Meeting report: alternatives for developmental neurotoxicity testing.Developmental neurotoxicity neurotoxicity /neu·ro·tox·ic·i·ty/ (noor?o-tok-sis´it-e) the quality of exerting a destructive or poisonous effect upon nerve tissue. testing (DNT DNT Document & Network Technologies DNT Dinitrotoluene DNT Dynamic Network Technologies DNT Do Not Type DNT Dodonu Ni Taukei Party (Fiji political party) DNT Do Not Touch DNT Dialed Number Trigger DNT Do Not Translate ) is perceived by many stakeholders Stakeholders All parties that have an interest, financial or otherwise, in a firm-stockholders, creditors, bondholders, employees, customers, management, the community, and the government. to be an area in critical need of alternatives to current animal testing Animal testing or animal research refers to the use of animals in experiments. It is estimated that 50 to 100 million vertebrate animals worldwide [4][5][6] protocols and guidelines. To address this need, the Johns Hopkins Noun 1. Johns Hopkins - United States financier and philanthropist who left money to found the university and hospital that bear his name in Baltimore (1795-1873) Hopkins 2. Center for Alternatives to Animal Testing The Johns Hopkins University Center for Alternatives to Animal Testing (CAAT) [1] has worked with scientists since 1981 to find new methods to replace the use of laboratory animals in experiments, reduce the number of animals tested, and refine necessary tests to (CAAT CAAT Campaign Against Arms Trade (UK) CAAT Center for Alternatives to Animal Testing (Johns Hopkins School of Hygiene and Public Health) CAAT College of Applied Arts and Technology ), the U.S. Environmental Protection Agency Environmental Protection Agency (EPA), independent agency of the U.S. government, with headquarters in Washington, D.C. It was established in 1970 to reduce and control air and water pollution, noise pollution, and radiation and to ensure the safe handling and , and the National Toxicology Program National Toxicology Program Environment A program that conducts toxicologic tests on substances frequently found at the EPA's National Priorities List sites, which have the greatest potential for human exposure 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 Reston is an internationally known planned community whose goal was to revolutionize post-World War II concepts of land use and residential/corporate development in American suburbia. . The primary objective was to bring together stakeholders (test developers, test users, regulators, and advocates for children's health Children's Health Definition Children's health encompasses the physical, mental, emotional, and social well-being of children from infancy through adolescence. , animal welfare, and environmental health) and individuals representing diverse disciplines (developmental neurobiology Neurobiology Study of the development and function of the nervous system, with emphasis on how nerve cells generate and control behavior. The major goal of neurobiology is to explain at the molecular level how nerve cells differentiate and develop their , toxicology, policy, and regulatory science) from around the world to share information and concerns relating to relating to relate prep → concernant relating to relate prep → bezüglich +gen, mit Bezug auf +acc 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. Key words: alternatives, developmental neurotoxicity testing, humane science, in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. models, policy, regulatory acceptance, screening, TestSmart, the 3Rs, validation. Environ Health Perspect 115:764-768 (2007). doi:10.1289/ehp.9841 available via http://dx.doi.org/ [Online 29 January 2007] Background There is considerable concern that chemical exposures are contributing to the increasing incidence of neurodevelopmental diseases in children (Schettler 2001). However, most chemicals have not been evaluated for their potential to cause developmental neurotoxicity (Goldman and Koduru 2000). To fill this information gap, industry is increasingly being asked to provide adequate information for the assessment of developmental neurotoxicity in its products and wastes. In response, developmental neurotoxicity testing (DNT) needs are expected to increase significantly in the United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. and globally. Current DNT testing guidelines, U.S. Environmental Protection Agency (EPA EPA eicosapentaenoic acid. EPA abbr. eicosapentaenoic acid EPA, n.pr See acid, eicosapentaenoic. EPA, n. ) 870.6300 DNT Guideline (U.S. EPA 1998) and the draft OECD OECD: see Organization for Economic Cooperation and Development. 426 [Organisation for Economic Co-operation and Development The Organisation for Economic Co-operation and Development (OECD), (in French: Organisation de coopération et de développement économiques; OCDE) is an international organisation of thirty countries that accept the principles of representative democracy and a free market (OECD) 2006] are expensive in terms of scientific resources, time, money, and animals (Lein et al. 2005), and risk-based criteria for setting testing priorities have yet to be developed. Relying solely on the existing guidelines to address current and anticipated future regulatory demands for DNT of the thousands of chemicals for which there is little to no DNT data would incur unacceptable costs in terms of animals and person-years. There is also increasing pressure on the scientific and regulatory communities from environmental health and children's welfare advocacy groups to test more chemicals for their potential to harm the developing human nervous system. Thus, there is strong incentive to create alternative methodologies that meet the expressed demands for identifying potential developmental neurotoxic neurotoxic pertaining to or emanating from a neurotoxin. neurotoxic state a case of poisoning by a neurotoxin. neurotoxic adjective agents with speed, reliability, and respect for animal welfare. The Johns Hopkins Center for Alternatives to Animal Testing (CAAT) introduced its first TestSmart program in 1999 to develop a more humane and efficient approach to risk assessment of high production volume (HPV HPV human papillomavirus. HPV abbr. human papilloma virus Human papilloma virus (HPV) ) chemicals. The TestSmart process brings together diverse stakeholder stakeholder n. a person having in his/her possession (holding) money or property in which he/she has no interest, right or title, awaiting the outcome of a dispute between two or more claimants to the money or property. groups from around the world, including research scientists, government scientists, regulators, policy analysts, industry representatives, academics, and public interest groups, encouraging them to work collaboratively so that as the science is developed, its policy implications will be understood, and, as policy needs are articulated, the science can respond. After the TestSmart HPV workshop (26-27 April 1999, Fairfax, VA, the U.S. EPA announced it had decreased its estimates for animal use by 80%. This estimate was based partly on the TestSmart HPV recommendation that the OECD combine required assays and, where possible, replace in vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. tests with in vitro OECD assays. These data are available from this website: http://caat.jhsph.edu/programs/workshops/testsmart/index.htm (CAAT 2007). Building on the success of this program, CAAT is collaborating with the U.S. EPA and the National Toxicology Program (NTP (Network Time Protocol) A TCP/IP protocol used to synchronize the real time clock in computers, network devices and other electronic equipment that is time sensitive. It is also used to maintain the correct time in NTP-based wall and desk clocks. ) to adapt the TestSmart approach to DNT. The goals of TestSmart DNT are to a) identify alternative DNT models based on evolutionarily conserved neurodevelopmental end points of mechanistic relevance to developmental neurotoxicity; b) develop the process for validating candidate alternative methods both scientifically and in terms of regulatory acceptance; and c) identify opportunities for reducing, refining, or replacing the use of animals in DNT. These goals were derived in part from a workshop sponsored by the CAAT, the European Chemical Industry Council (Cefic), and the European Center for the Validation of Alternative Methods (ECVAM ECVAM European Centre for the Validation of Alternative Methods ) in April 2005 in Ispra, Italy, which examined the current status of alternatives for DNT testing. A report of this workshop (Coecke et al. 2007) has been published online by Environmental Health Perspectives. Workshop Objectives The primary objective of the first international meeting of TestSmart DNT was to bring together the various 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) to exchange information and concerns relating to DNT science and policy. Additionally, the workshop sought to: (a) outline the opportunities for and challenges of DNT alternatives; (b) initiate dialogue on policy requirements for validating candidate alternatives; (c) discuss the 3Rs (refining, reducing, and replacing the use of animals) as they apply to DNT; (d) establish a community of scientists and policy makers who will work together to integrate and coordinate the science and policy of alternative DNT as it evolves; and (e) set the agenda for the second TestSmart DNT meeting (12-14 November 2006, Reston, VA). Workshop Summary: Challenges and Opportunities The science of DNT. Strategic approach to developing DNT alternatives. A fundamental scientific principle that has driven the successful development of alternatives for toxicity testing in organ systems is that highly conserved events in the biology of a system or a process provide a robust source of new efficient methods in target organ target organ n. A tissue or organ that is affected by a specific hormone. target organ, n the organ or body part whose activity levels demonstrate change in the course of biofeedback. testing (Lein et al. 2005). For example, the predictive power The predictive power of a scientific theory refers to its ability to generate testable predictions. Theories with strong predictive power are highly valued, because the predictions can often encourage the falsification of the theory. of in vitro mutagenesis mutagenesis /mu·ta·gen·e·sis/ (mu?tah-jen´e-sis) 1. the production of change. 2. the induction of genetic mutation. mu·ta·gen·e·sis n. pl. tests as screens for genotoxic genotoxic /ge·no·tox·ic/ (je´no-tok?sik) damaging to DNA: pertaining to agents known to damage DNA, thereby causing mutations, which can result in cancer. ge·no·tox·ic adj. agents results from their incorporation of a relevant biologic mechanism (DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. mutation) that is conserved across species. Applying this principle to developing alternatives for DNT is challenging because the molecular mechanism(s) by which developmental neurotoxicants perturb neurodevelopment are not well characterized. Moreover, because of the complexity of the developing brain, it is likely that there are many molecular mechanisms of developmental neurotoxicity, a conclusion borne out by mechanistic studies of neurodevelopmental diseases. However, significant advances in our understanding of the cellular and molecular mechanisms of neurodevelopment over the past 10 years have identified and characterized key cellular events that are critical to the formation of a functional nervous system. These include neural induction, precursor cell proliferation, pattern formation, cell migration, neuronal and glial glial /gli·al/ (gli´'l) of or pertaining to the neuroglia. glial of or pertaining to glia or neuroglia. glial limitans a dense network of glial processes at the pia mater. differentiation, formation of axons and dendrites, axonal axonal pertaining to or arising from an axon. axonal degeneration an axon dies and cannot be replaced if its cell body is destroyed. guidance and target recognition, cell survival and apoptosis, synapse synapse (sĭn`ăps), junction between various signal-transmitter cells, either between two neurons or between a neuron and a muscle or gland. A nerve impulse reaches the synapse through the axon, or transmitting end, of a nerve cell, or neuron. formation and pruning, and neurotransmitter neurotransmitter, chemical that transmits information across the junction (synapse) that separates one nerve cell (neuron) from another nerve cell or a muscle. Neurotransmitters are stored in the nerve cell's bulbous end (axon). specification. It is now clear that the fundamental principles underlying these cellular events of neurodevelopment are remarkably conserved across species ranging from the nematode nematode or roundworm Any of more than 15,000 named and many more unnamed species of worms in the class Nematoda (phylum Aschelminthes). Nematodes include plant and animal parasites and free-living forms found in soil, freshwater, saltwater, and even vinegar (Caenorhabditis elegans Caenorhabditis elegans (IPA: [ˌsiːnəʊræbˈdaɪtɪs ˈelegænz]) is a free-living nematode (roundworm), about 1 mm in length, which lives in temperate soil environments. ) to human. These advances provide the opportunity to develop DNT alternatives focused on end points that capture key evolutionarily conserved neurodevelopmental events. This strategy is based on the prevailing thought in the field that many developmental neurotoxicants, regardless of their actual mechanism of action, share common final outcomes of altered cell proliferation and survival, aberrant aberrant /ab·er·rant/ (ah-ber´ant) (ab´ur-ant) wandering or deviating from the usual or normal course. ab·er·rant adj. 1. cell differentiation Cell differentiation The mechanism by which cells in a multicellular organism become specialized to perform specific functions in a variety of tissues and organs. Specialized cells are the product of differentiation. , or disrupted neuronal connectivity (Barone et al. 2000; Lein et al. 2005; Slotkin 2004). The relevance of these end points to developmental neurotoxicity is further supported by clinical studies of children and experimental studies in primates, rodents, and simpler organisms, indicating that perturbation perturbation (pŭr'tərbā`shən), in astronomy and physics, small force or other influence that modifies the otherwise simple motion of some object. The term is also used for the effect produced by the perturbation, e.g. of these key neurodevelopmental events underlies functional deficits associated with neurodevelopmental diseases of environmental and/or genetic origin (Rice and Barone 2000). In vitro models and DNT. In vitro cell-based models that recapitulate re·ca·pit·u·late v. re·ca·pit·u·lat·ed, re·ca·pit·u·lat·ing, re·ca·pit·u·lates v.tr. 1. To repeat in concise form. 2. each of the neurodevelopmental events listed above have been developed to examine cellular and molecular mechanisms of neurodevelopment. These models, listed in order of increasing complexity, include neurotypic and gliotypic cell lines, primary neuronal and/or glial cell gli·al cell n. Any of the cells making up the neuroglia, especially the astrocytes, oligodendroglia, and microglia. cultures, reaggregate brain cultures, brain slices, and organotypic explants. End points that can be measured in these models include cellular morphology, biochemical markers, neurotransmission Neurotransmission When a neurotransmitter, or chemical agent released by a particular brain cell, travels across the synapse to act on the target cell to either inhibit or excite it. , and molecular events (e.g., gene expression and intracellular signaling). There is considerable ongoing effort to develop the technology for high(er) throughput/high(er) content analyses of these end points. More complex in vitro models, such as brain slices, have also been adapted to study functional correlates of complex behaviors, such as long-term potentiation In neuroscience, long-term potentiation (LTP) is the long-lasting improvement in communication between two neurons that results from stimulating them simultaneously. and synaptic plasticity synaptic plasticity Physiology Malleability present in synapses in various forms–eg, presynaptic inhibition, homosynaptic depression, presynaptic facilitation and modulation of transmitter release by tonic depolarization of sensory neuron. . Most of the primary cell culture models use tissues from avian or rodent sources; however, of particular interest to DNT is the availability of human embryonic stem cells Embryonic stem cells (ES cells) are stem cells derived from the inner cell mass of an early stage embryo known as a blastocyst. Human embryos reach the blastocyst stage 4-5 days post fertilization, at which time they consist of 50-150 cells. ES cells are pluripotent. for culture. Human neural progenitor cells, human stem cell lines, and human cord blood-derived stem cell stem cell In living organisms, an undifferentiated cell that can produce other cells that eventually make up specialized tissues and organs. There are two major types of stem cells, embryonic and adult. models recapitulate several key neurodevelopmental events, including differentiation of precursor cells into neurons and glia and the formation of neural networks. These models could potentially reduce uncertainty in cross-species extrapolation (mathematics, algorithm) extrapolation - A mathematical procedure which estimates values of a function for certain desired inputs given values for known inputs. If the desired input is outside the range of the known values this is called extrapolation, if it is inside then . The major advantage of in vitro cell-based models is the ability to replicate discrete stages of neurodevelopment in a relatively simple system amenable to monitoring and manipulation of gene expression. Because these models reduce the complexity of the developing nervous system, it is easier to detect subtle but functionally important changes in cell proliferation and differentiation and neuronal connectivity that are not easily observed in rodent models. The availability of technology to monitor or experimentally manipulate gene expression provides the opportunity to integrate molecular data with structural and functional observations at the cellular level and allows adaptation of models to incorporate genetic polymorphisms known or suspected to influence human susceptibility to developmental neurotoxicants. However, adapting in vitro cell-based models for DNT also poses significant challenges. Because developmental neurotoxicity is contextually driven--neurotoxic effects vary depending on brain region, developmental stage, and genetic background--the use of these models raises concerns about missing critical cell-cell or gene-environment interactions as well as differences between brain regions and between developmental stages (Lein et al. 2005). Another limitation of in vitro cell-based models is the lack of integrated systemic functions, which increases the probability of missing toxicant toxicant /tox·i·cant/ (tok´si-kant) 1. poisonous. 2. poison. tox·i·cant n. 1. A poison or poisonous agent. 2. An intoxicant. adj. effects on extraneural factors that influence neurodevelopment, such as metabolism, immune mediators, and endocrine function. Alternative systems-based models and DNT. The complexity of interdependent events in the developing nervous system raises concerns as to whether a DNT test battery based on a few well-defined end points reproduced in vitro using cell-based models will be predictive of in vivo effects. Therefore, systems-based models employing simple organisms that enable assessment of integrative effects may offer a more immediately viable and ultimately more powerful approach to DNT alternatives. Simple organisms that have been proposed as candidate DNT alternatives include (listed in order of increasing evolutionary complexity) sea urchins, nematodes (C. elegans C. elegans A nematode (Caenorhabditis elegans) that lives in soil, feeds on bacteria, and reaches lengths of about 1 mm (0.04 inch). It was the first animal whose genome was completely sequenced, and is widely used as a "model organism" by ), flies (Drosophila Drosophila: see fruit fly. drosophila Any member of about 1,000 species in the dipteran genus Drosophila, commonly known as fruit flies but also called vinegar flies. Some species, particularly D. melanogaster), fish [zebrafish (Danio da·ni·o n. pl. da·ni·os Any of various small, often brightly colored freshwater fishes of the genera Danio and Brachydanio, native to Asia and popular as aquarium fish. rerio) and medaka me·da·ka n. A small Japanese fish (Oryzias latipes) commonly found in rice fields and often used in biological research or in stocking aquariums. (Oryzias latipes Oryzias latipes see medehas. )], and chick embryos. Of these, C. elegans, Drosophila, zebrafish, and chick embryos have been used most extensively in mechanistic studies of developmental neurobiology and there exists a significant knowledge base regarding cellular and molecular regulation of neurodevelopment in these organisms. Such studies demonstrate that although there are notable differences between neurodevelopment in these simpler organisms and mammals, the fundamental processes of neurodevelopment are analogous to those that occur in humans. Moreover, genes homologous homologous /ho·mol·o·gous/ (ho-mol´ah-gus) 1. corresponding in structure, position, origin, etc. 2. allogeneic. ho·mol·o·gous adj. 1. to human genes linked to neurodevelopmental diseases are expressed in these models. The complete genome has been sequenced for C. elegans, Drosophila, zebrafish, and medaka, the technology is in place to monitor and experimentally manipulate gene expression in nematodes, flies, fish, and chick embryos, and some behavioral tests have been developed for these models. Thus, tools are available to integrate developmental neurotoxicity studies at the biochemical, molecular, and cellular level with alterations in structure, function, and behavior. This will allow direct testing of cause-effect relationships between toxicant effects on biochemical, cellular, or molecular end points and effects on apical apical /ap·i·cal/ (ap´i-k'l) pertaining to an apex. a·pi·cal adj. 1. Relating to the apex of a pyramidal or pointed structure. 2. measures such as behavior. In addition, this information could be used to construct a genomics/proteomics database for predicting developmental neurotoxic potential across species at the most fundamental level of homology homology (hōmŏl`əjē), in biology, the correspondence between structures of different species that is attributable to their evolutionary descent from a common ancestor. . Ongoing studies are focused on developing the technology to adapt these systems-based in vivo models for high(er) throughput/high(er) content analyses of genomic, proteomic, structural, biochemical, and behavioral end points. A significant advantage of all these organisms is their small size, rapid embryonic development, and short life cycle, which will greatly reduce time and space costs. Zebrafish and medaka offer an advantage relative to the other models in that their embryos are optically transparent. Thus, it is possible to visualize dynamic changes in gene expression (using fluorescent reporter transgenic lines) and detailed morphogenetic movements as they occur in the live developing embryo. This provides the opportunity to study compensatory mechanisms compensatory mechanisms Cardiac pacing Physiologic responsiveness of cardiovascular system whereby it changes its function and characteristics to ↑ or ↓ cardiac output. See Cardiac output. in developing nervous systems exposed to neurotoxicants, and to obtain repeated measures in the same organism over time, thereby reducing the number of animals required for testing. A major challenge confronting all in vivo systems-based DNT alternatives is determining the impact of potential species-specific toxicokinetic and toxicodynamic differences. How similar are xenobiotic xen·o·bi·ot·ic adj. Foreign to the body or to living organisms. Used of chemical compounds. n. A xenobiotic chemical. xenobiotic any substance, harmful or not, that is foreign to the animal's biological system. metabolism and cellular defense mechanisms in these organisms to those of humans? However, the technology exists to "humanize hu·man·ize tr.v. hu·man·ized, hu·man·iz·ing, hu·man·iz·es 1. To portray or endow with human characteristics or attributes; make human: humanized the puppets with great skill. 2. " these organisms by stably expressing human genes (e.g., metabolic enzymes), so it may be possible to mitigate this problem. Challenges to the development and application of DNT alternatives. Overall, a major challenge, which is driven by limited resources, is determining which of these in vitro cell-based and in vivo systems-based models to further develop as DNT alternatives. One approach is to evaluate each model against a set of characteristics defining the "ideal" DNT alternative. Although these defining characteristics require further discussion and refinement, it is widely accepted that the most important characteristic is that the model is predictive of neurotoxic responses in the developing human nervous system. Employing the strategy discussed above, alternative models for DNT would be based on conserved mechanisms of neurodevelopment. Additional characteristics of an ideal DNT alternative include sensitivity, specificity, and adaptability to high throughput/high content analyses. Other, more practical concerns are that the test be rapid, economical, and relatively simple to perform. These practical concerns are readily addressed for most candidate DNT alternatives, and there is considerable work ongoing to adapt many of these in vitro cell-based and in vivo systems-based models for high(er) throughput/high(er) content analyses. However, in general, there is insufficient data to rigorously evaluate the predictive validity In psychometrics, predictive validity is the extent to which a scale predicts scores on some criterion measure. For example, the validity of a cognitive test for job performance is the correlation between test scores and, for example, supervisor performance ratings. , specificity or sensitivity of either in vitro cell-based or in vivo systems-based DNT alternatives. An immediate need, therefore, is to begin testing candidate models, ideally using a common set of mechanistically diverse developmental neurotoxicants to facilitate comparisons between models. Generating a reference set of chemicals to be used for testing alternative DNT models is another issue demanding immediate attention. An additional consideration is establishing the criteria for assembling a battery of alternative DNT models. For example, what types of data do regulators need, and what model characteristics are required to generate those data? A second major challenge is coordinating the collection, storage, and analyses of DNT data. Ideally, all stakeholders would openly share information regarding alternative DNT model development and testing in a public database. Several issues will need to be addressed to achieve this goal, not least of which is identifying the resources to create and maintain a database. Also relevant to this challenge is determining how best to apply computational toxicology and systems biology Systems biology, a field of study in the biosciences, focuses on the systematic study of complex interactions in biological systems. Particularly from 2000 onwards, the term is used widely in the biosciences, and in a variety of contexts. to integrate structural and functional data with genomic, proteomic, and metabonomic data. The resources and effort required to tackle these challenges are justified by the opportunity for these DNT alternatives to increase the rate of data acquisition while reducing the animal and other costs of DNT, thereby enhancing the ultimate goal of protecting children's health. Data obtained from either in vitro cell-based or in vivo systems-based DNT alternatives may provide insights into relevant cellular, molecular, and regional targets, informing mode-of-action hypotheses and identifying potentially vulnerable developmental stages, thereby refining and reducing mammalian in vivo testing. A short-term goal is to identify DNT alternatives that can be used to prioritize chemicals for further testing, thereby focusing resources on those chemicals most likely to be hazardous to the developing nervous system. Long term, these alternative DNT models have the potential to replace at least some mammalian in vivo testing. Scientific and regulatory validation of alternative DNT models. The interface between developing science and its application to policy can be understood most effectively by discussing validation and regulatory acceptance. These concepts bridge the worlds of test development, laboratory research, and application of new test methods in regulation. A robust, timely, internationally harmonized har·mo·nize v. har·mo·nized, har·mo·niz·ing, har·mo·niz·es v.tr. 1. To bring or come into agreement or harmony. See Synonyms at agree. 2. Music To provide harmony for (a melody). , and effective path to validation and regulatory acceptance is essential for the successful deployment of alternatives in developmental neurotoxicology (Spielmann and Liebsch 2002). Validation: the process. Validation is the process by which the reliability and relevance of a test are established for a particular purpose. In the context of validation, "reliability" refers to the inter- and intralaboratory reproducibility of a methodology [Garthoff 2005; Interagency Coordinating Committee for the Validation of Alternative Methods (ICCVAM ICCVAM Interagency Coordination Committee on the Validation of Alternative Methods ) 1997; Zeigler and Stokes 1998] whereas "relevance" refers to a test's ability to measure, predict, or model a toxicologic event of interest (Zeigler and Stokes 1998). In many cases, an alternative test is judged to be relevant if it produces information and data that are equivalent to or better than the information or data produced by a currently used in vivo test. Simply put, the benchmark for alternative tests is whether they are deemed to be as predictive as (or more predictive than) the tests they are intended to replace (Spielmann and Liebsch 2002). Although the concept of validation is relatively easy to define and describe, in practice it remains challenging to implement for any single test. The process of validation is determined by a variety of factors including: a) the "comfort level" of the individual agencies or organizations that evaluate the test, which is a function of their statutory and regulatory mandate (Zeigler and Stokes 1998); b) influence from pressure groups (Garthoff 2005); and c) the perceived need for a new test protocol. Validation has evolved and improved in the past 15 years. Early lessons, arising out of the first unsuccessful attempts to validate alternative tests to replace the Draize eye procedure (Spielmann and Liebsch 2001), led to success in validating a number of tests, and has witnessed their acceptance by ICCVAM, ECVAM, and other international bodies, such as the OECD. Validation: challenges and opportunities. Despite these successes, test validation remains challenging. First, it is very expensive (Spielmann 2003). Second, it is time consuming, taking 1.5-10 years (Garthoff 2005). Third, validation can require the use of large numbers of animals. Fourth, it can be difficult to find a sponsor or group of sponsors for the test (Spielmann and Liebsch 2002). Finally, as we discuss below, validation in and of itself offers no guarantee (at least in the United States) that the data generated by an alternative test will be accepted for use in decision making by a regulatory body (ICCVAM 1997; Zeigler and Stokes 1998). A specific challenge facing DNT alternatives is that predictive validity is harder to conceptualize con·cep·tu·al·ize v. con·cep·tu·al·ized, con·cep·tu·al·iz·ing, con·cep·tu·al·iz·es v.tr. To form a concept or concepts of, and especially to interpret in a conceptual way: in cases where correlative Having a reciprocal relationship in that the existence of one relationship normally implies the existence of the other. Mother and child, and duty and claim, are correlative terms. in vivo tests have not been established. Biostatistians and modelers can play an important role, and test developers should strongly consider developing predictive models based on statistics and systems biology (Spielmann and Liebsch 2002). The presentations and discussions of the first TestSmart DNT workshop support the proposal that DNT alternatives, appropriately developed, can yield valuable data for decision making (Lein et al. 2005). The rate of throughput is another potential advantage of DNT alternatives over traditional in vivo tests. Alternatives that simultaneously test multiple end points of interest or multiple compounds would rapidly expand the knowledge base of developmental neurotoxicity. Successful use of these alternatives in decision making will require sorting them according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. their long-, medium-, or short-term potential. Regulatory acceptance: the process. Validation of an alternative test is a necessary but not the only step in using the test to make decisions that will affect regulations (Garthoff 2005). Once validated, a test must pass through another process to gain acceptance by regulatory agencies in the United States, the European Union European Union (EU), name given since the ratification (Nov., 1993) of the Treaty of European Union, or Maastricht Treaty, to the European Community , its member countries, and other jurisdictions. Regulatory acceptance is largely an ad hoc For this purpose. Meaning "to this" in Latin, it refers to dealing with special situations as they occur rather than functions that are repeated on a regular basis. See ad hoc query and ad hoc mode. process that varies depending on a) the agencies and jurisdictions involved [e.g., the Centre for the Documentation and Evaluation of Alternative Methods to Animal Experiments (ZEBET ZEBET Zentralstelle zur Erfassung und Bewertung von Ersatz- und Ergänzungsmethoden zum Tierversuch (German Center for Documentation & Evaluation of Alternative Methods to Animals)Experiments ) vs. OECD vs. U.S. EPA]; b) the particular law or regulation for which the testing data will be used; c) the influence of stakeholders, including business groups and advocacy groups for children's health, animal welfare, and the environment; and d) the cultural norms of the jurisdiction that influence the ethics surrounding animal use in testing (Garthoff 2005; Schettler 2001; Spielmann 2003; Zeigler and Stokes 1998). In the United States, regulatory acceptance is determined by each individual agency. The statute that created the ICCVAM specifically separates validation and regulatory acceptance so that an agency may, at its discretion, accept or reject a validated test (ICCVAM Authorization Act 2000). It may also take an intermediate approach and use a validated test under one or more statutes for some purposes but not others (ICCVAM 1997). In the European Union, the journey from validation to regulatory acceptance appears to be less disjointed and more direct. Member countries are free to adopt additional procedures for regulatory acceptance, as are other international organizations or programs [OECD; Registration, Evaluation and Authorization of Chemicals (REACH); and Science, Children, Awareness, Legislation, Evaluation (SCALE)] (Garthoff 2005). Regulatory acceptance: challenges and opportunities. To create incentives to develop alternatives and to maximize the regulatory use of the information generated by alternative tests will require that the gap between validation and regulatory acceptance be narrowed. A balance must be achieved between the needs of individual agencies to carry out their statutory mandates and the societal desire to implement the 3Rs (refining, reducing, and replacing the use of animals) while increasing testing of chemicals for developmental neurotoxic potential. DNT presents the opportunity to simultaneously achieve statutory directives and bring new alternatives on line, because as discussed during the TestSmart DNT Workshop, it is generally acknowledged that current DNT tests are not adequate for testing large numbers of chemicals. Nevertheless, the obstacles facing new tests in the regulatory area are substantial. To support alternatives, a more coordinated approach is needed. International harmonization har·mo·nize v. har·mo·nized, har·mo·niz·ing, har·mo·niz·es v.tr. 1. To bring or come into agreement or harmony. See Synonyms at agree. 2. Music To provide harmony for (a melody). presents a promising prospect for both simplifying and accelerating the pace of regulatory acceptance (Garthoff 2005; Spielmann 2003). A more integrated process of acceptance would serve the goals of accelerating the application of new knowledge, providing transparency for stakeholders and test developers, and protecting public health as called for by the statutory mandates that agencies must meet (Garthoff 2005). Workshop Conclusions and Recommendations Conclusions. The workshop achieved its primary objective to bring together the various stakeholders and individuals from diverse scientific disciplines to examine the TestSmart DNT goals and to share ideas and concerns relating to the science and policy of DNT. The goals of the TestSmart DNT program were generally supported across all stakeholder groups, and broad consensus was reached on the following conclusions: 1. There is a real and immediate need for an approach to DNT that incorporates faster and more efficient and cost-effective tests for developmental neurotoxicity. The DNT protocols currently approved for regulatory decision making are too expensive in terms of time, resources, and animals to meet the critical need of evaluating the thousands of chemicals for which there is currently little to no DNT information. 2. Short term, the goal is to identify DNT alternatives with predictive validity that could be used to prioritize chemicals for further testing, thereby focusing resources on exposures most likely to be hazardous to the developing human nervous system. The long-term goal is to develop policies that would incorporate DNT alternatives into regulatory decision making, which would significantly reduce, refine, and perhaps even replace current mammalian in vivo DNT protocols. 3. The overall strategy is to focus on DNT alternatives that assess chemical effects on evolutionarily conserved neurodevelopmental events. Coupling the tools and methods of cell and molecular developmental neurobiology with high throughput and/or high content technologies will be necessary to rapidly expand the DNT database. An immediate need is to initiate a systematic evaluation of alternative testing models to determine their relevance and reliability for DNT. Such an evaluation would be enhanced if DNT alternatives were tested against a generally accepted set of reference chemicals, which currently does not exist. 4. The creation of a high-quality open database to catalog existing DNT data and integrate new DNT data as they become available would significantly expedite the process of identifying and validating promising DNT end points and alternative DNT models. The usefulness of such a database would be enhanced significantly if it included access to DNT data generated by pharmaceutical, chemical, and other industries as part of their in-house product safety evaluations. Critical to the success of the database is identifying resources to support its creation and maintenance. 5. To achieve the TestSmart DNT goals it will be essential to continue to build a working group of scientists and policy makers who will maintain the momentum of the first workshop and interact to develop both the strategic goals and the process for establishing an alternative DNT testing system with broad applicability to protective public health decisions. Thus, as the science develops, its policy implications will be understood, and as policy needs are articulated, the science can respond. Recommendations. A pressing and immediate problem is the paucity of data regarding the predictive validity, specificity, and sensitivity of in vitro and alternative systems-based models for DNT. Such data are required not only to evaluate any given model, but also to determine how many end points and/or models are necessary for predictive validity. Thus, an immediate need is to begin testing candidate models--raising additional questions regarding which chemicals to use for these tests. Superimposed su·per·im·pose tr.v. su·per·im·posed, su·per·im·pos·ing, su·per·im·pos·es 1. To lay or place (something) on or over something else. 2. on these issues are the problems of limited resources (how do we prioritize models for testing?) and coordinating the collection, storage, and analyses of DNT data. Specific recommendations for questions to be addressed at the second TestSmart DNT workshop as they relate to each of the three overall goals of the TestSmart DNT program include: Develop scientifically valid and efficient DNT alternatives 1. Develop a structured plan for DNT data collection and storage * Develop a template for an open database that includes relevant fields for chemical- and end point-specific data * Populate database with currently available DNT data and develop a structure for integrating evolving DNT data * Provide open access for all stakeholders 2. Identify a reference set of chemicals for evaluating the reliability and relevance of alternative DNT models 3. Develop a decision framework for analyzing data generated using DNT alternatives * Develop criteria for measuring success with DNT alternatives * Integrate information from alternatives with data obtained from mammalian in vivo tests * Apply computational toxicology and biostatistical approaches to evaluate the predictive validity of tests and test batteries 4. Identify resources to support development of DNT alternatives Develop policies for incorporating DNT alternatives into regulatory decision making 1. Streamline the process of validation 2. Narrow the gap between validation and regulatory acceptance of DNT alternatives * Develop transparent and scientifically robust criteria for the acceptance of validated tests in regulatory decision making * Involve regulatory agencies throughout all stages of test development * Review guidance and policies to ensure that these encourage application of data generated by alternatives * Recognize the value of biologic endpoint data and its application to decision making 3. Harmonize validation and regulatory acceptance of DNT alternatives * Within countries or jurisdictions sharing common regulatory organizations, harmonize validation and regulatory acceptance * Between countries and jurisdictions, establish international principles for validation and regulatory acceptance * Employ priority and tiered testing approaches that incorporate alternative testing protocols and data where feasible Identify opportunities for reducing, refining, or replacing the use of animals in DNT 1. Refine current animal testing 2. Reduce the number of animals used in existing DNT protocols * Apply data from DNT alternatives to focus testing in mammalian in vivo protocols to relevant end points * Develop a tiered testing approach that can be used for regulatory decision making * Ensure an international cooperative effort to streamline and harmonize the scientific validation of candidate DNT alternatives 3. Replace animals by validating alternative methods REFERENCES Barone S Jr, Das KP, Lassiter TL, White LD. 2000. Vulnerable processes of nervous system development: a review of markers and methods. Neurotoxicology 21:15-36. CAAT (Center for Alternatives to Animal Testing). 2007. TestSmart. Available: http://caat.jhsph.edu/programs/workshops/testsmart/index.htm [accessed 25 January 2007]. Coecke S, Goldberg AM, Allen S, Buzanska L, Calamandrei G, Crofton K, et al. 2007. Incorporating in vitro alternative methods for developmental neurotoxicity into international hazard and risk assessment strategies. Environ Health Perspect; doi:10.1289/ehp.9427 [Online 6 February 2007]. Garthoff B. 2005. Alternatives to animal experimentation: the regulatory background. Toxicol Appl Pharmacol 207:388-392. Goldman LR, Koduru S. 2000. Chemicals in the environment and developmental toxicity to children: a public health and policy perspective. Environ Health Perspect 108(suppl 3):443-448. ICCVAM. 1997. Validation and Regulatory Acceptance of Toxicological Test Methods: A Report of the Ad Hoc Interagency Coordinating Committee on the Validation of Alternative Methods. NIH "Not invented here." See digispeak. NIH - The United States National Institutes of Health. Publication No. 97-3981. Research Triangle Park Research Triangle Park, research, business, medical, and educational complex situated in central North Carolina. It has an area of 6,900 acres (2,795 hectares) and is 8 × 2 mi (13 × 3 km) in size. Named for the triangle formed by Duke Univ. , NC:National Institute of Environmental Health Sciences The National Institute of Environmental Health Sciences (NIEHS) is one of 27 Institutes and Centers of the National Institutes of Health (NIH),which is a component of the Department of Health and Human Services (DHHS). The Director of the NIEHS is Dr. David A. Schwartz. . Available: http://iccvam.niehs.nih.gov/docs/about_docs/validate.pdf [accessed 22 March 2007]. ICCVAM Authorization Act of 2000. 2000. Public Law 106-545. Lein P, Silbergeld E, Locke P, Goldberg AM. 2005. In vitro and other alternative approaches to developmental neurotoxicity testing (DNT). Environ Toxicol Pharmacol 19:735-744. OECD (Organization for Economic Cooperation and Development Organization for Economic Cooperation and Development (OECD), international organization that came into being in 1961. 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Validation and regulatory acceptance of new carcinogenicity carcinogenicity /car·ci·no·ge·nic·i·ty/ (kahr?si-no-je-nis´i-te) the ability or tendency to produce cancer. carcinogenicity the ability or tendency to produce cancer. tests. Toxicol Pathol 31:54-59. Spielmann H, Liebsch M. 2001. Lessons learned from validation of in vitro toxicity test: from failure to acceptance into regulatory practice. Toxicol In Vitro 15:585-590. Spielmann H, Liebsch M. 2002. Validation successes: chemicals. Altern Lab Anim 30(suppl 2):33-40. U.S. EPA (U.S. Environmental Protection Agency). 1998. U.S. Environmental Protection Agency Health Effects Test Guidelines. OPPTS OPPTS Office of Prevention, Pesticides & Toxic Substances (US Environmental Protection Agency) 870.6300. Developmental Neurotoxicity Study. U.S. EPA 712-C-98-239. Available: http://www.epa.gov/opptsfrs/OPPTS_Harmonized/870_Health_Effects_Test_Guidelines/Series/ [accessed 1 January 2007]. Zeigler E, Stokes WS. 1998. Validating new toxicology tests for regulatory acceptance. Reg Toxicol Pharmacol 27:32-37. Pamela Lein, (1,2*) Paul Locke, (1*) and Alan Goldberg (1) (1) Department of Environmental Health Sciences and Center for Alternatives to Animal Testing (CAAT), Johns Hopkins University Johns Hopkins University, mainly at Baltimore, Md. Johns Hopkins in 1867 had a group of his associates incorporated as the trustees of a university and a hospital, endowing each with $3.5 million. Daniel C. Bloomberg School of Public Health, Baltimore, Maryland "Baltimore" redirects here. For the surrounding county, see Baltimore County, Maryland. For other uses, see Baltimore (disambiguation). Baltimore is an independent city located in the state of Maryland in the United States. , USA; (2) Center for Research on Occupational and Environmental Toxicology, Oregon Health & Science University, Portland, Oregon, USA Address correspondence to P. Lein, Oregon Health & Science University, CROET/L606, 3181 SW Sam Jackson Park Jackson Park refers to one of the following locations in the United States:
*These authors contributed equally to this work. We thank K. Crofton and W. Mundy for critical input and editing during the preparation of this manuscript. This meeting was supported by the following sponsors: American Chemistry Council The American Chemistry Council (ACC), formerly known as the Chemical Manufacturers' Association, is an industry trade association for American chemical companies. The American Chemistry Council (ACC) is in charge of improving the public image of the chemical industry. , Cefic Long Range Research Initiative, ExxonMobil, Johns Hopkins Center for Alternatives to Animal Testing (CAAT), National Toxicology Program/National Institute of Environmental Health Sciences (NIEHS), Research Institute for Fragrance Materials Research Institute for Fragrance Materials, n.pr a United States–based organization that maintains a program for research and testing ingredients in fragrances, including those found in essential oils. , Rohm and Haas Rohm and Haas Company (NYSE: ROH), a Philadelphia, Pennsylvania based company, manufactures miscellaneous materials. A Fortune 500 Company, Rohm and Haas employs more than 17,000 people in 27 countries. The annual sales revenue of Rohm and Haas stands at about USD 8.2 billion. Company, Society for Risk Analysis, Society of Toxicology, and the U.S. Environmental Protection Agency, and by grant ES014772 from the NIEHS. The contents of this report are solely the responsibility of the authors and do not necessarily represent the official view of the NIEHS or of any of the other sponsors. The authors declare they have no competing financial interests. Received 19 October 2006; accepted 29 January 2007. |
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