Center For Alternatives To Animal Testing Research Articles

The Implementation Moonshot Project for Alternative Chemical Testing (IMPACT) toward a Human Exposome Project.

The Human Exposome Project aims to revolutionize our understanding of how environmental exposures affect human health by systematically cataloging and analyzing the myriad exposures individuals encounter throughout their lives. This initiative draws a parallel with the Human Genome Project, expanding the focus from genetic factors to the dynamic and complex nature of environ-mental interactions. The project leverages advanced methodologies such as omics technologies, biomonitoring, microphysiological systems (MPS), and artificial intelligence (AI), forming the foun-dation of exposome intelligence (EI) to integrate and interpret vast datasets. Key objectives include identifying exposure-disease links, prioritizing hazardous chemicals, enhancing public health and regulatory policies, and reducing reliance on animal testing. The Implementation Moonshot Project for Alternative Chemical Testing (IMPACT), spearheaded by the Center for Alternatives to Animal Testing (CAAT), is a new element in this endeavor, driving the creation of a public-private part-nership toward a Human Exposome Project with a stakeholder forum in 2025. Establishing robust infrastructure, fostering interdisciplinary collaborations, and ensuring quality assurance through sys-tematic reviews and evidence-based frameworks are crucial for the project's success. The expected outcomes promise transformative advancements in precision public health, disease prevention, and a more ethical approach to toxicology. This paper outlines the strategic imperatives, challenges, and opportunities that lie ahead, calling on stakeholders to support and participate in this landmark initiative for a healthier, more sustainable future.

The Implementation Moonshot Project for Alternative Chemical Testing (IMPACT) toward a Human Exposome Project.

The Human Exposome Project aims to revolutionize our understanding of how environmental exposures affect human health by systematically cataloging and analyzing the myriad exposures individuals encounter throughout their lives. This initiative draws a parallel with the Human Genome Project, expanding the focus from genetic factors to the dynamic and complex nature of environ-mental interactions. The project leverages advanced methodologies such as omics technologies, biomonitoring, microphysiological systems (MPS), and artificial intelligence (AI), forming the foun-dation of exposome intelligence (EI) to integrate and interpret vast datasets. Key objectives include identifying exposure-disease links, prioritizing hazardous chemicals, enhancing public health and regulatory policies, and reducing reliance on animal testing. The Implementation Moonshot Project for Alternative Chemical Testing (IMPACT), spearheaded by the Center for Alternatives to Animal Testing (CAAT), is a new element in this endeavor, driving the creation of a public-private part-nership toward a Human Exposome Project with a stakeholder forum in 2025. Establishing robust infrastructure, fostering interdisciplinary collaborations, and ensuring quality assurance through sys-tematic reviews and evidence-based frameworks are crucial for the project's success. The expected outcomes promise transformative advancements in precision public health, disease prevention, and a more ethical approach to toxicology. This paper outlines the strategic imperatives, challenges, and opportunities that lie ahead, calling on stakeholders to support and participate in this landmark initiative for a healthier, more sustainable future.

Trust your gut: Establishing confidence in gastrointestinal models - An overview of the state of the science and contexts of use.

The webinar series and workshop titled “Trust Your Gut: Establishing Confidence in Gastrointestinal Models – An Overview of the State of the Science and Contexts of Use” was co-organized by NICEATM, NIEHS, FDA, EPA, CPSC, DoD, and the Johns Hopkins Center for Alternatives to Animal Testing (CAAT) and hosted at the National Institutes of Health in Bethesda, MD, USA on October 11-12, 2023. New approach methods (NAMs) for assessing issues of gastrointestinal tract (GIT)- related toxicity offer promise in addressing some of the limitations associated with animal-based assessments. GIT NAMs vary in complexity, from two-dimensional monolayer cell line-based systems to sophisticated 3-dimensional organoid systems derived from human primary cells. Despite advances in GIT NAMs, challenges remain in fully replicating the complex interactions and pro­cesses occurring within the human GIT. Presentations and discussions addressed regulatory needs, challenges, and innovations in incorporating NAMs into risk assessment frameworks; explored the state of the science in using NAMs for evaluating systemic toxicity, understanding absorption and pharmacokinetics, evaluating GIT toxicity, and assessing potential allergenicity; and discussed strengths, limitations, and data gaps of GIT NAMs as well as steps needed to establish confidence in these models for use in the regulatory setting.

60 Years of the 3Rs symposium: Lessons learned and the road ahead.

When The Principles of Humane Experimental Technique was published in 1959, authors William Russell and Rex Burch had a modest goal: to make researchers think about what they were doing in the laboratory - and to do it more humanely. Sixty years later, their groundbreaking book was celebrated for inspiring a revolution in science and launching a new field: The 3Rs of alternatives to animal experimentation. On November 22, 2019, some pioneering and leading scientists and researchers in the field gathered at the Johns Hopkins Bloomberg School of Public Health in Bal-timore for the 60 Years of the 3Rs Symposium: Lessons Learned and the Road Ahead. The event was sponsored by the Johns Hopkins Center for Alternatives to Animal Testing (CAAT), the Foundation for Chemistry Research and Initiatives, the Alternative Research & Development Foundation (ARDF), the American Cleaning Institute (ACI), the International Fragrance Association (IFRA), the Institute for In Vitro Sciences (IIVS), John "Jack" R. Fowle III, and the Society of Toxicology (SoT). Fourteen pres-entations shared the history behind the groundbreaking publication, international efforts to achieve its aims, stumbling blocks to progress, as well as remarkable achievements. The day was a tribute to Russell and Burch, and a testament to what is possible when people from many walks of life - science, government, and industry - work toward a common goal.

Perspectives on In Vitro to In Vivo Extrapolations.

Quantitative in vitro to in vivo extrapolation (QIVIVE) is broadly considered a prerequisite bridge from in vitro findings to a dose paradigm. Quality and relevance of cell systems are the first prerequisite for QIVIVE. Information-rich and mechanistic endpoints (biomarkers) improve extrapolations, but a sophisticated endpoint does not make a bad cell model a good one. The next need is reverse toxicokinetics (TK), which estimates the dose necessary to reach a tissue concentration that is active in vitro. The Johns Hopkins Center for Alternatives to Animal Testing (CAAT) has created a roadmap for animal-free systemic toxicity testing, in which the needs and opportunities for TK are elaborated, in the context of different systemic toxicities. The report was discussed at two stakeholder forums in Brussels in 2012 and in Washington in 2013; the key recommendations are summarized herein. Contrary to common belief and the Paracelsus paradigm of everything is toxic, the majority of industrial chemicals do not exhibit toxicity. Strengthening the credibility of negative results of alternative approaches for hazard identification, therefore, avoids the need for QIVIVE. Here, especially the combination of methods in integrated testing strategies is most promising. Two further but very different approaches aim to overcome the problem of modeling in vivo complexity: The human-on-a-chip movement aims to reproduce large parts of living organism's complexity via microphysiological systems, that is, organ equivalents combined by microfluidics. At the same time, the Toxicity Testing in the 21st Century (Tox-21c) movement aims for mechanistic approaches (adverse outcome pathways as promoted by Organisation for Economic Co-operation and Development (OECD) or pathways of toxicity in the Human Toxome Project) for high-throughput screening, biological phenotyping, and ultimately a systems toxicology approach through integration with computer modeling. These 21st century approaches also require 21st century validation, for example, by evidence-based toxicology. Ultimately, QIVIVE is a prerequisite for extrapolating Tox-21c such approaches to human risk assessment.

A History of the Johns Hopkins Center for Alternatives to Animal Testing (CAAT): The First 28 Years (1981–2009)

A History of the Johns Hopkins Center for Alternatives to Animal Testing (CAAT): The First 28 Years (1981–2009)

Tox21 to Date: Steps toward Modernizing Human Hazard Characterization

A new review in EHP describes the first phase of the federal government’s Tox21 collaboration, which is attempting to establish alternatives to the time-consuming and expensive animal testing used to evaluate chemical toxicity.1 The review details important strides investigators have made in demonstrating the usefulness of high-throughput data for identifying potential hazards and prioritizing chemicals for more extensive testing. In the long run, the program may help “protect people from exposure to a much greater number of harmful chemicals than is possible based on current testing methods,” says lead author Raymond Tice, chief of the Biomolecular Screening Branch of the NIEHS’s National Toxicology Program (NTP) Division. Officially begun five years ago, Tox21 is an outgrowth of U.S. federal interagency collaborations initiated in 2005 to explore the utility of a high-throughput screening program. It includes scientists at NTP and other NIH entities as well as the Environmental Protection Agency’s (EPA) National Center for Computational Toxicology. In 2010 the Food and Drug Administration (FDA) joined Tox21, but the new report focuses mainly on the efforts of the original Tox21 partners. “At the moment, I think Tox21 is clearly the most important effort to revamp toxicology,” says Thomas Hartung, who directs the Center for Alternatives to Animal Testing (CAAT), part of the Johns Hopkins Bloomberg School of Public Health. He considers the number of substances included, the quality assurance applied, and the public availability of data from Tox21 unique. Tox21 mainly uses cell-based and biochemical in vitro tests, although some testing is conducted with lower animals such as Danio rerio (zebrafish) and Caenorhabditis elegans (a nematode species). In the first phase of testing at the NIH Chemical Genomics Center, scientists screened up to 2,800 compounds with about 70 high-throughput assays.1 Tice points out that the number of compounds screened is relatively small from the perspective of the tens of thousands that need screening. But he says this number was adequate to demonstrate the utility of the approach and to identify assay-specific limitations. Phase I focused on evaluating how assays performed and the extent to which they could be optimized. The percentage of compounds classified as active by the assays ranged from 0.07% for an epigenetics cell-based assay to 41% for an assay that tested the ability of compounds to interact with the cytochrome P450 enzyme CYP1A2, which is involved in the metabolism of foreign substances.1 Phase I of Tox21 has provided insight into possible ways of optimizing highthroughput screening. Lorenz Rhomberg, a principal for the environmental consulting firm Gradient, says he believes the review is most important for describing the limitations of Tox21’s first phase, especially the fact that although thousands of chemicals can be screened in a single assay, it is difficult to interpret the patterns of changes in terms of particular pathways of toxicity generation. In addition, Rhomberg says, the chosen assays may not cover all the toxicological outcomes of potential concern that are currently evaluated in whole-animal studies. Problems identified during Phase I are being addressed in Phase II, which is now in full swing. According to the authors, the primary limitation of Tox21’s quantitative high-throughput testing in Phase I was that the biological output of each of the assays currently used was generally limited to one or two “signals” (measurable responses). Investigators have begun developing cell-based assays with hundreds to thousands of signals. And because Tice and his colleagues discovered that some of the compounds they purchased for testing had inaccurate information on their certificates of analysis or were unstable during storage and use, Phase II includes analysis of test chemicals for identity, purity, and stability. Another issue that came to light was what Tice calls “compound carryover”—some compounds can be transferred from one set of plates to another by the pin tools used in the quantitative high-throughput screening system. To compensate for this problem, the investigators are screening each substance at least three times in Phase II, changing the compounds’ well locations in each run. Another important limitation that Tice and his colleagues are trying to remedy for Tox21’s next phase is the inability of most cell lines to mimic in vivo metabolism of chemicals, which can produce intermediates that are more biologically active than the parent compound. Because the liver is the primary site where such reactive intermediates are metabolized, the Tox21 researchers are investigating whether cells with hepatocyte functionality can be used to assess a chemical’s ability to interact with multiple cellular pathways. The investigators stress that they still face many obstacles before they can definitively show that Tox21 will indeed transform toxicity testing. But they nonetheless believe the data and information they are obtaining is “foretelling the future of toxicology.”

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To address the pressing need for better in vitro testicular toxicity models, a workshop sponsored by the International Life Sciences Institute (ILSI), the Health and Environmental Science Institute (HESI), and the Johns Hopkins Center for Alternatives to Animal Testing (CAAT), was held at the Mt. Washington Conference Center in Baltimore, MD, USA on October 26-27, 2011. At this workshop, experts in testis physiology, toxicology, and tissue engineering discussed approaches for creating improved in vitro environments that would be more conducive to maintaining spermatogenesis and steroidogenesis and could provide more predictive models for testicular toxicity testing. This workshop report is intended to provide scientists with a broad overview of relevant testicular toxicity literature and to suggest opportunities where bioengineering principles and techniques could be used to build improved in vitro testicular models for safety evaluation. Tissue engineering techniques could, conceivably, be immediately implemented to improve existing models. However, it is likely that in vitro testis models that use single or multiple cell types will be needed to address such endpoints as accurate prediction of chemically induced testicular toxicity in humans, elucidation of mechanisms of toxicity, and identification of possible biomarkers of testicular toxicity.

Meeting Report: Alternatives for Developmental Neurotoxicity Testing

Developmental neurotoxicity testing (DNT) is perceived by many stakeholders to be an area in critical need of alternatives to current animal testing protocols and guidelines. To address this need, the Johns Hopkins Center for Alternatives to Animal Testing (CAAT), the U.S. Environmental Protection Agency, and the National Toxicology Program are collaborating in a program called TestSmart DNT, the goals of which are to: (a) develop alternative methodologies for identifying and prioritizing chemicals and exposures that may cause developmental neurotoxicity in humans; (b) develop the policies for incorporating DNT alternatives into regulatory decision making; and (c) identify opportunities for reducing, refining, or replacing the use of animals in DNT. The first TestSmart DNT workshop was an open registration meeting held 13–15 March 2006 in Reston, Virginia. The primary objective was to bring together stakeholders (test developers, test users, regulators, and advocates for children’s health, animal welfare, and environmental health) and individuals representing diverse disciplines (developmental neurobiology, toxicology, policy, and regulatory science) from around the world to share information and concerns relating to the science and policy of DNT. Individual presentations are available at the CAAT TestSmart website. This report provides a synthesis of workgroup discussions and recommendations for future directions and priorities, which include initiating a systematic evaluation of alternative models and technologies, developing a framework for the creation of an open database to catalog DNT data, and devising a strategy for harmonizing the validation process across international jurisdictional borders.

The Three Rs and Biomedical Research

The authors are at the Johns Hopkins Center for Alternatives to Animal Testing (CAAT), Johns Hopkins School of Public Health, 111 Market Place, Suite 840, Baltimore, MD 21202-6709, USA. E-mail: caat@caat.spharbor.jhu.edu In 1959, British scientists William M. S. Russell and Rex L. Burch wrote that scientific excellence and humane use of laboratory animals are inextricably linked. In The Principles of Humane Experimental Technique,* they described the “three Rs”—reduction, refinement, and replacement—of animal use in the life sciences, concepts now known as “alternatives.” Legislation mandating the incorporation of the three Rs into animal research and testing has been passed in the United States and Europe. Because some scientists view discussion of alternatives as driven exclusively by political and social forces rather than by scientific considerations, an international group of scientists prominent in the alternatives field met at a May 1995 workshop to reaffirm the scientific basis of the three Rs and to discuss how these concepts can best be disseminated to the scientific community.† Published surveys of the scientific literature have found inefficient use of animals due to poor experimental design or inappropriate statistical analysis of results or both. Reduction alternatives allow comparable amounts of data to be obtained from fewer animals or more information to be obtained from a given number of animals. The number of animals used should be the minimum necessary to test the experimental hypothesis and give statistically usable results. Refinement alternatives are methods that eliminate or minimize pain and distress or enhance animal well-being. Assessments of animal pain and distress are currently based on subjective evaluation of abnormal behavior and appearance. Because proper evaluation of pain relies largely on the ability to understand the behavior and needs of each species of laboratory animal, it is best for investigators to assume that a procedure that inflicts pain and distress on humans will inflict pain and distress on animals. Much pain and distress can be diminished or eliminated with the proper use of anesthetics and analgesics. Researchers can enhance animals9 well-being by using environmental enrichment techniques, such as proper handling, appropriately sized cages, and group housing of social species. Replacement alternatives are methods that use organisms with limited sentience or that do not use whole animals. They include improved information exchange to avoid unnecessary repetition of animal experiments; physicochemical techniques and structure-activity relations; mathematical and computer models; use of invertebrates, plants, and microorganisms; in vitro methods; and human studies, including the use of human volunteers, postmarketing surveys, and epidemiology. In the biomedical sciences, in vitro methods are increasingly being used, not because they provide precisely the same information as do animal studies but because they offer the best scientific approach. Such methods often use results from past animal studies as a basis for cellular and molecular investigations. Successful implementation of the three Rs requires that scientists and technicians be formally trained to scientifically and ethically evaluate the use of laboratory animals and to perform animal experiments that meet the highest scientific and animal welfare standards. Coursework should be included in graduate training programs and should focus on strengthening the principles of experimental design and teaching competence in animal handling, how to make ethical decisions about using animals in experiments, and how to find alternative methods. As the participants at the workshop concluded, present and future scientists should be encouraged to view the three Rs as an intellectual challenge and an opportunity to enhance the scientific, economic, and ethical value of their research.

Validation: A highly charged concept

In order that a proposal for an alternative to an animal test be developed as an internationally accepted guideline, there needs to be consensus on the validity of the method proposed. Over the years, considerable attempts have been made to ‘validate’ promising alternatives. Probably without exception, these validation programmes demanded considerable budgets whereas the high expectations as to the output, which would justify the costs involved, were hardly ever met. What went wrong? Obviously, as for each new animal test, each new alternative to an animal test should be subjected to a critical appraisal procedure involving its scientific justification, its sensitivity and its reproducibility, before it could be internationally acceptable. Although there may be differences of opinion on the extent of this exercise, there is considerable agreement that validation in one way or another is essential. None the less, validation programmes so far have not resulted in the broad acceptance of any alternative test method. There may be two reasons for this failure. First, the results of the validation studies may have been unsatisfactory, which could mean that either the method subjected to validation failed to show the desired relevance and reliability, or the validation study as such yielded inconclusive results. Secondly, despite clear-cut (supporting) results from the validation exercise, toxicologists/regulators appear reluctant actually to use the data provided for hazard and risk assessment procedures because of a lack of confidence with the (types of) endpoints of the new test. The latter in particular can be considered a major hurdle in the process of acceptance of alternative tests. Therefore, an independent and objective review of any new test, with a view to its usefulness as a contribution to the set of data essential for hazard characterization and risk assessment, should be considered the first step of any comprehensive validation project. Further, the establishment of international centres such as the Johns Hopkins Center for Alternatives to Animal Testing (CAAT) and the European Centre for the Validation of Alternative Methods (ECVAM) where scientists, including regulators, can meet and discuss strategies not only for validation but also for the use of alternative methods in risk assessment, is considered essential for a good understanding of the relevance of the new in vitro, toxicity tests.

Revlon, others end tests of products on animals

Revlon announced late last month that it will eliminate all use of animal testing in research, development, and production of its products. The New York City firm thus becomes the fourth U.S. cosmetics company to end such testing in recent weeks. Avon Products and Amway Corp. had made similar announcements last month, whereas Mary Kay Cosmetics declared its decision to halt such testing in May. The companies will use a combination of in-vitro tests, clinical testing with humans, and their databases of previous testing on formulations and ingredients to evaluate product safety and irritant potential. Development and validation of such test programs resulted from an eight-year, $3 million effort funded by the Cosmetic Toiletry & Fragrance Association and its member companies at Johns Hopkins University Center for Alternatives to Animal Testing (CAAT) in Baltimore. Perhaps the most emotionally charged animal test for cosmetics irritation has been the Draize test. In that test, technicians apply a ...