Anticipate, recognize, evaluate, control, and confirm

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Anticipate, recognize, evaluate, control, and confirm (ARECC) is a decision-making framework and process used in the field of industrial hygiene (IH) to anticipate and recognize hazards, evaluate exposures, and control and confirm protection from risks (Figure 1). ARECC supports exposure- and population-informed hazard assessment, hazard- and population-informed exposure assessment, hazard- and exposure-informed population assessment, and risk-informed decision making in any endeavor. [1] [2] [3] [4] [5] [6]

Contents

History

The anticipate, recognize, evaluate, control, and confirm (ARECC) decision-making framework began as recognize, evaluate, and control. In 1994 then-president of the American Industrial Hygiene Association (AIHA) Harry Ettinger added the anticipate step to formally convey the duty and opportunity of the worker protection community to proactively apply its growing body of knowledge and experience to assessing and managing hazards, exposures, and resulting risks in existing and emerging situations.

The confirm step was added in 2011 to clarify the necessity of confirming that all steps in the decision-making framework were being effectively applied and that the desired outcomes were being achieved. [2] Overall confirmation of the adequacy of decision making for risk management includes measurements of the effectiveness of controls in the workplace and evaluation of results from occupational epidemiological studies. Confirmation of training, documentation, and continuous improvement of the entire decision-making process must be carried out to ensure that all steps are scientifically grounded and appropriately applied. [2]

The ARECC process

Figure 1. The ARECC decision-making framework and process developed in industrial hygiene to Anticipate and Recognize Hazards, Evaluate Exposures, and Control and Confirm Protection from Risks. ARECC IH Process-2018.jpg
Figure 1. The ARECC decision-making framework and process developed in industrial hygiene to Anticipate and Recognize Hazards, Evaluate Exposures, and Control and Confirm Protection from Risks.

The implementation of ARECC (Figure 1) involves conducting risk assessment and applying risk management. The ARECC graphic appears as the first illustration in the authoritative industrial hygiene reference book A Strategy for Assessing and Managing Occupational Exposures. [4] The Occupational Exposure Assessment Body of Knowledge (BoK) documents developed by the American Industrial Hygiene Association [5] [6] provide an organized summary of the collective knowledge and skills necessary for persons to use the ARECC process in conducting occupational exposure assessments. AIHA has also developed a Technical Framework on Susceptible Worker Protection [7] which includes the application of ARECC to foster awareness, understanding, and the ability to apply knowledge about the protection of susceptible workers. AIHA is using the BoKs to establish a framework for the development of education programs and knowledge/skill assessment tools, and for the improvement of the state of professional IH knowledge.

Risk assessment

During the risk assessment phase, the details of existing or potential hazards and exposures to populations of workers and members of their communities are assessed to characterize risks. The hazard identification/dose-response/exposure assessment/risk assessment approach mirrors the process that was formulated by the National Academy of Sciences / National Research Council. [8] [9] Schulte et al. noted the interrelated criteria of hazard identification/exposure assessment/risk assessment/risk management/fostering of benefits for responsible development of nanotechnology. [10] Schulte et al. also noted significant examples of progress in the fields of toxicology, metrology, exposure assessment, engineering controls and personal protective equipment (PPE), risk assessment, risk management, medical surveillance, and epidemiology for protection of nanotechnology workers. [11]

As emphasized in Figure 1, strong interactions are needed between the hazard assessment, exposure assessment, and population assessment activities. [12] Exposure- and population-informed hazard assessment ensures that realistic information about actual workplace exposure compositions, concentrations, and conditions are factored into any laboratory-based studies of health effects that are conducted. Hazard- and population-informed exposure assessment ensures that the relevant exposures are assessed in the appropriate locations and at the appropriate times. Hazard- and exposure-informed population assessment ensures that relevant and reliable susceptibility information for the exposed population is collected for assessment against, and refinement of, the hazard criteria. Identifying and defining dose-response relationships for exposures to hazards allows for the establishment of occupational exposure limits, hazard criteria for concerns such as exposures to skin, and the grouping of materials into hazard bands that can be similarly controlled.

Risk management

The risk management portion of the ARECC framework and process emphasizes leadership commitment to the safety and health mission and application of the hierarchy of controls. Commitment includes confirming that all ARECC process steps are being followed and that protection of safety, health, well-being, and productivity is being achieved.

The hierarchy of hazard controls is an integral component of the application of ARECC. The hierarchy is traditionally depicted as a vertical listing of hazard control and exposure control options in descending order of priority, beginning at the top with elimination of the hazard as the most effective control, followed by substitution of a less hazardous option, followed by engineering controls to prevent exposures, followed by administrative and work practice controls, and concluding with use of personal protective equipment as the least effective control at the bottom.

Figure 2. Depiction of a pyramid formulation of the hierarchy of controls that conveys how different strategies of control are associated with different levels of sustainability and potential risks. Hoover-Pyramid Formulation of the Hierarchy of Control-20190203.jpg
Figure 2. Depiction of a pyramid formulation of the hierarchy of controls that conveys how different strategies of control are associated with different levels of sustainability and potential risks.

Figure 2 depicts an alternative depiction of the hierarchy as a pyramid of interactive control elements. [13] The components of hazard and exposure control depicted in the pyramid formulation of the hierarchy of control are

Figure 3. Depiction of how the pyramid formulation of the hierarchy of control can be used to guide retrospective investigations of past incidents or contemporaneous or prospective job safety analyses and planning based on knowledge about the types of controls being applied. Hoover-Pyramid Hierarchy of Control Use-20190203.jpg
Figure 3. Depiction of how the pyramid formulation of the hierarchy of control can be used to guide retrospective investigations of past incidents or contemporaneous or prospective job safety analyses and planning based on knowledge about the types of controls being applied.

Figure 3 illustrates how the pyramid formulation of the interrelated elements of the hierarchy of control can be used to provide retrospective, contemporaneous, or prospective insights about the sustainability and levels of risks associated with work activities that involve different combinations of hazards, exposures, controls, and resulting risks. For example, elimination of a hazard is considered to be a highly sustainable strategy, and if a hazard was or is thought to have been eliminated from a process, then initial evaluations can focus on confirmation of material inventories and process knowledge. Similarly, control situations that rely heavily on engineered controls, warnings, work practices, or use of PPE are less sustainable and involve greater risks, and risk management evaluations can focus on confirmation of whether those controls were actually in place and properly applied.

In addition, other hazards may also be present such as heat stress, slips trips and falls, struck-by injuries, toxic metals, toxic gases, electrical shock, lasers, shift work and fatigue. If multiple hazards are present in a work activity, the status of the hierarchy of controls can be assessed for each hazard, and a worst-first, all-hazards approach can be used to prioritize actions to ensure protection from risks. Ideally, as recommended in the American National Standard for Prevention through Design [15] the hierarchy will be used to guide the design of work in a manner that will prevent the presence of hazards, exposures, and resulting risks.

ARECC leaders, cultures, and systems

Figure 4. A Leaders, Cultures, and Systems approach to building and sustaining connected, protected, respected communities with all the tools, training, and experience needed to control and confirm protection from risks in any setting. Hoover-CPR-LCS-TTE Risk Mgmt Elements-2019-02-27.jpg
Figure 4. A Leaders, Cultures, and Systems approach to building and sustaining connected, protected, respected communities with all the tools, training, and experience needed to control and confirm protection from risks in any setting.

The ARECC framework recognizes the essential contributions of leaders, cultures, and systems to achieving success (Figure 4). [13] When failures to protect people and the environment from risks have occurred, root causes of those failures can be traced to shortcomings or breakdowns in one or more aspects of the prevailing leaders, cultures, and systems. Aspects of the decision-making framework and process related to building and sustaining relevant and reliable leaders, cultures, and systems can be particularly important when disparate technologies or activities are converging.

As illustrated in Figure 4, the components of a leaders, cultures, and systems approach in any setting can enable ARECC to:

Figure 4 includes a "score card" that can be used to assess the adequacy of each element of the Connected/Protected/Respected, Leaders/Cultures/Systems, Tools/Training/Experience environment. This enables effective focus on areas that must be sustained and areas that require improvement.

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<span class="mw-page-title-main">American Conference of Governmental Industrial Hygienists</span>

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References

  1. Brandt, Michael T. (2010). "Industrial hygiene in the 21st century". The Synergist. 21 (8): 8.
  2. 1 2 3 Hoover, M.D.; Armstrong, T.; Blodgett, T.; Fleeger, A.K.; Logan, P.W.; McArthur, B.; Middendorf, P.J. (2011). "Confirming our industrial hygiene decision-making framework". The Synergist. 22 (1): 10.
  3. Laszcz-Davis, C.A.; Maier, A.; Perkins, J. (2014). "The Hierarchy of OELs: A new organizing principle for occupational risk assessment". The Synergist. 25 (3): 27–30.
  4. 1 2 Jahn, S.D.; Bullock, W.H.; Ignacio, J.S., eds. (2015). A strategy for assessing and managing occupational exposures. Falls Church, VA: American Industrial Hygiene Association. ISBN   978-1935082460.
  5. 1 2 Occupational Exposure Assessment Body of Knowledge (OEA BoK). Falls Church, VA: American Industrial Hygiene Association. 2015.
  6. 1 2 Competency Framework: Understanding and Applying ARECC to Occupational and Environmental Health and Safety. Falls Church, VA: American Industrial Hygiene Association. 2022.
  7. Technical Framework: Susceptible Worker Protection. Falls Church, VA: American Industrial Hygiene Association. 2023.
  8. National Research Council (US) Committee on the Institutional Means for Assessment of Risks to Public Health (1983). Risk Assessment in the Federal Government: Managing the Process . National Research Council. doi:10.17226/366. ISBN   9780309033497. PMID   25032414.
  9. National Research Council (US) Committee on Improving Risk Analysis Approaches Used by the U.S. EPA (2008-12-03). Science and Decisions: Advancing Risk Assessment. National Research Council. doi:10.17226/12209. ISBN   9780309120463. PMID   25009905.
  10. Schulte, P.A.; Geraci, C.L.; Murashov, V.; Kuempel, E.D.; Zumwalde, R.D.; Castranova, V.; Hoover, M.D.; Hodson, L.; Martinez, K. (2014-01-01). "Occupational safety and health criteria for responsible development of nanotechnology". Journal of Nanoparticle Research. 16 (1): 2153. Bibcode:2014JNR....16.2153S. doi:10.1007/s11051-013-2153-9. ISSN   1572-896X. PMC   3890581 . PMID   24482607.
  11. Howard, J.; Castranova, V.; Stefaniak, A. B.; Geraci, C. L.; Kuempel, E. D.; Zumwalde, R.; Hoover, M. D.; Murashov, V.; Hodson, L. L. (2016-06-01). "Taking stock of the occupational safety and health challenges of nanotechnology: 2000–2015". Journal of Nanoparticle Research. 18 (6): 159. Bibcode:2016JNR....18..159S. doi:10.1007/s11051-016-3459-1. ISSN   1572-896X. PMC   5007006 . PMID   27594804.
  12. Erdely, Aaron; Dahm, Matthew M.; Schubauer-Berigan, Mary K.; Chen, Bean T.; Antonini, James M.; Hoover, Mark D. (2016-09-01). "Bridging the gap between exposure assessment and inhalation toxicology: Some insights from the carbon nanotube experience". Journal of Aerosol Science. 99: 157–162. Bibcode:2016JAerS..99..157E. doi:10.1016/j.jaerosci.2016.03.005. ISSN   0021-8502. PMC   4990210 . PMID   27546900.
  13. 1 2 3 4 Hoover, M.D.; Cash, L.J.; Feitshans, I.L.; Oglevie Hendren, C.; Harper, S.L. (2018). "A Nanoinformatics Approach to Safety, Health, Well-being, and Productivity". In Hull, M.S.; Bowman, D.M. (eds.). Nanotechnology Environmental Health and Safety: Risks, Regulation, and Management (3rd ed.). Oxford: Elsevier. pp. 83–117. doi:10.1016/B978-0-12-813588-4.00005-1. ISBN   9780128135884.
  14. Anastas, Paul T.; Zimmerman, Julie B. (2015-03-13). "Toward substitution with no regrets". Science. 347 (6227): 1198–1199. Bibcode:2015Sci...347.1198Z. doi:10.1126/science.aaa0812. ISSN   1095-9203. PMID   25766217. S2CID   2825669.
  15. American National Standards Institute/American Society of Safety Engineers (ANSI/ASSE). 2011. PtD Standard Z590.3.2011, Prevention through Design: Guidelines for addressing occupational risks in design and redesign processes. American National Standards Institute/American Society of Safety Engineers, Des Plains, IL.

Further reading