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2. Clarifying causality and information flows between time series: Particulate air pollution, temperature, and elderly mortality

Author

Louis Anthony Cox, Jr

Subjects
PM2.5, Mortality, Minimum daily temperature, Confounding, Time series, Partial dependence plots, Infectious and parasitic diseases, RC109-216
Abstract

Exposure-response associations between fine particulate matter (PM2.5) and mortality have been extensively studied but potential confounding by daily minimum and maximum temperatures in the weeks preceding death has not been carefully investigated. This paper seeks to close that gap by using lagged partial dependence plots (PDPs), sorted by importance, to quantify how mortality risk depends on lagged values of PM2.5, daily minimum and maximum temperatures and other variables in a dataset from the Los Angeles air basin (SCAQMD). We find that daily minimum and maximum temperatures and daily mortality counts two to three weeks ago are important independent predictors of both current daily elderly mortality and current PM2.5 levels. Thus, it is important to control for these variables over a period of at least several weeks preceding death. Such detailed control for lagged confounders has not been performed in influential past papers on PM2.5-mortality associations, but appears to be essential for isolating the potential causal contributions of specific variables to mortality risk, and, therefore, a worthwhile area for future research and risk assessment modeling.

Published
2024
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3. Challenging unverified assumptions in causal claims: Do gas stoves increase risk of pediatric asthma?

Author

Louis Anthony Cox, Jr.

Subjects
Gas stoves, Asthma, NO2, Causality, Infectious and parasitic diseases, RC109-216
Abstract

The use of unverified models for risk estimates and policy recommendations can be highly misleading, as their predictions may not reflect real-world health impacts. For example, a recent article states that NO2 from gas stoves “likely causes ∼50,000 cases of current pediatric asthma from long-term NO2 exposure alone” annually in the United States. This explicitly causal claim, which is contrary to several methodology and review articles published in this journal, among others, reflects both (a) An unverified modeling assumption that pediatric asthma burden is approximately proportional to NO2; and (b) An unverified causal assumption that the assumed proportionality between exposure and response is causal. The article is devoid of any causal analysis showing that these assumptions are likely to be true. It does not show that reducing NO2 exposure from gas stoves would reduce pediatric asthma risk. Its key references report no significant associations – let alone causation – between NO2 and pediatric asthma. Thus, the underlying data suggests that the number of pediatric asthma cases caused by gas stoves in the United States is indistinguishable from zero. This highlights the need to rigorously validate modeling assumptions and causal claims in public health risk assessments to ensure scientifically sound foundations for policy decisions.

Published
2024
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4. An AI assistant to help review and improve causal reasoning in epidemiological documents

Author

Louis Anthony Cox, Jr.

Subjects
Artificial intelligence, Causality, Review methodology, Causal AI boosting, Large language models (LLMs), Infectious and parasitic diseases, RC109-216
Abstract

Drawing sound causal inferences from observational data is often challenging for both authors and reviewers. This paper discusses the design and application of an Artificial Intelligence Causal Research Assistant (AIA) that seeks to help authors improve causal inferences and conclusions drawn from epidemiological data in health risk assessments. The AIA-assisted review process provides structured reviews and recommendations for improving the causal reasoning, analyses and interpretations made in scientific papers based on epidemiological data. Causal analysis methodologies range from earlier Bradford-Hill considerations to current causal directed acyclic graph (DAG) and related models. AIA seeks to make these methods more accessible and useful to researchers. AIA uses an external script (a “Causal AI Booster” (CAB) program based on classical AI concepts of slot-filling in frames organized into task hierarchies to complete goals) to guide Large Language Models (LLMs), such as OpenAI's ChatGPT or Google's LaMDA (Bard), to systematically review manuscripts and create both (a) recommendations for what to do to improve analyses and reporting; and (b) explanations and support for the recommendations. Review tables and summaries are completed systematically by the LLM in order. For example, recommendations for how to state and caveat causal conclusions in the Abstract and Discussion sections reflect previous analyses of the Study Design and Data Analysis sections. This work illustrates how current AI can contribute to reviewing and providing constructive feedback on research documents. We believe that such AI-assisted review shows promise for enhancing the quality of causal reasoning and exposition in epidemiological studies. It suggests the potential for effective human-AI collaboration in scientific authoring and review processes.

Published
2024
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5. What is an exposure-response curve?

Author

Louis Anthony Cox, Jr

Subjects
Exposure-response curve, Partial dependence plot (PDP), Accumulated local effects (ALE) plot, Individual conditional expectation (ICE) plot, Causal artificial intelligence (CAI), Infectious and parasitic diseases, RC109-216
Abstract

Exposure-response curves are among the most widely used tools of quantitative health risk assessment. However, we propose that exactly what they mean is usually left ambiguous, making it impossible to answer such fundamental questions as whether and by how much reducing exposure by a stated amount would change average population risks and distributions of individual risks. Recent concepts and computational methods from causal artificial intelligence (CAI) and machine learning (ML) can be applied to clarify what an exposure-response curve means; what other variables are held fixed (and at what levels) in estimating it; and how much inter-individual variability there is around population average exposure-response curves. These advances in conceptual clarity and practical computational methods not only enable epidemiologists and risk analysis practitioners to better quantify population and individual exposure-response curves but also challenge them to specify exactly what exposure-response relationships they seek to quantify and communicate to risk managers and how to use the resulting information to improve risk management decisions.

Published
2023
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6. The gas stove-childhood asthma kerfuffle: A teaching opportunity

Author

Louis Anthony Cox, Jr.

Subjects
Indoor air pollution, Gas stoves, Childhood asthma, Questionable research practices, Infectious and parasitic diseases, RC109-216
Abstract

Several recent news stories have alarmed many politicians and members of the public by reporting that indoor air pollution from gas stoves causes about 13% of childhood asthma in the United States. Research on the reproducibility and trustworthiness of epidemiological risk assessments has identified a number of common questionable research practices (QRPs) that should be avoided to draw sound causal conclusions from epidemiological data. Examples of such QRPs include claiming causation without using study designs or data analyses that allow valid causal inferences; generalizing or transporting risk estimates based on data for specific populations, time periods, and locations to different ones without accounting for differences in the study and target populations; claiming causation without discussing or quantitatively correcting for confounding, external validity bias, or other biases; and not mentioning or resolving contradictory evidence. We examine the recently estimated gas stove-childhood asthma associations from the perspective of these QRPs and conclude that it exemplifies all of them. The quantitative claim that about 13% of childhood asthma in the United States could be prevented by reducing exposure to gas stove pollution is not supported by the data collected or by the measures of association (Population Attributable Fractions) used to analyze the data. The qualitative finding that reducing exposure to gas stove pollution would reduce the burden of childhood asthma in the United States has no demonstrated validity. Systematically checking how and whether QRPs have been addressed before reporting or responding to claims that everyday exposures cause substantial harm to health might reduce social amplification of perceived risks based on QRPs and help to improve the credibility and trustworthiness of published epidemiological risk assessments.

Published
2023
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7. Causal reasoning about epidemiological associations in conversational AI

Author

Louis Anthony Cox, Jr

Subjects
Large language models, Causal reasoning, ChatGPT, Causal artificial intelligence, PM2.5, Infectious and parasitic diseases, RC109-216
Abstract

We present a Socratic dialogue with ChatGPT, a large language model (LLM), on the causal interpretation of epidemiological associations between fine particulate matter (PM2.5) and human mortality risks. ChatGPT, reflecting probable patterns of human reasoning and argumentation in the sources on which it has been trained, initially holds that “It is well-established that exposure to ambient levels of PM2.5 does increase mortality risk” and adds the unsolicited remark that “Reducing exposure to PM2.5 is an important public health priority.” After patient questioning, however, it concludes that “It is not known with certainty that current ambient levels of PM2.5 increase mortality risk. While there is strong evidence of an association between PM2.5 and mortality risk, the causal nature of this association remains uncertain due to the possibility of omitted confounders.” This revised evaluation of the evidence suggests the potential value of sustained questioning in refining and improving both the types of human reasoning and argumentation imitated by current LLMs and the reliability of the initial conclusions expressed by current LLMs.

Published
2023
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8. Higher line speed in young chicken slaughter establishments does not predict increased Salmonella contamination risks

Author

Louis Anthony Cox, Jr.

Subjects
Salmonella, risk analysis, chicken, slaughter, line speed, Animal culture, SF1-1100
Abstract

Do faster slaughter line speeds for young chickens increase risk of Salmonella contamination? We analyze data collected in 2018–2019 from 97 slaughter establishments processing young chickens to examine the extent to which differences in slaughter line speeds across establishments operating under the same inspection system explain observed differences in their microbial quality, specifically frequencies of positive Salmonella samples. A variety of off-the-shelf statistical and machine learning techniques applied to the data to identify and visualize correlations and potential causal relationships among variables showed that the presence of Salmonella or other indicators of process control, such as noncompliance records for regulations associated with process control and food safety, are not significantly increased in establishments with higher line speeds (e.g., above 140 birds per min) compared with establishments with lower line speeds when establishments are operating under the conditions present in this study. This included some establishments operating under specific criteria to obtain a waiver for line speed. A null hypothesis advanced over 30 yr ago by the National Research Council that increased line speeds result in a product that is not contaminated more often than before line speeds were increased, appears to be fully consistent with these recent data.

Published
2021
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9. Commentary: Using potential outcomes causal methods to assess whether reductions in PM2.5 result in decreased mortality

Author

Julie E. Goodman, Wenchao Li, and Louis Anthony Cox, Jr

Subjects
Causal methods, Fine particulate matter, Mortality, Instrumental variable, Structural nested mean model, Potential outcomes framework, Infectious and parasitic diseases, RC109-216
Abstract

Causal inference regarding exposures to ambient fine particulate matter (PM2.5) and mortality estimated from observational studies is limited by confounding, among other factors. In light of a variety of causal inference frameworks and methods that have been developed over the past century to specifically quantify causal effects, three research teams were selected in 2016 to evaluate the causality of PM2.5-mortality association among Medicare beneficiaries, using their own selections of causal inference methods and study designs but the same data sources. With a particular focus on controlling for unmeasured confounding, two research teams adopted an instrumental variables approach under a quasi-experiment or natural experiment study design, whereas one team adopted a structural nested mean model under the traditional cohort study design. All three research teams reported results supporting an estimated counterfactual causal relationship between ambient PM2.5 and all-cause mortality, and their estimated causal relationships are largely of similar magnitudes to recent epidemiological studies based on regression analyses with omitted potential confounders. The causal methods used by all three research teams were built upon the potential outcomes framework. This framework has marked conceptual advantages over regression-based methods in addressing confounding and yielding unbiased estimates of average treatment effect in observational epidemiological studies. However, potential violations of the unverifiable assumptions underlying each causal method leave the results from all three studies subject to biases. We also note that the studies are not immune to some other common sources of bias, including exposure measurement errors, ecological study design, model uncertainty and specification errors, and irrelevant exposure windows, that can undermine the validity of causal inferences in observational studies. As a result, despite some apparent consistency of study results from the three research teams with the wider epidemiological literature on PM2.5-mortality statistical associations, caution seems warranted in drawing causal conclusions from the results. A possible way forward is to improve study design and reduce dependence of conclusions on untested assumptions by complementing potential outcomes methods with structural causal modeling and information-theoretic methods that emphasize empirically tested and validated relationships.

Published
2021
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10. Thinking about Causation: A Thought Experiment with Dominos

Author

Louis Anthony Cox, Jr

Subjects
Causality, Causal artificial intelligence, Population attributable fraction, Probability of causation, Risk analysis, Statistical methods, Infectious and parasitic diseases, RC109-216
Abstract

We argue that population attributable fractions, probabilities of causation, burdens of disease, and similar association-based measures often do not provide valid estimates or surrogates for the fraction or number of disease cases that would be prevented by eliminating or reducing an exposure because their calculations do not include crucial mechanistic information. We use a thought experiment with a cascade of dominos to illustrate the need for mechanistic information when answering questions about how changing exposures changes risk. We suggest that modern methods of causal artificial intelligence (CAI) can fill this gap: they can complement and extend traditional epidemiological attribution calculations to provide information useful for risk management decisions.

Published
2021
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11. Toward practical causal epidemiology

Author

Louis Anthony Cox, Jr

Subjects
Causality, Causal artificial intelligence, Population attributable fraction, Probability of causation, Risk analysis, Statistical methods, Infectious and parasitic diseases, RC109-216
Abstract

Population attributable fraction (PAF), probability of causation, burden of disease, and related quantities derived from relative risk ratios are widely used in applied epidemiology and health risk analysis to quantify the extent to which reducing or eliminating exposures would reduce disease risks. This causal interpretation conflates association with causation. It has sometimes led to demonstrably mistaken predictions and ineffective risk management recommendations. Causal artificial intelligence (CAI) methods developed at the intersection of many scientific disciplines over the past century instead use quantitative high-level descriptions of networks of causal mechanisms (typically represented by conditional probability tables or structural equations) to predict the effects caused by interventions. We summarize these developments and discuss how CAI methods can be applied to realistically imperfect data and knowledge – e.g., with unobserved (latent) variables, missing data, measurement errors, interindividual heterogeneity in exposure-response functions, and model uncertainty. We recommend that CAI methods can help to improve the conceptual foundations and practical value of epidemiological calculations by replacing association-based attributions of risk to exposures or other risk factors with causal predictions of the changes in health effects caused by interventions.

Published
2021
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12. Should air pollution health effects assumptions be tested? Fine particulate matter and COVID-19 mortality as an example

Author

Louis Anthony Cox, Jr and Douglas A. Popken

Subjects
Air pollution, COVID-19 mortality risk, PM2.5, Health effects, Causation, Scientific method, Infectious and parasitic diseases, RC109-216
Abstract

In the first half of 2020, much excitement in news media and some peer reviewed scientific articles was generated by the discovery that fine particulate matter (PM2.5) concentrations and COVID-19 mortality rates are statistically significantly positively associated in some regression models. This article points out that they are non-significantly negatively associated in other regression models, once omitted confounders (such as latitude and longitude) are included. More importantly, positive regression coefficients can and do arise when (generalized) linear regression models are applied to data with strong nonlinearities, including data on PM2.5, population density, and COVID-19 mortality rates, due to model specification errors. In general, statistical modeling accompanied by judgments about causal interpretations of statistical associations and regression coefficients – the current weight-of-evidence (WoE) approach favored in much current regulatory risk analysis for air pollutants – is not a valid basis for determining whether or to what extent risk of harm to human health would be reduced by reducing exposure. The traditional scientific method based on testing predictive generalizations against data remains a more reliable paradigm for risk analysis and risk management.

Published
2020
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13. Shapes and definitions of exposure-response curves: A comment on 'A matrix for bridging the epidemiology and risk assessment gap'

Author

Louis Anthony Cox, Jr.

Subjects
Infectious and parasitic diseases, RC109-216
Abstract

A proposed matrix bridging between the results supplied by epidemiologists and those demanded by risk assessors proposes that a key piece of information sought by risk assessors is the shape of the exposure-response curve (e.g., linear vs. nonlinear, threshold vs. no threshold, etc.). This comment emphasizes that there are several different exposure-response curves, having different causal interpretations and risk management implications. Risk assessors and risk management decision makers and policy maker usually need to know how changes in exposures would change disease risks (given assumptions about levels of other variables). Epidemiologists typically provide conditional expected observed values of response variables for different observed levels of exposures, i.e., regression relationships. These are two different curves and may have quite different shapes. Current widespread epidemiological practice conflates them. Being clear about what is needed for risk assessment (usually the former) and what has been produced by epidemiologists (usually the latter) can help to identify mismatches and to build more useful bridges between these communities.

Published
2019
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14. Should health risks of air pollution be studied scientifically?

Author

Louis Anthony Cox, Jr.

Subjects
Infectious and parasitic diseases, RC109-216
Abstract

In most areas of applied research, sound science entails use of clear definitions, explicit derivations of conclusions, reproducible tests of predictions against observations, and careful qualification of causal interpretations and conclusions to acknowledge remaining ambiguities or conflicts in evidence. I propose that these same principles should also be applied to the study of air pollution health effects associated with exposures to air pollution. This contrasts with a popular weight-of-evidence approach that does not require these restrictions, but that instead draws on authoritative judgments by selected experts to reach policy-relevant conclusions. Although the scientific approach summarized here may be less popular and more exacting, I propose that it is essential for reaching valid conclusions and identifying causally effective policies to protect public health, and that it should therefore be adopted in regulatory risk analysis.

Published
2019
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15. Communicating more clearly about deaths caused by air pollution

Author

Louis Anthony Cox, Jr.

Subjects
Risk communication, Attributable risk, Association, Causation, Risk attribution, Internal validity, Infectious and parasitic diseases, RC109-216
Abstract

How can scientists and risk assessors best communicate with each other, the media, the public, and policy makers what is known, what is guessed, and what is still unknown or uncertain about how changes in air pollution affect human mortality? Current practice includes emphatic pronouncements, striking headlines, and colorful infographics about deaths attributed to air pollution. Important qualifications, uncertainties, and unverified assumptions are often buried deeply in technical paper if they are stated at all. Although some sensational claims about air pollution mortalities have proved to be mistaken, errors and corrections receive little or no attention from media, policy makers, or interest groups who helped to spread the original sensational claims. More encouragingly, substantial recent progress has been made in technical methods for quantifying and communicating what is known about how reducing exposure affects health risks and uncertainties. These advances make it possible to better describe and explain both what we now know and what we are still uncertain about for human health effects of interventions that reduce pollution levels. We review progress in accurate communication about deaths caused by air pollution and discuss how advances in quantitative risk assessment and risk communication can provide a more useful basis for informing public opinion and policy deliberations – one that is more accurate and that answers more relevant questions – than the infographics and sensational claims that dominate risk communication about air pollution deaths today.

Published
2019
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16. Improving causal determination

Author

Louis Anthony Cox, Jr.

Subjects
Causality, Causal determination, Expert judgment, Causation, Invariant causal prediction, Causal models, Infectious and parasitic diseases, RC109-216
Abstract

Holistic expert judgments about causality are widely used in regulatory risk assessments, with causal determination categories being used to summarize huge amounts of complex evidence and to help inform and drive major regulatory decisions. The causal determination categories used typically cover a relatively narrow range (e.g., from “causal relationship,” “likely to be a causal relationship,” or “suggestive of a causal relationship” to “inadequate to infer a causal relationship” and “not likely to be a causal relationship”). Other categories, such as “not a causal relationship” or “likely to not be a causal relationship,” are omitted entirely. We note fundamental limitations of such procedures. A few categories cannot encode most of the wide variations in evidence about risks and causal exposure-response relationships found in both theory and practice. “Causal relationship” is usually left undefined, and may be interpreted very differently by different people. Whether it refers to direct, indirect, or total causal effects is seldom specified. We propose that causal partial dependence plots of predicted risk against exposure, calculated from conditional probability tables (CPTs) or models that satisfy an empirically testable condition of invariant causal prediction (ICP) across studies, can provide much more useful and clearly defined information to decision-makers. This alternative framework treats causal relationships, and evidence about them, as continuous and quantitative rather than categorical and qualitative. This is not only advantageous for clarity and realism, but it encourages better use of data and scientific method, including applying independently verifiable tests to inform conclusions about how and whether changes in exposures would change individual and population health risks.

Published
2019
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36. AI-ML for Decision and Risk Analysis : Challenges and Opportunities for Normative Decision Theory

Author

Louis Anthony Cox Jr and Louis Anthony Cox Jr

Subjects
Artificial intelligence, Machine learning, Decision making--Data processing, Risk assessment--Data processing
Abstract

This book explains and illustrates recent developments and advances in decision-making and risk analysis. It demonstrates how artificial intelligence (AI) and machine learning (ML) have not only benefitted from classical decision analysis concepts such as expected utility maximization but have also contributed to making normative decision theory more useful by forcing it to confront realistic complexities. These include skill acquisition, uncertain and time-consuming implementation of intended actions, open-world uncertainties about what might happen next and what consequences actions can have, and learning to cope effectively with uncertain and changing environments. The result is a more robust and implementable technology for AI/ML-assisted decision-making.The book is intended to inform a wide audience in related applied areas and to provide a fun and stimulating resource for students, researchers, and academics in data science and AI-ML, decision analysis, and other closely linked academic fields. It will also appeal to managers, analysts, decision-makers, and policymakers in financial, health and safety, environmental, business, engineering, and security risk management.

Published
2023

39. Quantitative Risk Analysis of Air Pollution Health Effects

Author

Louis Anthony Cox Jr and Louis Anthony Cox Jr

Subjects
Quantitative research--Data processing, Medical policy--Decision making--Statistical methods, Air--Pollution--Risk assessment, Health risk assessment--Statistical methods
Abstract

This book highlights quantitative risk assessment and modeling methods for assessing health risks caused by air pollution, as well as characterizing and communicating remaining uncertainties. It shows how to apply modern data science, artificial intelligence and machine learning, causal analytics, mathematical modeling, and risk analysis to better quantify human health risks caused by environmental and occupational exposures to air pollutants. The adverse health effects that are caused by air pollution, and preventable by reducing it, instead of merely being statistically associated with exposure to air pollution (and with other many conditions, from cold weather to low income) have proved to be difficult to quantify with high precision and confidence, largely because correlation is not causation. This book shows how to use recent advances in causal analytics and risk analysis to determine more accurately how reducing exposures affects human health risks. Quantitative Risk Analysis of Air Pollution Health Effects is divided into three parts. Part I focuses mainly on quantitative simulation modelling of biological responses to exposures and resulting health risks. It considers occupational risks from asbestos and crystalline silica as examples, showing how dynamic simulation models can provide insights into more effective policies for protecting worker health. Part II examines limitations of regression models and the potential to instead apply machine learning, causal analysis, and Bayesian network learning methods for more accurate quantitative risk assessment, with applications to occupational risks from inhalation exposures. Finally, Part III examines applications to public health risks from air pollution, especially fine particulate matter (PM2.5) air pollution. The book applies freely available browser analytics software and data sets that allow readers to download data and carry out many of the analyses described, in addition to applying the techniques discussed to their own data.http://cox-associates.com:8899/

Published
2021

40. Causal Analytics for Applied Risk Analysis

Author

Louis Anthony Cox Jr, Douglas A. Popken, Richard X. Sun, Louis Anthony Cox Jr, Douglas A. Popken, and Richard X. Sun

Subjects
Risk assessment, Risk management
Abstract

Causal analytics methods can revolutionize the use of data to make effective decisions by revealing how different choices affect probabilities of various outcomes. This book presents and illustrates models, algorithms, principles, and software for deriving causal models from data and for using them to optimize decisions with uncertain outcomes. It discusses how to describe and summarize situations; detect changes; evaluate effects of policies or interventions; learn what works best under different conditions; predict values of as-yet unobserved quantities from available data; and identify the most likely explanations for observed outcomes, including surprises and anomalies. The book resents practical techniques for causal modeling and analytics that practitioners can apply to improve understanding of how choices affect probabilities of consequences and, based on this understanding, to recommend choices that are more likely to accomplish their intended objectives.The book begins with a survey of modern analytics methods, focusing mainly on techniques useful for decision, risk, and policy analysis. Chapter 2 introduces free in-browser software, including the Causal Analytics Toolkit (CAT) software, to enable readers to perform the analyses described and to apply modern analytics methods easily to their own data sets. Chapters 3 through 11 show how to apply causal analytics and risk analytics to practical risk analysis challenges, mainly related to public and occupational health risks from pathogens in food or from pollutants in air. Chapters 12 through 15 turn to broader questions of how to improve risk management decision-making by individuals, groups, organizations, institutions, and multi-generation societies with different cultures and norms for cooperation. These chapters examine organizational learning, community resilience, societal risk management, and intergenerational collaboration and justice in managing risks.

Published
2018

41. Breakthroughs in Decision Science and Risk Analysis

Author

Louis Anthony Cox, Jr and Louis Anthony Cox, Jr

Subjects
Risk assessment, Decision making
Abstract

Discover recent powerful advances in the theory, methods, and applications of decision and risk analysis Focusing on modern advances and innovations in the field of decision analysis (DA), Breakthroughs in Decision Science and Risk Analysis presents theories and methods for making, improving, and learning from significant practical decisions. The book explains these new methods and important applications in an accessible and stimulating style for readers from multiple backgrounds, including psychology, economics, statistics, engineering, risk analysis, operations research, and management science. Highlighting topics not conventionally found in DA textbooks, the book illustrates genuine advances in practical decision science, including developments and trends that depart from, or break with, the standard axiomatic DA paradigm in fundamental and useful ways. The book features methods for coping with realistic decision-making challenges such as online adaptive learning algorithms, innovations in robust decision-making, and the use of a variety of models to explain available data and recommend actions. In addition, the book illustrates how these techniques can be applied to dramatically improve risk management decisions. Breakthroughs in Decision Science and Risk Analysis also includes: An emphasis on new approaches rather than only classical and traditional ideas Discussions of how decision and risk analysis can be applied to improve high-stakes policy and management decisions Coverage of the potential value and realism of decision science within applications in financial, health, safety, environmental, business, engineering, and security risk management Innovative methods for deciding what actions to take when decision problems are not completely known or described or when useful probabilities cannot be specified Recent breakthroughs in the psychology and brain science of risky decisions, mathematical foundations and techniques, and integration with learning and pattern recognition methods from computational intelligence Breakthroughs in Decision Science and Risk Analysis is an ideal reference for researchers, consultants, and practitioners in the fields of decision science, operations research, business, management science, engineering, statistics, and mathematics. The book is also an appropriate guide for managers, analysts, and decision and policy makers in the areas of finance, health and safety, environment, business, engineering, and security risk management.

Published
2014

42. Risk Analysis Foundations, Models, and Methods

Author

Louis Anthony Cox Jr and Louis Anthony Cox Jr

Subjects
Health risk assessment--United States, Environmental health--United States, Medical policy--United States
Abstract

Risk Analysis: Foundations, Models, and Methods fully addresses the questions of'What is health risk analysis?'and'How can its potentialities be developed to be most valuable to public health decision-makers and other health risk managers?'Risk analysis provides methods and principles for answering these questions. It is divided into methods for assessing, communicating, and managing health risks. Risk assessment quantitatively estimates the health risks to individuals and to groups from hazardous exposures and from the decisions or activities that create them. It applies specialized models and methods to quantify likely exposures and their resulting health risks. Its goal is to produce information to improve decisions. It does this by relating alternative decisions to their probable consequences and by identifying those decisions that make preferred outcomes more likely. Health risk assessment draws on explicit engineering, biomathematical, and statistical consequence models to describe or simulate the causal relations between actions and their probable effects on health. Risk communication characterizes and presents information about health risks and uncertainties to decision-makers and stakeholders. Risk management applies principles for choosing among alternative decision alternatives or actions that affect exposure, health risks, or their consequences.

Published
2012

43. Improving Risk Analysis

Author

Louis Anthony Cox Jr and Louis Anthony Cox Jr

Subjects
Risk assessment, Risk management
Abstract

Improving Risk Analysis shows how to better assess and manage uncertain risks when the consequences of alternative actions are in doubt. The constructive methods of causal analysis and risk modeling presented in this monograph will enable to better understand uncertain risks and decide how to manage them.The book is divided into three parts. Parts 1 shows how high-quality risk analysis can improve the clarity and effectiveness of individual, community, and enterprise decisions when the consequences of different choices are uncertain. Part 2 discusses social decisions. Part 3 illustrates these methods and models, showing how to apply them to health effects of particulate air pollution.'Tony Cox's new book addresses what risk analysts and policy makers most need to know: How to find out what causes what, and how to quantify the practical differences that changes in risk management practices would make. The constructive methods in Improving Risk Analysis will be invaluable in helping practitioners to deliver more useful insights to inform high-stakes decisions and policy,in areas ranging from disaster planning to counter-terrorism investments to enterprise risk management to air pollution abatement policies. Better risk management is possible and practicable; Improving Risk Analysis explains how.'Elisabeth Pate-Cornell, Stanford University'Improving Risk Analysis offers crucial advice for moving policy-relevant risk analyses towards more defensible, causally-based methods. Tony Cox draws on his extensive experience to offer sound advice and insights that will be invaluable to both policy makers and analysts in strengthening the foundations for important risk analyses. This much-needed book should be required reading for policy makers and policy analysts confronting uncertain risks and seeking more trustworthy risk analyses.'Seth Guikema, Johns Hopkins University'TonyCox has been a trail blazer in quantitative risk analysis, and his new book gives readers the knowledge and tools needed to cut through the complexity and advocacy inherent in risk analysis. Cox's careful exposition is detailed and thorough, yet accessible to non-technical readers interested in understanding uncertain risks and the outcomes associated with different mitigation actions. Improving Risk Analysis should be required reading for public officials responsible for making policy decisions about how best to protect public health and safety in an uncertain world.'Susan E. Dudley, George Washington University

Published
2012

44. Risk Analysis of Complex and Uncertain Systems

Author

Louis Anthony Cox Jr and Louis Anthony Cox Jr

Subjects
System theory, Risk assessment, Uncertainty (Information theory), Nonlinear systems
Abstract

In Risk Analysis of Complex and Uncertain Systems acknowledged risk authority Tony Cox shows all risk practitioners how Quantitative Risk Assessment (QRA) can be used to improve risk management decisions and policies. It develops and illustrates QRA methods for complex and uncertain biological, engineering, and social systems – systems that have behaviors that are just too complex to be modeled accurately in detail with high confidence – and shows how they can be applied to applications including assessing and managing risks from chemical carcinogens, antibiotic resistance, mad cow disease, terrorist attacks, and accidental or deliberate failures in telecommunications network infrastructure. This book was written for a broad range of practitioners, including decision risk analysts, operations researchers and management scientists, quantitative policy analysts, economists, health and safety risk assessors, engineers, and modelers.

Published
2009

45. Response

Author

Louis Anthony Cox Jr., Weihsueh A. Chiu, David M. Hassenzahl, and Daniel M. Kammen

Subjects
Physiology (medical), Safety, Risk, Reliability and Quality
Published
2000
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46. Quantitative Health Risk Analysis Methods : Modeling the Human Health Impacts of Antibiotics Used in Food Animals

Author

Louis Anthony Cox Jr and Louis Anthony Cox Jr

Subjects
Drug resistance in microorganisms, Domestic animals, Food--Microbiology, Antibiotics in agriculture--Health aspects--Mathematical models, Health risk assessment--Mathematical models, Antibiotic residues--Toxicology--Mathematical models, Antibiotics in animal nutrition--Health aspects--Mathematical models, Biological models
Abstract

This book grew out of an effort to salvage a potentially useful idea for greatly simplifying traditional quantitative risk assessments of the human health consequences of using antibiotics in food animals. In 2001, the United States FDA's Center for Veterinary Medicine (CVM) (FDA-CVM, 2001) published a risk assessment model for potential adverse human health consequences of using a certain class of antibiotics, fluoroquinolones, to treat flocks of chickens with fatal respiratory disease caused by infectious bacteria. CVM's concern was that fluoroquinolones are also used in human medicine, raising the possibility that fluoroquinolone-resistant strains of bacteria selected by use of fluoroquinolones in chickens might infect humans and then prove resistant to treatment with human medicines in the same class of antibiotics, such as ciprofloxacin. As a foundation for its risk assessment model, CVM proposed a dramatically simple approach that skipped many of the steps in traditional risk assessment. The basic idea was to assume that human health risks were directly proportional to some suitably defined exposure metric. In symbols: Risk = K × Exposure, where “Exposure” would be defined in terms of a metric such as total production of chicken contaminated with fluoroquinolone-resistant bacteria that might cause human illnesses, and “Risk” would describe the expected number of cases per year of human illness due to fluoroquinolone-resistant bacterial infections caused by chicken and treated with fluoroquinolones.

Published
2006

47. Exact Solution of the Capacitated Vehicle Routing Problem

Author

Daniele Vigo, Paolo Toth, Roberto Baldacci, JAMES J. COCHRAN, LOUIS ANTHONY COX, JR., PINAR KESKINOCAK, JEFFREY P. KHAROUFEH, J. COLE SMITH, R. Baldacci, P.Toth, and D. Vigo

Subjects
Optimal design, Class (computer programming), Engineering, Mathematical optimization, business.industry, capacitated vehicle routing, Travelling salesman problem, Set (abstract data type), Constraint (information theory), Exact solutions in general relativity, Vehicle routing problem, exact method, survey, Routing (electronic design automation), business
Abstract

This multi-volume encyclopedia is organized alphabetically and contains four levels of articles (Introductory, Advanced, Technical, and Case Studies/Historical Interludes) designed to make its content useful and accessible to the widest possible readership. Introductory articles provide a broad and moderately technical treatment of core topics at a level suitable for advanced undergraduate students as well as scientists without a strong background in the field. Advanced articles, aimed at graduate students and researchers, review key areas of research in a citation-rich format similar to that of leading review journals. Technical articles, written as "breakouts" from the advanced articles, provide more detailed discussions of key concepts addressed in the reviews. Case studies/biographical sketches/historical interludes provide an opportunity to present successful and/or interesting examples of operations research/management science methodology in practice or in historical contexts. These articles are less technical in nature and aimed primarily at graduate students and practicing researchers. EORMS has also been developed as a dynamic online resource, combining the most useful features of traditional reference works and review journals in a compelling format designed to exploit the full potential of the online medium. Extensive linking to the primary literature and to other online resources such as the Wiley Encyclopedia of Statistical Sciences, Second Edition further enhances the value of EORMS as a gateway to broader scientific literature. The editorial approach and structure of EORMS ensures the longevity of its content.

Published
2011
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