Template-Type: ReDIF-Paper 1.0
Title: Drivers of COVID-19 deaths in the United States: A two-stage modeling approach
Abstract: We offer a two-stage (time-series and cross-section) econometric modeling approach to examine the drivers behind the spread of COVID-19
deaths across counties in the United States.
Our empirical strategy exploits the availability of two years (January 2020 through January 2022) of daily data on the number of conKrmed deaths
and cases of COVID-19 in the 3,000 U.S. counties of the 48 contiguous states and the District of Columbia. In the Krst stage of the analysis, we use
daily time-series data on COVID-19 cases and deaths to Kt mixed models of deaths against lagged conKrmed cases for each county. Because the
resulting coeffcients are county specifc, they relax the homogeneity assumption that is implicit when the analysis is performed using
geographically aggregated cross-section units. In the second stage of the analysis, we assume that these county estimates are a function of
economic and sociodemographic factors that are taken as Kxed over the course of the pandemic. Here we employ the novel one-covariate-at-a-
time variable-selection algorithm proposed by Chudik et al. (2018) to guide the choice of regressors.
Author-name: Kit Baum
Author-workplace-name: Boston College 
Author-Person: pba1
Author-Name: Andrés Garcia-Suaza
Author-Workplace-Name: University del Rosario
Author-Person: pga253
Author-Name: Miguel Henry
Author-Workplace-Name: QuantEcon Research
Author-Person: phe668
Author-Name: Jesús Otero
Author-Workplace-Name: University del Rosario
Author-Person: pot11
File-URL: http://repec.org/neur2023/Northern_Europe23_Baum.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:01

Template-Type: ReDIF-Paper 1.0
Title: Estimation of two-stage models in individual participant data meta-analysis with missing data.
Abstract: Individual participant data (IPD) meta-analysis often has missing data and is analyzed in two-steps: estimates are Krst obtained within each
individual study and then averaged across studies.The current mi suite of commands for dealing with missing data does not allow a two-stage approach in Ktting regression models. Therefore, I
introduce a new command, twostage, that offers to Kt two-stage regression models for IPD meta-analysis with missing data. twostage has been
developed to accommodate systematic and sporadically missing data in IPD meta-analysis. I Krst brieYy describe the challenges of missing data in
IPD meta-analysis and then illustrate applications of the twostage command in the context of health-related studies.
Author-name: Robert Thiesmeier
Author-workplace-name: Karolinska Institutet 
File-URL: http://repec.org/neur2023/Northern_Europe23_Thiesmeier.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:02

Template-Type: ReDIF-Paper 1.0
Title: Imputation of systematic missing data in individual participant data meta-analysis
Abstract: Answering research questions in light of multiple studies is challenged by one or more variables being 100% unobserved by design, also
known as systematic missing data.The current imputation methods implemented in mi, however, are mainly suited for one study and sporadically missing data. Our aim is
introduce a new user-deKned imputation method within mi impute capable of handling the main features of individual participant data (IPD) meta-
analysis. Realistic simulated studies will be used to illustrate the logic and practice of imputing systematic missing data.
Author-name: Nicola Orsini
Author-workplace-name: Karolinska Institutet 
File-URL: http://repec.org/neur2023/Northern_Europe23_Orsini.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:03

Template-Type: ReDIF-Paper 1.0
Title: A command for estimating regression parameters for the maximum agreement predictor
Abstract: This presentation presents mareg, a command for estimating the coeQcients of maximum agreement regression models for an outcome
variable given predictors. Recently introduced by Bottai et al. (The American Statistician. 2022. 76:4, 313–321), maximum agreement regression maximizes the concordance
correlation between the prediction and the observed outcome, not the Pearson's correlation coeQcient maximized by ordinary linear regression.
The syntax of the command is nearly identical to that of regress, which estimates least-squares regression. The presentation shows the features
of the command and its possible applications through real data examples.
Author-name: Matteo Bottai
Author-workplace-name: Karolinska Institutet
File-URL: http://repec.org/neur2023/Northern_Europe23_Bottai.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:04

Template-Type: ReDIF-Paper 1.0
Title: Regression to the mean and randomized control trials with continuous outcomes
Abstract: Measurement errors in a study make the “regression to the mean” occur to different degrees.
To remedy the “regression to the mean” effect in randomized control trials, one should measure the continuous outcome before randomization and
adjust for the baseline outcome value in the analysis. This adjustment requires the use of regression constraints. The adjustment leads to lesser
standard errors. After presenting a real case, I introduce the concept of “regression to the mean.” Then I introduce the relation from “regression to
the mean” to the intraclass correlation and the measurement error. Using the case, I compare the estimates from several approaches in
randomized control trials. Here I demonstrate the use of constraints. Knowing the intraclass correlation in power calculations will lead to a lesser
required number of observations, for example, higher power. Hence, randomized control trials should report the intraclass correlation.
Author-name: Nils Henrik Bruun
Author-workplace-name: Aalborg University Hospital 
File-URL: http://repec.org/neur2023/Northern_Europe23_Bruun.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:05

Template-Type: ReDIF-Paper 1.0
Title: Heterogeneous difference-in-differences estimation
Abstract: Treatment effects might differ over time and for groups that are treated at different points in time.
These groups are known as treatment cohorts. In Stata 18, we introduced two commands that estimate treatment effects that vary over time and
cohort. For repeated cross-sectional data, we have hdidregress. For panel data, we have xthdidregress. Both commands let you graph the
evolution of treatment over time. They also allow you to aggregate treatment within cohort and time and visualize these effects. I will show you
how both commands work and brieYy discuss the theory underlying them.
Author-name: Enrique Pinzón
Author-workplace-name: StataCorp LLC
File-URL: http://repec.org/neur2023/Northern_Europe23_Pinzon.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:06

Template-Type: ReDIF-Paper 1.0
Title: Modeling hazard rates with mutliple time scales: An application study
Abstract: There are situations when we need to model multiple time scales in survival analysis.
A usual approach would involve Ktting Cox or Poisson models to a time-split dataset. However, this leads to large datasets and can be
computationally intensive when model Ktting, especially if interest lies in displaying how the estimated hazard rate or survival changes along
multiple time scales continuously. Flexible parametric survival models on the log-hazard scale are an alternative method when modeling data with
multiple time scales. This can be achieved by using the Stata package stmt, where one of the time scales is chosen to be a primary time scale, and
the other time scale(s) is(are) speciKed by using the offset option. Through a case study, I will demonstrate this method and provide examples of
graphical representations.
Author-name: Nurgul Batyrbekova
Author-workplace-name: Karolinska Institutet 
Handle: RePEc:boc:neur23:07

Template-Type: ReDIF-Paper 1.0
Title: Hierarchical time-to-event data is common across various research domains.
Abstract: In the medical Keld, for instance, patients are often nested within hospitals and regions, while in education, students are nested within schools. In
these settings, the outcome is typically measured at the individual level, with covariates recorded at any level of the hierarchy. This hierarchical
structure poses unique challenges and necessitates appropriate analytical approaches. Traditional methods, like the widely used Cox model,
assume the independence of study subjects, disregarding the inherent correlations among subjects nested within the same higher-level unit (such
as a hospital). Consequently, failing to account for the multilevel structure and within-cluster correlation can yield biased and ineQcient results.
To address these issues, one can use mixed-effects models, which incorporate both population-level Kxed effects and cluster-speciKc random
effects at various levels of the hierarchy. Stata users can leverage several powerful commands to Kt hierarchical survival models, such as mestreg
and stmixed. With this presentation, I introduce and demonstrate the use of these commands, including a range of postestimation predictions.
Moreover, I delve into measures that quantify the impact of the hierarchical structure, commonly referred to as contextual effects in the literature,
and discuss the interpretation of model-based predictions, focusing on the difference between conditional and marginal effects.
Author-name: Alessandro Gasparini
Author-workplace-name: Red Door Analytics AB
File-URL: http://repec.org/neur2023/Northern_Europe23_Gasparini.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:08

Template-Type: ReDIF-Paper 1.0
Title: Modeling excess mortality comparing with a control population: A combined additive and relative hazards model
Abstract: In this presentation, I propose a Yexible parametric excess hazard model on the log-hazard scale, incorporating a modeled expected rate
from a control population (for example, matched comparators). Covariate effects are assumed to be multiplicative within both the expected hazard and the excess hazard, while the presence of disease among
the studied group has an additive effect, hence the excess hazard. By modeling the expected rate, we can appropriately allow for uncertainty. The
model is extended to include time-dependent effects, multiple time scales, and more. Following estimation, we quantify results through the
prediction of the survival, hazard, and cumulative incidence functions, as well as transformations of these, and crucially with associated conKdence
intervals on all measures. The proposed method has been implemented in the Stata package stexcess (github.com/RedDoorAnalytics/stexcess).
Author-name: Caroline Weibull
Author-workplace-name: Karolinska Institutet 
Author-workplace-name: Red Door Analytics AB
File-URL: http://repec.org/neur2023/Northern_Europe23_Weibull.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:09

Template-Type: ReDIF-Paper 1.0
Title: Health technology assessment and Stata: Reviewing the old and coding the new
Abstract: Health technology assessment (HTA) utilizes a wide variety of statistical methods to evaluate clinical and cost effectiveness of treatments,
including survival analysis and meta-analysis.
In this presentation, I will brieYy review some of the available features in Stata that have been developed over the years, with a focus towards their
use in HTA, and describe some ongoing work to improve their applicability in such settings. This will include Yexible survival modeling with merlin,
Markov, semi-Markov and non-Markov multistate modeling with multistate, and eQcient and generalizable individual patient simulation with
survsim. Finally, I will introduce some new tools, such as the maic command for conducting matched-adjusted indirect comparisons, and a new
preKx command for stmerlin, providing Bayesian Yexible survival models.
Author-name: Michael Crowther 
Author-workplace-name: Red Door Analytics AB
File-URL: http://repec.org/neur2023/Northern_Europe23_Crowther.pdf
File-Format: application/pdf
File-Function: presentation materials
Handle: RePEc:boc:neur23:10