Purposeful training

Training is the most common means of supporting employees’ career advancement [Reference Elnaga and Imran17] by enhancing employees’ knowledge and skills to perform current or future job duties [18]. Effective training is purposeful – developed to address specific organizational needs while being informed by individual workers’ needs. Thus, expected training results improve work performance, benefiting employees and the organization (see Fig. 1).

Performance enhancement

Job performance depends on an individual’s competencies, types of tasks, and the social and physical environments encountered in the workplace [Reference Coetzer and Rothmann19]. Competencies refer to an individual’s core capability to perform specific tasks [Reference Boyatzis20]. Job descriptions identify expected duties and related job tasks that can be translated into competencies (e.g., skills and knowledge) needed to perform the tasks. Individuals’ workstyle attributes (e.g., achievement orientation, social influence, interpersonal orientation, adjustment, conscientiousness, independence, and practical intelligence) are important mediating factors in determining performance outcomes [Reference Borman, Kubisiak and Schneider21]. Thus, identifying employee competencies and workstyle attributes that can be aligned with required job tasks is vital for understanding and predicting performance outcomes for the job of CRC.

Career advancement

Career advancement is the long-term process of discovering and achieving one’s career goals by accumulating work experience, acquiring advanced training, and identifying and pursuing future positions [Reference Arokiasamy and Ismail22]. Career advancement reflects an individual’s personal and professional goals and the growth accrued to meet these goals. Collectively, career advancement can be a critical indicator of current and emerging trends for workforce progression, representing an ongoing negotiation of individuals’ career goals, organizational goals, and societal needs. How, then, can career information be matched to facilitate informed career-related decisions and behaviors?

Empowerment through data-driven decision-making

Empowering individuals to decide their career paths is essential for a satisfied and productive workforce [Reference Kong, Sun and Yan23,Reference Kuokkanen, Leino-Kilpi and Katajisto24]. Increasing volatility in current job markets and other changes in the workplace have relegated the responsibility of career advancement to individuals. Yet, limited resources are often provided to support their career decisions [Reference Rojewski and Hill25]. Accordingly, access to relevant, personalized data (e.g., necessary competencies of desired jobs, training to build competencies, and current and future labor market needs) is essential for career decision-making [Reference Lent and Brown26]. Such data enables individuals to establish career goals [Reference Greenhaus, Callanan and Kaplan27], select training to enhance work-related competencies, and navigate career pathways by identifying opportunities to advance their careers.

eMPACT^TM: addressing stakeholders’ needs

The framework presented in Figure 1 reflects a need for novel solutions to workforce development and guided us to design eMPACT^TM, a career navigation system, that could promote a cycle of purposeful training and career advancement outcomes. The system collects personal and cumulative data about workplace competencies, local job openings, and training availability from three key stakeholder groups (employees, employers [e.g., Principal Investigators], and training developers/coordinators) and applies them to promote both individual workers’ career advancement and organizational training goals. Each stakeholder group’s needs and contributions are reciprocal and complementary rather than exclusive or contradictory. The full benefits of this system can only be achieved when all three stakeholder groups are committed to using the system. For example, employees need access to available job and training data to make informed career decisions. This information is usually provided by employers and training coordinators. Likewise, employers and training coordinators need data on employees’ current competencies and targeted job or career goals. These data can assist employers in their recruitment efforts by identifying individuals with the desired skills and qualifications for specific positions. Training coordinators can also benefit from these data to develop effective training programs catering to employees’ needs and aspirations.

Details of each stakeholder group’s needs, benefits (i.e., system functions), and contributions are provided in Table 2.

Table 2. Three user groups and their primary needs and their potential benefits from and contributions to eMPACT^TM

CRCs = clinical research coordinators; PI = principal investigator; HR = human resources representative.

Employee’s purposeful training and career advancement. CRCs initially engage the eMPACT^TM career navigation system by completing a brief questionnaire highlighting key work knowledge and skills (e.g., demographic information, task competency levels, and personal attributes). Knowledge about self is a critical first step in the career navigation process [Reference Sampson, Peterson, Reardon and Lenz28]. This knowledge is organized into a personal profile that serves as a baseline for identifying future job aspirations and training needed to successfully achieve an individual’s career goals.

Principal investigators (PIs) and HR for efficient employee recruitment. Employers (PIs/HR) engage the career navigation system by posting profiles of available jobs, using an intake survey similar to the one used by employees. Posted job information includes required education and experience levels and required or preferred competencies of the position. In addition, potential employers receive aggregated data that summarizes system information about potential, albeit anonymized, candidates (i.e., individuals that match job requirements). Employers can send recruitment letters to matching candidates who opt for this feature. Aggregated data also provides a broader perspective of the local labor pool.

Training coordinators/developers for needs-based training offers. Individuals responsible for developing/coordinating organizational training contribute to the system by entering new or future training program profiles that reflect intake survey data. Training program profiles include information about training levels (e.g., entry level, advanced) and expected learning outcomes based on the same competency survey used by CRCs. A training profile generates an aggregated data report on potential trainee needs. Recruitment emails can be disseminated to candidates (albeit, anonymized for those selecting this feature). Training program profiles can identify individuals with compatible training needs and forecast future training needs.

Methods

The eight competency domains for Clinical Research Professionals (Joint Task Force for Clinical Trials Competency [JTF] [Reference Sonstein, Seltzer, Li, Silva, Jones and Daemen29]) provided the basis for the classification of the task competency. An exhaustive list of 263 tasks performed or expected by CRCs was generated through an analysis of three data sources: (a) job descriptions posted by three major medical institutions in the Atlanta metro area, (b) interview data with current and former CRCs collected during needs assessment [Reference Hill, Walters and Ko30], and (c) core competency guidelines for CRCs developed by the Association of Clinical Research Professionals [31]. Two subject-matter experts were asked to sort and assemble 263 task statements associated with CRC duties (on separate index cards, along with blank cards to add missing tasks) into categories. Experts sorted and combined tasks until a consensus was reached. Ultimately, this process reduced the 263 tasks into essential (or core) task statements.

Results

A total of 44 task statements were identified through the expert analysis process and then classified into one of JTF’s eight competency domains (see Supplementary Table 1 for the final version of the survey). Six proficiency levels were developed (see Supplementary Table 2) to indicate employee competency on each task statement [32]. The survey reflecting these statements was reviewed by two experts for validity, tested, and refined by two practicing CRCs.

Individual and job matching algorithm

Consider the scenario: An individual wants to know how much his or her competency profile matches the skills profile of a particular job. Proficiency levels, provided by individual responses to the 44 competency-task survey, represent one’s current competency profile and can be represented by vector, ${{{\vec u}_i}}$ , denoting the individual’s proficiency level in task i. Similarly, a job’s required competency profile can be represented by vector, ${{{\vec j}_i}}$ , indicating the job’s required proficiency level in task i. To calculate the matching score of an individual to a particular job, a set of relevant tasks (RT) for the job (proficiency level in task i for the job is not zero) is identified.

$$RT\left( {Relevant\ Tasks} \right) = \left\{ {i|\ {{\vec j}_i} \ne 0} \right\}$$

Next, a matching score can be calculated by obtaining the ratio of the sum of a user’s proficiency levels on relevant tasks to the sum of a job’s required or preferred proficiency levels on the same tasks. To avoid overinfluence of a user’s overqualified skills during the matching score calculation, relevant tasks (i) are classified into two sets: underqualified tasks, the tasks of a user’s proficiency level that are at or below the job’s required level, and overqualified tasks (OT), the tasks of a user’s proficiency level that are greater than the job’s required level. Then, the influence of OT on the overall matching score is adjusted by adding a coefficient (ω = 0.8 ∼ 1) to the following:

UT(Underqualified tasks) = {i ∈ RT | ${{{\vec u}_i}}$ ≤ ${{{\vec j}_i}}$ }

$$OT\left( {Overqualified\ task} \right) = \left\{ {i \in RT|{{\vec u}_i} \gt {{\vec j}_i}} \right\}$$

$$\overrightarrow {A{u_i}} = \left\{ {\matrix{ {{{\vec u}_i}} & & {i \in UT} \cr {({{\vec J}_i} + 1)\omega } & & {i \in OT} \cr } } \right.$$

Accordingly, when a user is overqualified in a specific task, i, for a job, its influence on the matching score is limited, while underqualified tasks are fully accounted for in the matching score. This allows the system to embrace less matching trainings in its recommendation list to make sure users do not miss any potential training opportunities. For each job, an adjusted vector, $\vec {Au_{i}}$ , is calculated to reflect each user’s proficiency level for each task, i. Then, a user’s matching score for a job is represented as:

$$ Job\ {Matching}\ {Score} \left(u,j\right)={\sum \overrightarrow {A{u_i}} \over \sum \vec {j}_{i}}\times 100 $$

Individual and training matching algorithm

Suppose an individual has competency gaps in certain tasks for a particular job. We want to assign a matching score for a certain training (T) according to the degree of potential benefits of the training in filling the competency gaps. First, we need to identify a set of tasks where an individual’s competency levels are below the job’s required levels (TG, Tasks with Gap), represented as TG = {i| ${{{\vec u}_i}}$ < ${{{\vec j}_i}}$ }. Among the tasks with the gaps, we need to check if the individual’s current task levels ( ${{{\vec u}_i}}$ ) for the task are in the range of the training’s target audience levels by checking the training’s entry-level (i.e., the minimum level needed for an effective learning experience) and maximum level of expected learning outcome for each selected task. We denote minimum and maximum levels of a task, i, by two vectors, ${{{\vec T}_{min,i}}}$ and ${{{\vec T}_{min,i}}}$ . Of the tasks for which an individual does not meet job requirements (TG), we consider two sets:

$${Optimal}\ {Range} \left(OR\right)=\left\{i\in TG | \vec {T}_{min, i}\leq \vec {u}_{i}\leq \vec {T}_{max,i}\right\}$$

Not Optimal Range(NOR) = $\left\{i\in TG |{{{\vec u}_i}} \lt \vec {T}_{min,i}\right\}$

Optimal Range (OR) refers to a set of tasks (TG) where the individual’s task level is in the optimal range for training’s effectiveness. In contrast, Not Optimal Range (NOR) refers to a set of tasks (TG) where individual competency levels are below the entry level for training, meaning that the training topic is relevant to the individual but may not be as effective as expected. To obtain the training matching score, we count tasks in the optimal range (OR) and not in the optimal range (NOR), respectively. To account for the possibility that the individual may receive limited benefits from the trainings that are not in the optimal range (NOR), we use a coefficient, ω (0.5 as a default value). Finally, we define the training matching score as

$$ {Training}\ {Matching}\ {Score} \left(u,j,T\right)={\left| OR\right| +\omega \left| NOR\right| \over \left| TG\right| }X100 $$

With this algorithm, it is possible to compare different training profiles to each other according to an individual’s competency gap for a job. In other words, the system can recommend highly-tailored training for individuals with their desired jobs.

We further refined the algorithms by differentiating required and preferred tasks for a job. We also considered other qualifications (e.g., degrees, certificates, and years of experience) as filters to screen applicable jobs for an individual before calculating matching scores. Notably, the same algorithms and resulting scores are used to recommend top marching candidates for a job and potential trainees for training to serve organizational stakeholders (e.g., employers and training coordinators).

Methods

Five hypothetical employee profiles were created to represent various levels in the progression of CRC careers, from an entry-level (CRC I) to an advanced level (CRC IV), with corresponding competency levels on the 44 tasks and basic qualifications (see Supplementary Tables 1 and 2). With the profiles, we simulated five scenarios and collected the eMPACT system’s recommendations of jobs and the trainings for pursuing a selected matching job position.

Results

The simulation test results demonstrate eMPACT’s potential in supporting CRCs in their career planning and advancement. Sample screens of eMPACT demonstrating the Case 1 scenario are shown in Figure 2. For a hypothetical CRC I profile with an entry-level competency, the system recommended five CRC II positions through Dashboard, with the top-matching job calculated as a 74% match. The 74% matching score indicates the extent to which the candidate’s competency profile meets the required competency profile of the job position. The system also recommended training courses, such as Quality at the Data Level (50%) and Medical Device Feasibility Clinical Trials (37.5%), for the job position to close the gap (26%). Training matching scores indicate the maximum percentage of the gap that could be covered by a given training, according to the training’s learning outcome profile. The remaining scenarios and their results are summarized in Table 3. Notably, while Case 1 and Case 2 had the same level of CRC position (CRC I), Case 2’s slightly higher competency level resulted in a higher matching score (95%) for the same job position (CRC 2 Infectious Disease) compared to Case 1. Case 3 represents an individual with educational and experience backgrounds who qualifies for a CRC 3 position but is currently a CRC 2. The system’s recommendations clearly reveal this candidate’s suitability for available CRC 3 positions (97% match). Case 5 presents a scenario of an advanced-level candidate who currently holds a CRC IV position, and the system recommended a Clinical Research Supervisor position with a matching score of 111%. This means that no job positions were available in the eMPACT database that held matching scores ranging from 90 to 100%, resulting in the system producing the next best alternative – positions the candidate may be slightly overqualified for.

Figure 2. Sample screen captures for top job and training matches of a hypothetical user holding a current position of clinical research coordinator I.

Table 3. eMPACT results of job and training recommendations in hypothetical scenarios

ACRP-CP = association of clinical research professionals-certified professional; CCRC = certified clinical research coordinator; CRC = clinical research coordinator; exp = experience; FDA = The United States food and drug administration; N/A = Not Applicable.

^a Indicates the top job recommended for each scenario. The results of training recommendations are based on the top job. The results vary depending on the selected job and user competency profile.

While the dashboard (see Fig. 2) is designed to display a user’s top five matching job positions as well as top five matching training recommendations according to his or her saved target job positions, users also have access to a full list of job opportunities available in the eMPACT database that they can review and filter by critical factors, such as salary or location. They can explore positions at different levels and institutions, gaining insight into the types of competencies required by employers across the spectrum. Should they be interested in pursuing a particular position, immediately or as a next step in their career, they are provided direct links to related trainings that can support them. A full list of training opportunities is also available for review.

The system uses identical algorithms for all three user groups; thus, validation for one group (employee) grants the validation for the other groups (employer and training coordinator/developer).

Number of visits to eMPACT

The eMPACT website had a total of 2,509 visits during this early dissemination period. Although we targeted CRCs in Georgia (969 visits, 38.6%), there is a significant number of visits from other states and countries worldwide (see Table 4). The average duration of each visit was approximately 3 minutes for new visitors and 5.3 minutes for returning visitors.

Table 4. eMPACT site visit geological data (Oct 14, 2022–May 31, 2023)

^a Includes foreign countries.

eMPACT user demographics and workforce competency data

A total of 192 CRCs (employees) were registered users of the eMPACT^TM system as of May 31, 2023. Their demographic statistics showed diverse backgrounds in gender, age, ethnicity, and job level (see Table 5). The educational level of most users was at or above a bachelor’s degree. The system also captured workforce competency data according to the user’s job levels (see Fig. 3). The CRC workforce reported a relatively lower level of perceived competency in Domain 3, investigational products development and regulation, and Domain 1 – scientific concepts and research design – while they perceived relatively higher competency in Domain 5 – study and site management. A similar competency pattern among CRCs was also found in a recent study [Reference Sonstein, Samuels and Aldinger33].

Figure 3. Plots for mean scores of the eMPACT users’ perceived proficiencies on core competency domains for clinical research according to their job levels. N = 128. The joint task force for clinical trial competency core competency framework for clinical research professionals [Reference Sonstein, Seltzer, Li, Silva, Jones and Daemen29]; Domain 1, scientific concepts and research design; Domain 2, ethical and participant safety considerations; Domain 3, investigational products development and regulation; Domain 4, clinical trial operations; Domain 5, study and site management; Domain 6, data management and informatics; Domain 7, leadership and professionalism; and Domain 8, communication and teamwork; 6-point Likert-type response scale (0, no experience/not applicable; 1, basic understanding; 2, perform with supervision; 3, perform independently; 4, take initiative and train others; and 5, recognized authority); job level 1, handling basic administrative duties related to clinical trials; job level 2, handling key administrative and monitoring duties related to clinical trials; and job level 3, independently leading, managing, and providing expertise across all areas of study operations.

Table 5. Demographics of eMPACT users overall (Oct 14, 2022–May 31, 2023)

GED = general educational diploma.

^a Each institution may use different job-level systems. A generic three-level system was developed to accommodate institutional differences. Level 1 indicates CRC job positions handling basic administrative duties related to clinical trials. Level 2 indicates CRC job positions handling key administrative and monitoring duties related to clinical trials. Level 3 assumes independently leading, managing, and providing expertise across all areas of study operations. Users selected a corresponding job level according to their job duties.

Overall, the growth pattern reflected in site visits by registered users was steady, while their demographic characteristics were diverse. The workforce statistics captured by the system offered the characteristics of the CRCs in Georgia, manifesting the potential to support informed decisions on workforce development at an individual, organizational, and state level.