current courses

• None. Check back later.

past courses

• Public Health 242C & Statistics 247C: Longitudinal Data Analysis (Fall 2019), as graduate student instructor with Prof. Alan Hubbard

• Public Health 290: Targeted Learning in Biomedical Big Data (Spring 2018), as graduate student instructor with Prof. Mark van der Laan
  Course materials here | GitHub repositories here

recent workshops

• The tlverse software ecosystem for causal inference at the Atlantic Causal Inference Conference; 2019 May 22; co-taught with M. van der Laan, A. Hubbard, J. Coyle, I. Malenica, R. Phillips.
  Course materials here | GitHub repository here.

Carpentries workshops

I am an active member of Software Carpentry and Data Carpentry, through which I engage in curriculum development, maintenance of lesson materials, and workshop delivery.

• Software Carpentry: Shell, Git, and R at the Berkeley Institute for Data Science; 2019 Jan. 17-18; co-taught with S. Peterson, N. Varoquaux.
  Course materials here | GitHub repository here

• Software Carpentry: Shell, Git, and Python at the Berkeley Institute for Data Science; 2018 Jul. 16-17; co-taught with K. Marwaha.
  Course materials here | GitHub repository here

• Data Carpentry: Genomics at Lawrence Berkeley National Laboratory; 2018 May 3-4; co-taught with A. Orr.
  Course materials here | GitHub repository here

Targeted Learning and the tlverse

The tlverse is an ecosystem of R packages for Targeted Learning, of which I am a co-founder and core developer. A few of the tlverse packages to which I have made significant contributions include

• sl3: An R package providing a modern implementation of the Super Learner ensemble modeling algorithm that simultaneously exposes a grammar for composing arbitrary machine learning pipelines. Joint work with Jeremy Coyle, Ivana Malenica, and Oleg Sofrygin.
  [Docs] | [GitHub]
  

• origami: An R package providing a general framework for the application of various cross-validation schemes to arbitrary functions, facilitating the extension of cross-validation to a diversity of applications. Joint work with Jeremy Coyle.
  [Docs] | [GitHub] | [CRAN]
  

• hal9001: An R package providing an efficient implementation of the Highly Adaptive Lasso (HAL), a nonparametric regression estimator with optimality guarantees useful in semiparametric inference. Joint work with Jeremy Coyle and Mark van der Laan.
  [Docs] | [GitHub]
  

• tmle3shift: An R package providing a targeted maximum likelihood estimator of effects of stochastic interventions, with summarization of effects via working marginal structural models. Joint work with Jeremy Coyle and Mark van der Laan.
  [Docs] | [GitHub]
  

Causal Inference with Machine Learning

A significant focus of my research program lies at the intersection of causal inference and statistical machine learning. I’ve (co-)developed R packages for settings ranging from causal mediation analysis and the assessment of stochastic intervention effects with two-phase sampling to nonparametric conditional density estimation and survival analysis.

• medshift: An R package for estimating the population intervention (in)direct effects based on stochastic interventions, including both classical and efficient estimators for incremental propensity score intervention (causal) effects. Joint work with Iván Díaz.
  [Docs] | [GitHub]
  

• txshift: An R package for efficient estimation of and inference on the causal effects of stochastic interventions, accommodating robust estimation and semiparametric-efficient inference in the presence of two-phased sampling. Joint work with David Benkeser.
  [Docs] | [GitHub]
  

• haldensify: An R package for nonparametric conditional density estimation using techniques based on the highly adaptive lasso, designed specifically for estimation of the generalized propensity score. Joint work with David Benkeser and Mark van der Laan.
  [Docs] | [GitHub]
  

• survtmle: An R package for the construction of targeted maximum likelihood estimates of marginal cumulative incidence in survival settings with and without competing risks, including estimators that respect bounds. Joint work with David Benkeser.
  [Docs] | [GitHub] | [CRAN]
  

Computational Biology and Bioconductor

A parallel thread of my research concerns the development of novel statistical methodologies for application in high-dimensional and computational biology settings. Consequently, I have (co-)developed several R packages extending the Bioconductor Project.

• biotmle: An R package for the model-free discovery of biomarkers from biological expression data, introducing a generalization of moderated statistics for variance stabilization of semiparametric estimators. Joint work with Alan Hubbard and Mark van der Laan.
  [Docs] | [GitHub] | [Bioconductor]

• scPCA: An R package for sparse contrastive principal component analysis, facilitating the recovery of stable and low-dimensional expression patterns while removing technical artifacts based on control samples. Joint work with Philippe Boileau and Sandrine Dudoit.
  [GitHub] | [Bioconductor]

• methyvim: An R package for genome-wide assessment of differential methylation based on estimation of variable importance measures at the level of CpG sites. Joint work with Mark van der Laan.
  [Docs] | [GitHub] | [Bioconductor]
  

• adaptest: An R package for multiple hypothesis testing with data adaptive target parameters in high-dimensional settings using Targeted Learning. Joint work with Weixin Cai and Alan Hubbard.
  [GitHub] | [Bioconductor]
  

Miscellaneous

• nima: An R package housing my personal R toolbox, written to support statistical computing for research.
  [Docs] | [GitHub] | [CRAN]