Lean six sigma 4.0 methodology for optimizing occupational exams in operations management

2.1 Lean six sigma

Lean manufacturing, originating from the Toyota Production System, is a groundbreaking Japanese management model characterized by minimal inventory and high flexibility. The concept emerged in the aftermath of the Second World War, when Japanese companies faced the challenge of achieving efficiency levels comparable to Ford that was known for its low waste and cost-effective operations. These circumstances compelled organizations to align their actions with the principles advocated by lean manufacturing (Barreto, 2012), which consequently became a guiding principle for activities aimed at delivering customer value and eliminating waste (Santos et al., 2020).

The concept of Six Sigma was introduced in 1980 by Bill Smith at Motorola Corporation, aiming to reduce errors and defects through the application of the DMAIC methodology (Popa et al., 2005). DMAIC refers to a data-based life cycle approach that ensures an organized, logical and efficient sequence of operations in project management. Its objective is to identify, quantify and minimize sources of process variation (De Mast and Lokkerbol, 2012; Sokovic et al., 2010) through the utilization of statistical quality tools for data collection and analysis that facilitates sustainable decision-making in process-related inquiries.

According to George (2003), merging LSS methodologies is crucial for reducing costs and complexity. While lean focuses on process speed and capital reduction, six sigma alone may not provide the statistical control required. Alternatively, the objective of LSS is to minimize waste, enhance performance and contribute to customer satisfaction (Popa et al., 2005). It is crucial for all individuals within an organization to understand and implement concepts of this methodology, which can be regarded as a business strategy (Endler et al., 2016). By addressing hidden costs of complexity, LSS ensures engagement from all stakeholders, enabling the establishment of a range and quality without compromising speed and cost (George, 2003). Moreover, the combination of lean principles with the DMAIC approach, as advocated by Voehl et al. (2010), enables organizations to tackle process inefficiencies systematically, improve quality and deliver sustainable results across a wide range of projects and initiatives.

The integration of LSS principles, along with the DMAIC approach, holds immense importance in the realm of occupational safety and health, as well as the management of occupational exams. By applying LSS principles, organizations can identify and eliminate potential hazards, reduce workplace accidents and enhance the overall safety culture. The systematic DMAIC process allows for the measurement and analysis of safety-related data, enabling organizations to pinpoint root causes of occupational risks and design effective interventions. In addition, LSS and DMAIC provide a structured framework to improve the management of occupational exams, ensuring accuracy, efficiency and reliability. By leveraging LSS and DMAIC in occupational safety and health, as well as exam management, organizations can create safer work environments, protect employee well-being and ensure the integrity and effectiveness of occupational examinations.

2.2 Health and safety requirements in Brazil

The promotion of occupational safety and health is of paramount importance in the labor environment. In Brazil, the necessary requirements and conditions for workplace safety and health are stipulated in the legal document called Norms Regulated (NR) that was approved in 1978 by the Ordinance No. 3,214 of the Ministry of Labor (Ministério do Trabalho, 1978). This central law establishes standards and mandates compliance for the implementation of programs and services dedicated to occupational health and safety (Silva and Santos, 2014).

However, it was not until May 18th, 1995, that Brazil officially ratified the Convention 161/85 of the International Labor Organization, signaling a pivotal shift in the approach to labor environment risks and workers’ health. This convention prescribed that companies adopted an integrated approach to identifying and addressing such risks, moving away from isolated efforts. To ensure compliance with this convention, Brazil took a proactive step a year prior, in December 1994, by issuing SSST Ordinance No. 24. This ordinance mandated that all employers and institutions employing workers assume the responsibility of developing and implementing specific programs to meet the convention’s requirements. These programs include the PPRA under NR 9 and the PCMSO outlined in NR 7 (Ministério do Trabalho e Emprego, 2013; Ministério do Trabalho e Emprego, 2016).

The PPRA plays a crucial role in managing occupational risks and ensuring health and safety of workers in Brazil. The program encompasses various stages, including anticipation, recognition, evaluation and definition of control measures for environmental risks present or potentially present in the work environment. The risks that can pose a threat to the well-being of workers are typically referred to as physical, chemical and biological hazards. The PPRA aims to manage these risks effectively through systematic planning and implementation. It establishes guidelines for identifying and assessing risks, determining appropriate control measures and monitoring their effectiveness.

To facilitate the evaluation process, the NR provides further guidance by detailing two crucial elements of the risk management process: tolerance limits (TL) and levels of action (LA). The TL represents concentration or intensity thresholds that are carefully determined based on the nature and duration of exposure to a particular risk. They represent the maximum or minimum levels at which the risk is deemed acceptable without causing harm to the employee’s health throughout their working life. Compliance with these limits ensures that the workplace maintains a safe environment for workers (Ministério do Trabalho e Emprego, 2014).

Complementing the TL, the LA serve as trigger points for implementing preventive measures when risk exposures approach or surpass the established TL. It is essential to initiate proactive actions beyond the LA to minimize the likelihood of occupational risks exceeding the acceptable limits. These preventive actions encompass various strategies, including periodic monitoring of exposures, providing relevant information to workers and implementing appropriate medical controls. By promptly addressing risks once they approach the LA, employers can effectively mitigate potential harm to their employees (Ministério do Trabalho e Emprego, 2016). These collective efforts ensure that risks are proactively managed and occupational health and safety standards are upheld.

Based on the recognition and evaluation of risks described in the PPRA, the establishment and implementation of the PCMSO is vital. This program, in accordance with the guidelines outlined in NR 7, sets forth the minimum parameters for occupational and clinical examinations, as well as their recommended frequency for employees. Its primary objective is to detect potential risks and factors contributing to employee illness, while defining measures for prevention, elimination or reduction (Ministério do Trabalho e Emprego, 2013).

Alongside NR 7 and NR 9, it is also important to consider NR 15, a regulatory standard that evaluates and classifies unhealthy conditions. This standard assesses activities that have the potential to cause diseases in exposed workers, such as those involving gammagraphy radiation and gamma-type ionizing radiation. These activities can pose significant health risks within a certain distance (Saliba and Corrêa, 2022). A critical aspect of implementing the NR 15 is the classification, planning and control of activities to ensure ongoing compliance and to dynamically measure adherence (Saliba and Corrêa, 2022).

To effectively implement these programs, it is crucial to identify occupational risks through technical site visits, employee interviews and quantitative risk monitoring. This comprehensive approach ensures compliance with legislation, prevents underestimation or overestimation of actions and allows for proper allocation of costs associated with managing these programs (SESI, 2007; Gueiros, 2006). By following this systematic approach, organizations can guarantee the successful implementation of these programs and promote a safe and healthy work environment for employees.

2.3 Lean Six Sigma 4.0

LSS 4.0 concerns the integration of tools, methodologies and principles of LSS with I4.0 technologies, focusing on operational improvements in production processes (Nascimento et al., 2020). This integration, called LSS 4.0, uses I4.0 technologies, such as big data analytics, artificial intelligence, cloud computing, Internet of Things, digital twin, 3D printing and interoperability to support and optimize the implementation of the Lean principles linked with the DMAIC methodology in favor of operational excellence (Antony et al., 2023). Also, for example, the use of I4.0 technologies to digitalize lean tools, such as value stream mapping (Fontoura et al., 2023), Ishikawa diagram (Sal et al., 2021), poka yokes (Chen et al., 2023), among others.

The implementation and maturation of LSS 4.0 in industrial organizations require significant adaptation and transformation, with culture being a key factor (Arcidiacono and Pieroni, 2018). Successful adoption of emerging technologies relies on prior adaptation of processes and people, according to the cultural determinism theory (Jackson and Philip, 2010). However, these sociocultural changes can create conflict regarding the effort needed to achieve success in LSS 4.0 implementation (Antony et al., 2023; Citybabu and Yamini 2023a). Standardizing data modelling and processes is critical to ensuring a sustainable and interoperable adoption of LSS 4.0, making them key success factors for real and scaling-up implementation (Caiado et al., 2021; de Mattos Nascimento et al., 2024). Data and process interoperability are crucial for accurately representing the LSS 4.0 application domain in an open, scalable and standardized manner, benefiting the digital supply chain and operations management (Bueno et al., 2023).

2.4 Digital process interoperability

Interoperability is the ability of systems, processes, catalogues and knowledge to be standardized and automated in favor of digital operations and supply chain resilience (Caiado et al., 2021). Within this context, object-oriented information modeling and standardization through neutral interoperability formats are one of the premises for the digital transformation of processes (de Mattos Nascimento, 2017). In this way, providing the modeling of the processes and the data object that permeate them, all necessary integration for the value flow of information is specified, called information delivery manuals (IDMs), in a standardized and accessible manner (Pinheiro et al., 2018; Calvetti et al., 2023). The construction of an IDM is essential to provide improvements and standardize information flows linked to work processes, resulting in exchange information requirements (EIRs) that specify each necessary object-oriented information to validate a stage of the work process and allow it to be translated by neutral standards (Pinheiro et al., 2018), such as the industry foundation classes to import and export information in software that an organization needs and standardize data contract with digital operations and supply chains (Eastman et al., 2010; Andriamamonjy et al., 2018).

4.1 Define phase

Based on an in-depth analysis of the occupational examinations provided by Suppliers A and B to Epsilon from January 2017 to January 2018, significant insights were gained regarding the annual growth of the number of occupational exams and their corresponding costs (see Figure 2). During this period, it was estimated that Supplier A would have conducted 1,723 occupational exams annually. However, following the change of the health service supplier in July 2017, the forecasted number of exams significantly increased to 4,296 per year (approximately 149.39%).

Consequently, the associated costs also experienced a substantial surge, rising by 89% annually. The estimated cost of exams for Supplier A was calculated to be R$66,903.94, and for Supplier B, the projected cost reached R$126,422.60, equivalent to €15,561.86 [6] and €29,405.90, respectively, which suggests an 89% surge in costs. These findings reveal the considerable impact of the change in health service supplier on both the number of exams conducted and the subsequent financial burden.

4.2 Measure phase

To gain a comprehensive understanding of the workflow and activities involved, a detailed process map was developed, illustrating the step-by-step sequence of activities. This process map, depicted in Figure 3, provided a visual representation of the various stages and interactions within the process of occupational examination. In addition, the corresponding information requirements were identified for each activity. These information requirements were outlined in Table A1 (Appendix 1), detailing specific data, documents or inputs necessary for each step of the process.

After identifying the necessary information, several parameters were evaluated, but it was found that certain criteria did not meet the legal requirements. These deviations included the following:

• inappropriate homogeneous exposure group (HEG);

• inappropriate exposure assessment methodology for chemical risks;

• unidentified concentrations of vapor organic compounds and vibration risks; and

• rejection of metal fumes, metal dust and BTX (benzene, toluene and xylene) concentration data for examination definition.

These deviations were quantified and are illustrated in the Pareto chart (Figure 4), highlighting the most significant issues. Among them, the unidentified concentration category had the highest occurrence rate, totaling 201 occurrences.

4.3 Analyze phase

Following this stage, the QHSE team organized a brainstorming meeting to identify the causes of deviations using the Ishikawa diagram, also known as the fishbone diagram (Figure 5). This collaborative session allowed for a structured exploration of potential causes across different categories, facilitating a systematic approach to problem-solving.

Using the Ishikawa diagram as a basis, a cause-and-effect matrix (Table A2, Appendix 2) was developed to prioritize actions that would address the most significant effects. The matrix aimed to identify the causes that, when eliminated, would lead to a reduction in the highest number of associated impacts.

In the matrix, the first column represents the causes that contributed to the deviations, while the top row indicates the effects along with their assigned importance weights (ranging from 5 to 10) as determined by the team. To establish the correlation between causes and effects, the team assigned correlation values based on the following criteria: (0) no correlation, (1) poor correlation, (3) moderate correlation and (5) strong correlation. The final column in each row of the matrix presents the cumulative values obtained by multiplying the correlation level of each cause by the weight of the effect and summing them up.

Interpreting the results, the highest value in the last column of the matrix indicates the top priority, as it represents a strong correlation with the identified effects. By implementing corrective actions to address the root cause associated with this highest value, the largest number of effects can be eliminated. In this case, out of the eight identified effects, the action implementation would have resolved seven, as observed in the Pareto chart presented in Figure 6.

The findings from our cause analyses support the research conducted by Silva and Santos (2014) regarding the lack of coherence between occupational risks in the workplace and recommended occupational exams in the PCMSO. In their study, 60.9% of the examined companies reported this inconsistency. Similarly, Miranda and Dias (2004) found this lack of coherence in 64.21% of the analyzed PCMSOs from 28 companies. Specifically, 50% of these discrepancies were associated with occupational exams for physical risks, 7.1% with exams for chemical risks and 7.1% with exams for biological risks in the workplace. In companies with inconsistencies in their PCMSO, 57.1% were related to the conducted exams, 21.4% to their periodicity, 17.9% to clinical exams performed, 17.9% to the Occupational Health Medical Certification [7] (ASO) process and 3.6% to data registration in individual clinical records. Miranda and Dias (2004) also discovered that 92.9% of companies had inconsistencies in their PPRA. Among these, 42.9% of firms exhibited discrepancies in risk recognition, while 39.3% had inconsistencies in quantitative monitoring.

To recapitulate, both the research conducted by Silva and Santos (2014) and Miranda and Dias (2004), as well as the findings from our cause analyses highlight the lack of coherence between occupational risks and recommended occupational exams in the PCMSO, as well as inconsistencies within the PPRA and PCMSO programs in various companies. These discrepancies encompass aspects such as risk recognition, quantitative monitoring and the performance of specific exams, which have implications for ensuring the health and safety of workers in the workplace. The results of our analysis particularly indicate that misclassification of vapor organic compounds and the lack of their monitoring resulted in a significant increase in related exams. Furthermore, the absence of monitoring for vibration risk led to the inclusion of pulse X-ray exams, as the concentration measurements to determine the level of employer exposure (NR 15 and NR 9), were not performed. In addition, the concentrations of metallic fumes, metallic dust and BTX vapors were below the LA, and they did not require medical control. However, these circumstances were not considered by Supplier B who was assigning occupational exams associated with these risks.

4.4 Improve phase

During the improvement phase, the IDM process mapping was used to identify inefficiencies and bottlenecks in the current process. This methodology helped propose and validate an optimized IDM process to enable software and hardware solutions to connect in an LSS 4.0 digital process. The team also conducted analyses to optimize occupational exams while modeling information from digital packages. EIRs were modeled by considering classes and attributes, and this helped establish the minimum and optional digital requirements for implementing LSS 4.0 in industrial organizations to manage occupational health examinations. The information necessary for each stage of the digital process was stratified and standardized, which led to creating a procedure specific to a digital process with information packages (EIRs) and standardized sequences.

Thereby, specific actions and solutions were designed to address the identified issues and optimize the process. These actions were carefully planned and executed, leveraging the expertise and collaborative efforts of the project team. Specifically, the QHSE team identified the primary corrective actions for addressing the root cause in a systematic manner. To facilitate the implementation of these actions, an action was developed and is presented in Table 1. The action plan was developed using the 5W2H tool, which provides a clear framework for addressing key aspects of the plan. The first W outlines the specific actions to be taken, the second W explains the rationale behind those actions, the third W identifies the locations where the actions will be implemented, the fourth W designates the responsible individuals for each action, the fifth W establishes the timeline for completion, the first H outlines the methods or procedures for executing the actions, and the second H addresses the associated costs, either in terms of labor hours worked or the monetary value in Brazilian Real (and in EUR). This comprehensive action plan aimed to drive the necessary process improvements and included defined tasks and deadlines for each team member. The QHSE coordinator effectively communicated the action plan to the project team, general management and the board of directors to ensure alignment and commitment to its implementation. The action plan was implemented from July 2017 to January 2019.

4.5 Control phase

Finally, in the control phase, measures were put in place to ensure the sustained success and continued improvement of the optimized process. Robust monitoring systems were implemented to track performance, and appropriate control mechanisms were established to mitigate any potential deviations or setbacks.

Thus, during this period, an on-site assessment of environmental risks was conducted, along with interviews with employees. Based on this assessment, the HEG was defined according to the exposure to environmental risks. The risks that could be monitored included chemical risks (organic compound vapors, metallic dust and metallic fumes) and physical risks (vibration and noise). The chemical products were classified according to NR 15 (based on the types of chemicals present in the workplace and their LT). Vibration was also classified according to NR 15, which establishes the daily exposure limit for occupational vibration.

Accordingly, to monitor these risks, an external consulting company was hired at a cost of R$6,000 (approximately €1,400). The monitoring results showed that the levels of metallic fumes, metallic dust, BTX vapors, vibration and organic compound vapors were below the permissible exposure limits (LA), as specified in NR 9. Therefore, no further medical control was required for these risks. However, the levels of manganese and noise exceeded the permissible limits, indicating the need for occupational exams to be conducted.

To assess the characteristics of the occupational exams process prior to the implementation of the action plan, a P-type statistical control chart was employed as a means of comparison. Figure 7 illustrates the relationship between the total number of exams conducted within each HEG and the number of exams identified as defective prior to the implementation of the action plan.

The data covers the period from August 2017 (when the service provider was changed) to March 2019 (prior to the implementation of corrective actions). The P chart clearly indicates that the process is both under control and stable, with no points exceeding the lower control limit (LCL) or upper control limit (UCL). This suggests a well-regulated process. However, the proportion of defective exams was found to be 52.01%, indicating a low process capability corresponding to a sigma level of −0.05, resulting in 520,093 defects per million.

In March 2018, employees commenced their occupational exams in line with the revised PCMSO. The QHSE team conducted a thorough review of the employees’ ASO to ensure compliance with the specified exam types, frequencies and job functions. During this process, defective exams were identified. As a result, the QHSE department integrated the approval stage of the PCMSO into the process map (Figure 8) as a poka-yoke detection mechanism. This ensured that the health-care service provider would receive guidance from the QHSE unit via email, guaranteeing the adequacy of exams (if necessary) before these are taken by employees.

Figure 9 illustrates the progress made in the occupational exam process after the implementation of improvements. It depicts the relationship between the total number of exams conducted by HEG and the number of exams identified as defective. The data spans from 01/04/2018 to 31/01/19, representing the period when employees began undergoing exams in accordance with the updated process map and PPRA.

The P-type statistical control chart displayed in Figure 9 provides valuable insights into the stability of the process. It shows that the process is under control and stable, as evidenced by the absence of data points surpassing the LCL and UCL. This indicates that the variations in the process are primarily due to natural causes.

Although one defective exam was detected during this period, the overall results of the study were considered satisfactory. The proportion of defectives decreased significantly to a mere 0.09%. This reduction highlights the effectiveness of the implemented changes in enhancing the stability and reliability of the process. It demonstrates that the improvements contributed to a higher level of process control and a reduction in its variability.

The achieved sigma level of Z = 3.13 further reinforces the positive impact of the implemented actions. This sigma level signifies a high level of process capability, with only 860 defects per million exams conducted. These results reflect the successful outcome of the implemented improvements, leading to a more efficient and reliable occupational exam process.

When considering the future scenario where all employees undergo occupational exams, the estimated annual reduction in exams is projected to be from 4,296 to 1,597 (62.82%). This substantial reduction not only signifies the streamlining of the process but also emphasizes the potential for significant cost savings. The estimated cost reduction is expected to reach 63.4%, from R$126,422.60 (€29,405.90) to R$46,404.60 (€10,793.71), as shown in Figure 10.

These findings are consistent with the work of Saliba and Corrêa (2022), who emphasized the importance of using LSS methodologies in optimizing processes and achieving cost savings. In addition, the study aligns with the research by SESI (2007) and Gueiros (2006), who emphasize the significance of identifying occupational risks through technical site visits, employee interviews and quantitative risk monitoring.

Furthermore, the development of an operational procedure by the QHSE department, along with the training provided to employees responsible for process activities, has played a crucial role in sustaining the systematic approach implemented in the organization. This aligns with the recommendations of several scholars, including Fischer et al. (2020) and Mor et al. (2019), who highlight the importance of standardizing procedures and providing adequate training to ensure the long-term success of process improvements.

In conclusion, the results of this study underscore the effectiveness of the DMAIC methodology and the LSS approach in driving positive changes in the occupational exams process. The significant reduction in the number of exams and associated costs demonstrates tangible benefits of implementing improvements. Moreover, the development of an operational procedure and training of employees support the sustainability of the implemented changes and foster a culture of continuous improvement within the organization.

5.1 Implications

The implications of this research are twofold. First, it provides a practical framework for organizations to manage and optimize the process of occupational exams using LSS 4.0 approaches along with the DMAIC methodology. The systematic approach presented in this study can help organizations identify areas for improvement, implement targeted changes and monitor outcomes, leading to more efficient utilization of resources and reduction of unnecessary costs.

Second, this research contributes to the originality of the field of study by applying the LSS principles and DMAIC methodology specifically to management of occupational exams. While these principles and methodologies have been widely used in various industries, their application of LSS 4.0 framework in the context of occupational exams is relatively novel. By demonstrating their effectiveness in improving the process and reducing costs, this research adds to the existing body of knowledge and opens avenues for further research in this area.

5.2 Limitations

It is important to acknowledge certain limitations of this research. First, the generalizability of the findings may be limited as this study was conducted solely at Epsilon. The unique characteristics of the organization and its specific context may not directly translate to other industries or organizations.

Secondly, the scope of this study focused exclusively on the management of occupational exams related to chemical risks at Epsilon’s main office. Other categories of exams and their associated challenges were not considered, potentially restricting the comprehensive understanding of the broader occupational exam management process. Thirdly, the cost considerations presented in this research only accounted for direct exam costs and did not include additional expenses such as employee travel or clinical costs. The financial implications discussed may therefore not encompass the full cost impact of managing occupational exams.

Furthermore, the short timeframe of the study limited the ability to evaluate long-term trends and the sustainability of the proposed improvements over an extended period. External factors such as changing regulations or industry standards were also not considered, which could influence the effectiveness and applicability of LSS principles in different contexts. Finally, the accuracy and potential biases in the data collected from Epsilon’s occupational exam records and assessments may introduce certain limitations to the reliability and validity of the findings.

5.3 Future research

Despite the limitations mentioned, the findings of this study provide valuable insights and a starting point for organizations seeking to enhance the management of occupational exams. Further research incorporating a broader range of exams, considering external factors and addressing the identified limitations would contribute to a more comprehensive understanding of this topic. One avenue for future research is to conduct comparative studies across different industries and organizations to assess the generalizability of LSS principles in the context of occupational exams. This would involve examining how different organizational structures, regulatory environments and industry-specific challenges impact the effectiveness of process improvement methodologies.

Likewise, future research can expand the scope of the study to include a broader range of occupational exams, such as medical exams, psychological assessments or physical fitness tests. By considering the unique requirements and challenges associated with each type of exam, researchers can develop tailored approaches that address specific areas of improvement within the exam management process. Long-term studies can be conducted to evaluate the sustainability and long-lasting impact of implementing LSS principles in the management of occupational exams. Such research would provide insights into the continued effectiveness of process improvements over time and help identify any potential barriers or challenges that arise in maintaining the improved processes.

In addition, future research should take into account external factors that can influence the management of occupational exams, such as evolving regulations, emerging technologies or changes in industry standards. By considering these external influences, researchers can better understand how to adapt and apply LSS principles in a dynamic and evolving environment. Overall, future research endeavors should aim to address the identified limitations, explore new avenues for improvement and contribute to the development of best practices in the management of occupational exams. By continuously expanding our knowledge in this area, organizations can optimize their processes, improve employee well-being and ensure compliance with regulatory requirements.