabetes Mellitus, Type 2, Sodium-Glucose Transporter 2 Inhibitors, Glucagon-Like Peptide-1 Receptor, Medicare

Abstract

Selected glucagon-like peptide-1 receptor agonists (GLP-1RAs) and sodium-glucose cotransporter-2 inhibitors (SGLT-2is) have cardioprotective effects in patients with type 2 diabetes mellitus (T2D) and elevated cardiovascular risk. Prescription and consistent use of these medications are essential to realizing their benefits. In a nationwide deidentified United States administrative claims database of adults with T2D, the prescription practices of GLP-1RAs and SGLT-2i were evaluated across guideline-directed co-morbidity indications from 2018 to 2020. The monthly fill rates were assessed for 12 months after the initiation of therapy by calculating the proportion of days with consistent medication use. Of 587,657 subjects with T2D, 80,196 (13.6%) were prescribed GLP-1RAs and 68,149 (11.5%) SGLT-2i from 2018 to 2020, representing 12.9% and 11.6% of patients with indications for each medication, respectively. In new initiators, 1-year fill rate was 52.5% for GLP-1RAs and 52.9% for SGLT-2i, which was higher for patients with commercial insurance than those with Medicare Advantage plans for both GLP-1RAs (59.3% vs 51.0%, p

Published

2023

28. Automatic Differentiation is no Panacea for Phylogenetic Gradient Computation.

Author

Fourment, Mathieu, Swanepoel, Christiaan J, Galloway, Jared G, Ji, Xiang, Gangavarapu, Karthik, Suchard, Marc A, and Matsen Iv, Frederick A

Subjects

Models, Statistical, Likelihood Functions, Phylogeny, Algorithms, Machine Learning, Bayesian inference, gradient, phylogenetics, variational inference, Biochemistry and Cell Biology, Evolutionary Biology, Genetics, Developmental Biology

Abstract

Gradients of probabilistic model likelihoods with respect to their parameters are essential for modern computational statistics and machine learning. These calculations are readily available for arbitrary models via "automatic differentiation" implemented in general-purpose machine-learning libraries such as TensorFlow and PyTorch. Although these libraries are highly optimized, it is not clear if their general-purpose nature will limit their algorithmic complexity or implementation speed for the phylogenetic case compared to phylogenetics-specific code. In this paper, we compare six gradient implementations of the phylogenetic likelihood functions, in isolation and also as part of a variational inference procedure. We find that although automatic differentiation can scale approximately linearly in tree size, it is much slower than the carefully implemented gradient calculation for tree likelihood and ratio transformation operations. We conclude that a mixed approach combining phylogenetic libraries with machine learning libraries will provide the optimal combination of speed and model flexibility moving forward.

Published

2023

29. Reproducible variability: assessing investigator discordance across 9 research teams attempting to reproduce the same observational study.

Author

Ostropolets, Anna, Albogami, Yasser, Conover, Mitchell, Banda, Juan, Baumgartner, William, Blacketer, Clair, Desai, Priyamvada, DuVall, Scott, Fortin, Stephen, Gilbert, James, Golozar, Asieh, Ide, Joshua, Kanter, Andrew, Kern, David, Kim, Chungsoo, Lai, Lana, Li, Chenyu, Liu, Feifan, Lynch, Kristine, Minty, Evan, Neves, Maria, Ng, Ding, Obene, Tontel, Pera, Victor, Pratt, Nicole, Rao, Gowtham, Rappoport, Nadav, Reinecke, Ines, Saroufim, Paola, Shoaibi, Azza, Simon, Katherine, Swerdel, Joel, Voss, Erica, Weaver, James, Zhang, Linying, Hripcsak, George, Ryan, Patrick, and Suchard, Marc

Subjects

credibility, observational data, open science, reproducibility, Humans, Research Personnel, Databases, Factual

Abstract

OBJECTIVE: Observational studies can impact patient care but must be robust and reproducible. Nonreproducibility is primarily caused by unclear reporting of design choices and analytic procedures. This study aimed to: (1) assess how the study logic described in an observational study could be interpreted by independent researchers and (2) quantify the impact of interpretations variability on patient characteristics. MATERIALS AND METHODS: Nine teams of highly qualified researchers reproduced a cohort from a study by Albogami et al. The teams were provided the clinical codes and access to the tools to create cohort definitions such that the only variable part was their logic choices. We executed teams cohort definitions against the database and compared the number of subjects, patient overlap, and patient characteristics. RESULTS: On average, the teams interpretations fully aligned with the master implementation in 4 out of 10 inclusion criteria with at least 4 deviations per team. Cohorts size varied from one-third of the master cohort size to 10 times the cohort size (2159-63 619 subjects compared to 6196 subjects). Median agreement was 9.4% (interquartile range 15.3-16.2%). The teams cohorts significantly differed from the master implementation by at least 2 baseline characteristics, and most of the teams differed by at least 5. CONCLUSIONS: Independent research teams attempting to reproduce the study based on its free-text description alone produce different implementations that vary in the population size and composition. Sharing analytical code supported by a common data model and open-source tools allows reproducing a study unambiguously thereby preserving initial design choices.

Published

2023

30. Outbreak.info genomic reports: scalable and dynamic surveillance of SARS-CoV-2 variants and mutations.

Author

Latif, Alaa, Mullen, Julia, Alkuzweny, Manar, Hufbauer, Emory, Tsueng, Ginger, Haag, Emily, Zeller, Mark, Aceves, Christine, Zaiets, Karina, Cano, Marco, Zhou, Xinghua, Qian, Zhongchao, Sattler, Rachel, Matteson, Nathaniel, Levy, Joshua, Lee, Raphael, Freitas, Lucas, Maurer-Stroh, Sebastian, Wu, Chunlei, Su, Andrew, Andersen, Kristian, Hughes, Laura, Suchard, Marc, and Gangavarapu, Karthik

Subjects

Humans, SARS-CoV-2, COVID-19, Genomics, Disease Outbreaks, Mutation

Abstract

In response to the emergence of SARS-CoV-2 variants of concern, the global scientific community, through unprecedented effort, has sequenced and shared over 11 million genomes through GISAID, as of May 2022. This extraordinarily high sampling rate provides a unique opportunity to track the evolution of the virus in near real-time. Here, we present outbreak.info , a platform that currently tracks over 40 million combinations of Pango lineages and individual mutations, across over 7,000 locations, to provide insights for researchers, public health officials and the general public. We describe the interpretable visualizations available in our web application, the pipelines that enable the scalable ingestion of heterogeneous sources of SARS-CoV-2 variant data and the server infrastructure that enables widespread data dissemination via a high-performance API that can be accessed using an R package. We show how outbreak.info can be used for genomic surveillance and as a hypothesis-generation tool to understand the ongoing pandemic at varying geographic and temporal scales.

Published

2023

31. Contextualising adverse events of special interest to characterise the baseline incidence rates in 24 million patients with COVID-19 across 26 databases: a multinational retrospective cohort study

Author

Voss, Erica A, Shoaibi, Azza, Lai, Lana Yin Hui, Blacketer, Clair, Alshammari, Thamir, Makadia, Rupa, Haynes, Kevin, Sena, Anthony G, Rao, Gowtham, van Sandijk, Sebastiaan, Fraboulet, Clement, Boyer, Laurent, Le Carrour, Tanguy, Horban, Scott, Morales, Daniel R, Roldán, Jordi Martínez, Ramírez-Anguita, Juan Manuel, Mayer, Miguel A, de Wilde, Marcel, John, Luis H, Duarte-Salles, Talita, Roel, Elena, Pistillo, Andrea, Kolde, Raivo, Maljković, Filip, Denaxas, Spiros, Papez, Vaclav, Kahn, Michael G, Natarajan, Karthik, Reich, Christian, Secora, Alex, Minty, Evan P, Shah, Nigam H, Posada, Jose D, Morales, Maria Teresa Garcia, Bosca, Diego, Juanino, Honorio Cadenas, Holgado, Antonio Diaz, Jiménez, Miguel Pedrera, Balazote, Pablo Serrano, Barrio, Noelia García, Şen, Selçuk, Üresin, Ali Yağız, Erdogan, Baris, Belmans, Luc, Byttebier, Geert, Malbrain, Manu LNG, Dedman, Daniel J, Cuccu, Zara, Vashisht, Rohit, Butte, Atul J, Patel, Ayan, Dahm, Lisa, Han, Cora, Bu, Fan, Arshad, Faaizah, Ostropolets, Anna, Nyberg, Fredrik, Hripcsak, George, Suchard, Marc A, Prieto-Alhambra, Dani, Rijnbeek, Peter R, Schuemie, Martijn J, and Ryan, Patrick B

Subjects

Lung, Brain Disorders, Patient Safety, Hematology, Infectious Diseases, 2.4 Surveillance and distribution, Aetiology, Good Health and Well Being, COVID-19, Observational research, OMOP CDM, Adverse events of special interest

Abstract

BackgroundAdverse events of special interest (AESIs) were pre-specified to be monitored for the COVID-19 vaccines. Some AESIs are not only associated with the vaccines, but with COVID-19. Our aim was to characterise the incidence rates of AESIs following SARS-CoV-2 infection in patients and compare these to historical rates in the general population.MethodsA multi-national cohort study with data from primary care, electronic health records, and insurance claims mapped to a common data model. This study's evidence was collected between Jan 1, 2017 and the conclusion of each database (which ranged from Jul 2020 to May 2022). The 16 pre-specified prevalent AESIs were: acute myocardial infarction, anaphylaxis, appendicitis, Bell's palsy, deep vein thrombosis, disseminated intravascular coagulation, encephalomyelitis, Guillain- Barré syndrome, haemorrhagic stroke, non-haemorrhagic stroke, immune thrombocytopenia, myocarditis/pericarditis, narcolepsy, pulmonary embolism, transverse myelitis, and thrombosis with thrombocytopenia. Age-sex standardised incidence rate ratios (SIR) were estimated to compare post-COVID-19 to pre-pandemic rates in each of the databases.FindingsSubstantial heterogeneity by age was seen for AESI rates, with some clearly increasing with age but others following the opposite trend. Similarly, differences were also observed across databases for same health outcome and age-sex strata. All studied AESIs appeared consistently more common in the post-COVID-19 compared to the historical cohorts, with related meta-analytic SIRs ranging from 1.32 (1.05 to 1.66) for narcolepsy to 11.70 (10.10 to 13.70) for pulmonary embolism.InterpretationOur findings suggest all AESIs are more common after COVID-19 than in the general population. Thromboembolic events were particularly common, and over 10-fold more so. More research is needed to contextualise post-COVID-19 complications in the longer term.FundingNone.

Published

2023

32. Data Integration in Bayesian Phylogenetics

Author

Hassler, Gabriel W, Magee, Andrew, Zhang, Zhenyu, Baele, Guy, Lemey, Philippe, Ji, Xiang, Fourment, Mathieu, and Suchard, Marc A

Subjects

Mathematical Sciences, Statistics, Genetics, Networking and Information Technology R&D (NITRD), Bioengineering, Infection, Generic health relevance, Bayesian networks, continuous-time Markov processes, Gaussian processes, phylogenetic comparative methods, phylogeography, Numerical and Computational Mathematics

Abstract

Researchers studying the evolution of viral pathogens and other organisms increasingly encounter and use large and complex data sets from multiple different sources. Statistical research in Bayesian phylogenetics has risen to this challenge. Researchers use phylogenetics not only to reconstruct the evolutionary history of a group of organisms, but also to understand the processes that guide its evolution and spread through space and time. To this end, it is now the norm to integrate numerous sources of data. For example, epidemiologists studying the spread of a virus through a region incorporate data including genetic sequences (e.g. DNA), time, location (both continuous and discrete) and environmental covariates (e.g. social connectivity between regions) into a coherent statistical model. Evolutionary biologists routinely do the same with genetic sequences, location, time, fossil and modern phenotypes, and ecological covariates. These complex, hierarchical models readily accommodate both discrete and continuous data and have enormous combined discrete/continuous parameter spaces including, at a minimum, phylogenetic tree topologies and branch lengths. The increased size and complexity of these statistical models have spurred advances in computational methods to make them tractable. We discuss both the modeling and computational advances below, as well as unsolved problems and areas of active research.

Published

2023

33. TreeFlow: probabilistic programming and automatic differentiation for phylogenetics

Author

Swanepoel, Christiaan, Fourment, Mathieu, Ji, Xiang, Nasif, Hassan, Suchard, Marc A, Matsen IV, Frederick A, and Drummond, Alexei

Subjects

Quantitative Biology - Populations and Evolution, Statistics - Computation

Abstract

Probabilistic programming frameworks are powerful tools for statistical modelling and inference. They are not immediately generalisable to phylogenetic problems due to the particular computational properties of the phylogenetic tree object. TreeFlow is a software library for probabilistic programming and automatic differentiation with phylogenetic trees. It implements inference algorithms for phylogenetic tree times and model parameters given a tree topology. We demonstrate how TreeFlow can be used to quickly implement and assess new models. We also show that it provides reasonable performance for gradient-based inference algorithms compared to specialized computational libraries for phylogenetics., Comment: 34 pages, 8 figures

Published

2022

34. Automatic differentiation is no panacea for phylogenetic gradient computation

Author

Fourment, Mathieu, Swanepoel, Christiaan J., Galloway, Jared G., Ji, Xiang, Gangavarapu, Karthik, Suchard, Marc A., and Matsen IV, Frederick A.

Subjects

Quantitative Biology - Populations and Evolution

Abstract

Gradients of probabilistic model likelihoods with respect to their parameters are essential for modern computational statistics and machine learning. These calculations are readily available for arbitrary models via automatic differentiation implemented in general-purpose machine-learning libraries such as TensorFlow and PyTorch. Although these libraries are highly optimized, it is not clear if their general-purpose nature will limit their algorithmic complexity or implementation speed for the phylogenetic case compared to phylogenetics-specific code. In this paper, we compare six gradient implementations of the phylogenetic likelihood functions, in isolation and also as part of a variational inference procedure. We find that although automatic differentiation can scale approximately linearly in tree size, it is much slower than the carefully-implemented gradient calculation for tree likelihood and ratio transformation operations. We conclude that a mixed approach combining phylogenetic libraries with machine learning libraries will provide the optimal combination of speed and model flexibility moving forward., Comment: 17 pages and 2 figures in main text, plus supplementary materials

Published

2022

35. hdtg: An R package for high-dimensional truncated normal simulation

Author

Zhang, Zhenyu, Chin, Andrew, Nishimura, Akihiko, and Suchard, Marc A.

Subjects

Statistics - Computation, Statistics - Applications

Abstract

Simulating from the multivariate truncated normal distribution (MTN) is required in various statistical applications yet remains challenging in high dimensions. Currently available algorithms and their implementations often fail when the number of parameters exceeds a few hundred. To provide a general computational tool to efficiently sample from high-dimensional MTNs, we introduce the hdtg package that implements two state-of-the-art simulation algorithms: harmonic Hamiltonian Monte Carlo (harmonic-HMC) and zigzag Hamiltonian Monte Carlo (Zigzag-HMC). Both algorithms exploit analytical solutions of the Hamiltonian dynamics under a quadratic potential energy with hard boundary constraints, leading to rejection-free methods. We compare their efficiencies against another state-of-the-art algorithm for MTN simulation, the minimax tilting accept-reject sampler (MET). The run-time of these three approaches heavily depends on the underlying multivariate normal correlation structure. Zigzag-HMC and harmonic-HMC both achieve 100 effective samples within 3,600 seconds across all tests with dimension ranging from 100 to 1,600, while MET has difficulty in several high-dimensional examples. We provide guidance on how to choose an appropriate method for a given situation and illustrate the usage of hdtg.

Published

2022

36. Adjusting for both sequential testing and systematic error in safety surveillance using observational data: Empirical calibration and MaxSPRT

Author

Schuemie, Martijn J., Bu, Fan, Nishimura, Akihiko, and Suchard, Marc A.

Subjects

Statistics - Methodology

Abstract

Post-approval safety surveillance of medical products using observational healthcare data can help identify safety issues beyond those found in pre-approval trials. When testing sequentially as data accrue, maximum sequential probability ratio testing (MaxSPRT) is a common approach to maintaining nominal type 1 error. However, the true type 1 error may still deviate from the specified one because of systematic error due to the observational nature of the analysis. This systematic error may persist even after controlling for known confounders. Here we propose to address this issue by combing MaxSPRT with empirical calibration. In empirical calibration, we assume uncertainty about the systematic error in our analysis, the source of uncertainty commonly overlooked in practice. We infer a probability distribution of systematic error by relying on a large set of negative controls: exposure-outcome where no causal effect is believed to exist. Integrating this distribution into our test statistics has previously been shown to restore type 1 error to nominal. Here we show how we can calibrate the critical value central to MaxSPRT. We evaluate this novel approach using simulations and real electronic health records, using H1N1 vaccinations during the 2009-2010 season as an example. Results show that combining empirical calibration with MaxSPRT restores nominal type 1 error. In our real-world example, adjusting for systematic error using empirical calibration has a larger impact than, and hence is just as essential as, adjusting for sequential testing using MaxSPRT. We recommend performing both, using the method described here., Comment: Supplemental Materials are available at https://github.com/ohdsi-studies/Eumaeus/tree/main/extras/EmpiricalCalibrationMaxSprtSuppl

Published

2022

37. Sparse precision matrix estimation in phenotypic trait evolution models

Author

Pinheiro, Felipe G., Prass, Taiane S., Hassler, Gabriel W., Suchard, Marc A., and Cybis, Gabriela B.

Subjects

Statistics - Methodology, Statistics - Computation

Abstract

Phylogenetic trait evolution models allow for the estimation of evolutionary correlations between a set of traits observed in a sample of related organisms. By directly modeling the evolution of the traits along an estimable phylogenetic tree, the model's structure effectively controls for shared evolutionary history. In these models, relevant correlations are usually assessed through the high posterior density interval of their marginal distributions. However, the selected correlations alone may not provide the full picture regarding trait relationships. Their association structure, expressed through a graph that encodes partial correlations, can in contrast highlight sparsity patterns featuring direct associations between traits. In order to develop a model-based method to identify this association structure we explore the use of Gaussian graphical models (GGM) for covariance selection. We model the precision matrix with a G-Wishart conjugate prior, which results in sparse precision estimates. Furthermore the model naturally allows for Bayes Factor tests of association between the traits, with no additional computation required. We evaluate our approach through Monte Carlo simulations and applications that examine the association structure and evolutionary correlations of phenotypic traits in Darwin's finches and genomic and phenotypic traits in prokaryotes. Our approach provides accurate graph estimates and lower errors for the precision and correlation parameter estimates, particularly for conditionally independent traits, which are the target for sparsity in GGMs., Comment: 24 pages, 4 figures

Published

2022

38. Adjusting for both sequential testing and systematic error in safety surveillance using observational data: Empirical calibration and MaxSPRT

Author

Schuemie, Martijn J, Bu, Fan, Nishimura, Akihiko, and Suchard, Marc A

Subjects

Epidemiology, Health Sciences, Generic health relevance, Humans, Calibration, Influenza A Virus, H1N1 Subtype, Probability, Delivery of Health Care, Electronic Health Records, empirical calibration, observational research, sequential testing, Statistics, Public Health and Health Services, Statistics & Probability

Abstract

Post-approval safety surveillance of medical products using observational healthcare data can help identify safety issues beyond those found in pre-approval trials. When testing sequentially as data accrue, maximum sequential probability ratio testing (MaxSPRT) is a common approach to maintaining nominal type 1 error. However, the true type 1 error may still deviate from the specified one because of systematic error due to the observational nature of the analysis. This systematic error may persist even after controlling for known confounders. Here we propose to address this issue by combing MaxSPRT with empirical calibration. In empirical calibration, we assume uncertainty about the systematic error in our analysis, the source of uncertainty commonly overlooked in practice. We infer a probability distribution of systematic error by relying on a large set of negative controls: exposure-outcome pairs where no causal effect is believed to exist. Integrating this distribution into our test statistics has previously been shown to restore type 1 error to nominal. Here we show how we can calibrate the critical value central to MaxSPRT. We evaluate this novel approach using simulations and real electronic health records, using H1N1 vaccinations during the 2009-2010 season as an example. Results show that combining empirical calibration with MaxSPRT restores nominal type 1 error. In our real-world example, adjusting for systematic error using empirical calibration has a larger impact than, and hence is just as essential as, adjusting for sequential testing using MaxSPRT. We recommend performing both, using the method described here.

Published

2023

39. Early Genomic Surveillance and Phylogeographic Analysis of Getah Virus, a Reemerging Arbovirus, in Livestock in China.

Author

Zhao, Jin, Dellicour, Simon, Yan, Ziqing, Veit, Michael, Gill, Mandev, He, Wan-Ting, Zhai, Xiaofeng, Ji, Xiang, Suchard, Marc, Lemey, Philippe, and Su, Shuo

Subjects

Getah virus, genomic surveillance, next-generation sequencing, phylodynamics, phylogeography, zoonotic pathogens, Animals, Humans, Mice, Arboviruses, China, Genomics, Livestock, Phylogeny, Genome, Viral

Abstract

Getah virus (GETV) mainly causes disease in livestock and may pose an epidemic risk due to its expanding host range and the potential of long-distance dispersal through animal trade. Here, we used metagenomic next-generation sequencing (mNGS) to identify GETV as the pathogen responsible for reemerging swine disease in China and subsequently estimated key epidemiological parameters using phylodynamic and spatially-explicit phylogeographic approaches. The GETV isolates were able to replicate in a variety of cell lines, including human cells, and showed high pathogenicity in a mouse model, suggesting the potential for more mammal hosts. We obtained 16 complete genomes and 79 E2 gene sequences from viral strains collected in China from 2016 to 2021 through large-scale surveillance among livestock, pets, and mosquitoes. Our phylogenetic analysis revealed that three major GETV lineages are responsible for the current epidemic in livestock in China. We identified three potential positively selected sites and mutations of interest in E2, which may impact the transmissibility and pathogenicity of the virus. Phylodynamic inference of the GETV demographic dynamics identified an association between livestock meat consumption and the evolution of viral genetic diversity. Finally, phylogeographic reconstruction of GETV dispersal indicated that the sampled lineages have preferentially circulated within areas associated with relatively higher mean annual temperature and pig population density. Our results highlight the importance of continuous surveillance of GETV among livestock in southern Chinese regions associated with relatively high temperatures. IMPORTANCE Although livestock is known to be the primary reservoir of Getah virus (GETV) in Asian countries, where identification is largely based on serology, the evolutionary history and spatial epidemiology of GETV in these regions remain largely unknown. Through our sequencing efforts, we provided robust support for lineage delineation of GETV and identified three major lineages that are responsible for the current epidemic in livestock in China. We further analyzed genomic and epidemiological data to reconstruct the recent demographic and dispersal history of GETV in domestic animals in China and to explore the impact of environmental factors on its genetic diversity and its diffusion. Notably, except for livestock meat consumption, other pig-related factors such as the evolution of live pig transport and pork production do not show a significant association with the evolution of viral genetic diversity, pointing out that further studies should investigate the potential contribution of other host species to the GETV outbreak. Our analysis of GETV demonstrates the need for wider animal species surveillance and provides a baseline for future studies of the molecular epidemiology and early warning of emerging arboviruses in China.

Published

2023

40. Dispersal history and bidirectional human-fish host switching of invasive, hypervirulent Streptococcus agalactiae sequence type 283.

Author

Schar, Daniel, Zhang, Zhenyu, Pires, Joao, Vrancken, Bram, Suchard, Marc, Lemey, Philippe, Ip, Margaret, Gilbert, Marius, Van Boeckel, Thomas, and Dellicour, Simon

Abstract

Human group B Streptococcus (GBS) infections attributable to an invasive, hypervirulent sequence type (ST) 283 have been associated with freshwater fish consumption in Asia. The origin, geographic dispersion pathways and host transitions of GBS ST283 remain unresolved. We gather 328 ST283 isolate whole-genome sequences collected from humans and fish between 1998 and 2021, representing eleven countries across four continents. We apply Bayesian phylogeographic analyses to reconstruct the dispersal history of ST283 and combine ST283 phylogenies with genetic markers and host association to investigate host switching and the gain and loss of antimicrobial resistance and virulence factor genes. Initial dispersal within Asia followed ST283 emergence in the early 1980s, with Singapore, Thailand and Hong Kong observed as early transmission hubs. Subsequent intercontinental dispersal originating from Vietnam began in the decade commencing 2001, demonstrating ST283 holds potential to expand geographically. Furthermore, we observe bidirectional host switching, with the detection of more frequent human-to-fish than fish-to-human transitions, suggesting that sound wastewater management, hygiene and sanitation may help to interrupt chains of transmission between hosts. We also show that antimicrobial resistance and virulence factor genes were lost more frequently than gained across the evolutionary history of ST283. Our findings highlight the need for enhanced surveillance, clinical awareness, and targeted risk mitigation to limit transmission and reduce the impact of an emerging pathogen associated with a high-growth aquaculture industry.

Published

2023

41. Prior-Preconditioned Conjugate Gradient Method for Accelerated Gibbs Sampling in Large n, Large p Bayesian Sparse Regression.

Author

Nishimura, Akihiko and Suchard, Marc

Subjects

Big data, Conjugate gradient, Markov chain Monte Carlo, Numerical linear algebra, Sparse matrix, Variable selection

Abstract

In a modern observational study based on healthcare databases, the number of observations and of predictors typically range in the order of 105-106 and of 104-105. Despite the large sample size, data rarely provide sufficient information to reliably estimate such a large number of parameters. Sparse regression techniques provide potential solutions, one notable approach being the Bayesian method based on shrinkage priors. In the large n and large p setting, however, the required posterior computation encounters a bottleneck at repeated sampling from a high-dimensional Gaussian distribution, whose precision matrix Φ is expensive to compute and factorize. In this article, we present a novel algorithm to speed up this bottleneck based on the following observation: We can cheaply generate a random vector b such that the solution to the linear system Φβ = b has the desired Gaussian distribution. We can then solve the linear system by the conjugate gradient (CG) algorithm through matrix-vector multiplications by Φ; this involves no explicit factorization or calculation of Φ itself. Rapid convergence of CG in this context is guaranteed by the theory of prior-preconditioning we develop. We apply our algorithm to a clinically relevant large-scale observational study with n = 72,489 patients and p = 22,175 clinical covariates, designed to assess the relative risk of adverse events from two alternative blood anti-coagulants. Our algorithm demonstrates an order of magnitude speed-up in posterior inference, in our case cutting the computation time from two weeks to less than a day. Supplementary materials for this article are available online.

Published

2023

42. Newly identified lineages of porcine hemagglutinating encephalomyelitis virus exhibit respiratory phenotype.

Author

He, Wan-Ting, Li, Dongyan, Baele, Guy, Zhao, Jin, Jiang, Zhiwen, Ji, Xiang, Veit, Michael, Suchard, Marc, Holmes, Edward, Lemey, Philippe, Boni, Maciej, and Su, Shuo

Subjects

novel porcine hemagglutinating encephalomyelitis virus, recombination, swine coronavirus

Abstract

Swine pathogens have a long history of zoonotic transmission to humans, occasionally leading to sustained outbreaks or pandemics. Through a retrospective epidemiological study of swine populations in China, we describe novel lineages of porcine hemagglutinating encephalomyelitis virus (PHEV) complex coronaviruses (CoVs) that cause exclusively respiratory symptoms with no signs of the neurological symptoms typically associated with classical PHEV infection. Through large-scale epidemiological surveillance, we show that these novel lineages have circulated in at least eight provinces in southeastern China. Phylogenetic and recombination analyses of twenty-four genomes identified two major viral lineages causing respiratory symptoms with extensive recombination within them, between them, and between classical PHEV and the novel respiratory variant PHEV (rvPHEV) lineages. Divergence times among the sampled lineages in the PHEV virus complex date back to 1886-1958 (mean estimate 1928), with the two major rvPHEV lineages separating approximately 20 years later. Many rvPHEV viruses show amino acid substitutions at the carbohydrate-binding site of hemagglutinin esterase (HE) and/or have lost the cysteine required for HE dimerization. This resembles the early adaptation of human CoVs, where HE lost its hemagglutination ability to adapt to growth in the human respiratory tract. Our study represents the first report of the evolutionary history of rvPHEV circulating in swine and highlights the importance of characterizing CoV diversity and recombination in swine to identify pathogens with outbreak potential that could threaten swine farming.

Published

2023

43. Health-Analytics Data to Evidence Suite (HADES): Open-Source Software for Observational Research

Author

Schuemie, Martijn, primary, Reps, Jenna, additional, Black, Adam, additional, Defalco, Frank, additional, Evans, Lee, additional, Fridgeirsson, Egill, additional, Gilbert, James P., additional, Knoll, Chris, additional, Lavallee, Martin, additional, Rao, Gowtham A., additional, Rijnbeek, Peter, additional, Sadowski, Katy, additional, Sena, Anthony, additional, Swerdel, Joel, additional, Williams, Ross D., additional, and Suchard, Marc, additional

Published

2024

44. Massive Parallelization of Massive Sample-size Survival Analysis

Author

Yang, Jianxiao, Schuemie, Martijn J., Ji, Xiang, and Suchard, Marc A.

Subjects

Statistics - Computation

Abstract

Large-scale observational health databases are increasingly popular for conducting comparative effectiveness and safety studies of medical products. However, increasing number of patients poses computational challenges when fitting survival regression models in such studies. In this paper, we use graphics processing units (GPUs) to parallelize the computational bottlenecks of massive sample-size survival analyses. Specifically, we develop and apply time- and memory-efficient single-pass parallel scan algorithms for Cox proportional hazards models and forward-backward parallel scan algorithms for Fine-Gray models for analysis with and without a competing risk using a cyclic coordinate descent optimization approach. We demonstrate that GPUs accelerate the computation of fitting these complex models in large databases by orders of magnitude as compared to traditional multi-core CPU parallelism. Our implementation enables efficient large-scale observational studies involving millions of patients and thousands of patient characteristics. The above implementation is available in the open-source R package Cyclops (Suchard et al., 2013).

Published

2022

45. Computational Statistics and Data Science in the Twenty-first Century

Author

Holbrook, Andrew J., Nishimura, Akihiko, Ji, Xiang, and Suchard, Marc A.

Subjects

Statistics - Other Statistics

Abstract

Data science has arrived, and computational statistics is its engine. As the scale and complexity of scientific and industrial data grow, the discipline of computational statistics assumes an increasingly central role among the statistical sciences. An explosion in the range of real-world applications means the development of more and more specialized computational methods, but five Core Challenges remain. We provide a high-level introduction to computational statistics by focusing on its central challenges, present recent model-specific advances and preach the ever-increasing role of non-sequential computational paradigms such as multi-core, many-core and quantum computing. Data science is bringing major changes to computational statistics, and these changes will shape the trajectory of the discipline in the 21st century.

Published

2022

46. SPREAD 4: online visualization of pathogen phylogeographic reconstructions

Author

Nahata, Kanika D, Bielejec, Filip, Monetta, Juan, Dellicour, Simon, Rambaut, Andrew, Suchard, Marc A, Baele, Guy, and Lemey, Philippe

Subjects

Biological Sciences, Genetics, phylogeography, viral spread, BEAST, Bayesian inference, visualisation, Evolutionary Biology, Microbiology

Abstract

Phylogeographic analyses aim to extract information about pathogen spread from genomic data, and visualising spatio-temporal reconstructions is a key aspect of this process. Here we present SPREAD 4, a feature-rich web-based application that visualises estimates of pathogen dispersal resulting from Bayesian phylogeographic inference using BEAST on a geographic map, offering zoom-and-filter functionality and smooth animation over time. SPREAD 4 takes as input phylogenies with both discrete and continuous location annotation and offers customised visualisation as well as generation of publication-ready figures. SPREAD 4 now features account-based storage and easy sharing of visualisations by means of unique web addresses. SPREAD 4 is intuitive to use and is available online at https://spreadviz.org, with an accompanying web page containing answers to frequently asked questions at https://beast.community/spread4.

Published

2022

47. Scalable Bayesian phylogenetics

Author

Fisher, Alexander A, Hassler, Gabriel W, Ji, Xiang, Baele, Guy, Suchard, Marc A, and Lemey, Philippe

Subjects

Biological Sciences, Genetics, Infectious Diseases, Bioengineering, Infection, Algorithms, Bayes Theorem, COVID-19, Humans, Markov Chains, Monte Carlo Method, Phylogeny, SARS-CoV-2, Software, Bayesian phylogenetics, scalable inference, online inference, Hamiltonian Monte Carlo, BEAST, adapative MCMC, Medical and Health Sciences, Evolutionary Biology, Biological sciences, Biomedical and clinical sciences

Abstract

Recent advances in Bayesian phylogenetics offer substantial computational savings to accommodate increased genomic sampling that challenges traditional inference methods. In this review, we begin with a brief summary of the Bayesian phylogenetic framework, and then conceptualize a variety of methods to improve posterior approximations via Markov chain Monte Carlo (MCMC) sampling. Specifically, we discuss methods to improve the speed of likelihood calculations, reduce MCMC burn-in, and generate better MCMC proposals. We apply several of these techniques to study the evolution of HIV virulence along a 1536-tip phylogeny and estimate the internal node heights of a 1000-tip SARS-CoV-2 phylogenetic tree in order to illustrate the speed-up of such analyses using current state-of-the-art approaches. We conclude our review with a discussion of promising alternatives to MCMC that approximate the phylogenetic posterior. This article is part of a discussion meeting issue 'Genomic population structures of microbial pathogens'.

Published

2022

48. Context-specific emergence and growth of the SARS-CoV-2 Delta variant

Author

McCrone, John T, Hill, Verity, Bajaj, Sumali, Pena, Rosario Evans, Lambert, Ben C, Inward, Rhys, Bhatt, Samir, Volz, Erik, Ruis, Christopher, Dellicour, Simon, Baele, Guy, Zarebski, Alexander E, Sadilek, Adam, Wu, Neo, Schneider, Aaron, Ji, Xiang, Raghwani, Jayna, Jackson, Ben, Colquhoun, Rachel, O’Toole, Áine, Peacock, Thomas P, Twohig, Kate, Thelwall, Simon, Dabrera, Gavin, Myers, Richard, Faria, Nuno R, Huber, Carmen, Bogoch, Isaac I, Khan, Kamran, du Plessis, Louis, Barrett, Jeffrey C, Aanensen, David M, Barclay, Wendy S, Chand, Meera, Connor, Thomas, Loman, Nicholas J, Suchard, Marc A, Pybus, Oliver G, Rambaut, Andrew, and Kraemer, Moritz UG

Subjects

Emerging Infectious Diseases, Infectious Diseases, Good Health and Well Being, COVID-19, Cities, Contact Tracing, England, Genome, Viral, Humans, Quarantine, SARS-CoV-2, Travel, COVID-19 Genomics UK (COG-UK) Consortium, General Science & Technology

Abstract

The SARS-CoV-2 Delta (Pango lineage B.1.617.2) variant of concern spread globally, causing resurgences of COVID-19 worldwide1,2. The emergence of the Delta variant in the UK occurred on the background of a heterogeneous landscape of immunity and relaxation of non-pharmaceutical interventions. Here we analyse 52,992 SARS-CoV-2 genomes from England together with 93,649 genomes from the rest of the world to reconstruct the emergence of Delta and quantify its introduction to and regional dissemination across England in the context of changing travel and social restrictions. Using analysis of human movement, contact tracing and virus genomic data, we find that the geographic focus of the expansion of Delta shifted from India to a more global pattern in early May 2021. In England, Delta lineages were introduced more than 1,000 times and spread nationally as non-pharmaceutical interventions were relaxed. We find that hotel quarantine for travellers reduced onward transmission from importations; however, the transmission chains that later dominated the Delta wave in England were seeded before travel restrictions were introduced. Increasing inter-regional travel within England drove the nationwide dissemination of Delta, with some cities receiving more than 2,000 observable lineage introductions from elsewhere. Subsequently, increased levels of local population mixing-and not the number of importations-were associated with the faster relative spread of Delta. The invasion dynamics of Delta depended on spatial heterogeneity in contact patterns, and our findings will inform optimal spatial interventions to reduce the transmission of current and future variants of concern, such as Omicron (Pango lineage B.1.1.529).

Published

2022

49. Genetic tracing of market wildlife and viruses at the epicenter of the COVID-19 pandemic

Author

Crits-Christoph, Alexander, Levy, Joshua I., Pekar, Jonathan E., Goldstein, Stephen A., Singh, Reema, Hensel, Zach, Gangavarapu, Karthik, Rogers, Matthew B., Moshiri, Niema, Garry, Robert F., Holmes, Edward C., Koopmans, Marion P.G., Lemey, Philippe, Peacock, Thomas P., Popescu, Saskia, Rambaut, Andrew, Robertson, David L., Suchard, Marc A., Wertheim, Joel O., Rasmussen, Angela L., Andersen, Kristian G., Worobey, Michael, and Débarre, Florence

Published

2024

50. Accelerating Bayesian inference of dependency between complex biological traits

Author

Zhang, Zhenyu, Nishimura, Akihiko, Trovão, Nídia S., Cherry, Joshua L., Holbrook, Andrew J., Ji, Xiang, Lemey, Philippe, and Suchard, Marc A.

Subjects

Statistics - Methodology, Quantitative Biology - Populations and Evolution, Statistics - Computation

Abstract

Inferring dependencies between complex biological traits while accounting for evolutionary relationships between specimens is of great scientific interest yet remains infeasible when trait and specimen counts grow large. The state-of-the-art approach uses a phylogenetic multivariate probit model to accommodate binary and continuous traits via a latent variable framework, and utilizes an efficient bouncy particle sampler (BPS) to tackle the computational bottleneck -- integrating many latent variables from a high-dimensional truncated normal distribution. This approach breaks down as the number of specimens grows and fails to reliably characterize conditional dependencies between traits. Here, we propose an inference pipeline for phylogenetic probit models that greatly outperforms BPS. The novelty lies in 1) a combination of the recent Zigzag Hamiltonian Monte Carlo (Zigzag-HMC) with linear-time gradient evaluations and 2) a joint sampling scheme for highly correlated latent variables and correlation matrix elements. In an application exploring HIV-1 evolution from 535 viruses, the inference requires joint sampling from an 11,235-dimensional truncated normal and a 24-dimensional covariance matrix. Our method yields a 5-fold speedup compared to BPS and makes it possible to learn partial correlations between candidate viral mutations and virulence. Computational speedup now enables us to tackle even larger problems: we study the evolution of influenza H1N1 glycosylations on around 900 viruses. For broader applicability, we extend the phylogenetic probit model to incorporate categorical traits, and demonstrate its use to study Aquilegia flower and pollinator co-evolution., Comment: 39 pages, 5 figures, 3 tables

Published

2022