Participants (n=32) with expertise in research, education, allied health, coaching, or healthcare, and with an interest in childhood physical activity were identified. A 1-day, in-person meeting was facilitated by PL, CB, AA with assistance from 2 graduate students. The research team shared results of an environmental scan outlining current physical literacy assessment tools, including the Canadian Assessment of Physical Literacy (CAPL). A group discussion identified goals and criteria for potential screening tasks, and which domains of physical literacy (motivation, knowledge, behavior, and physical competence) should be reflected. The panel was then divided into five sub-groups. Each sub-group had 30 minutes to identify specific tasks that should be investigated as a potential screening task for children’s physical literacy. These discussions were unstructured, and each subgroup was comprised of 5 or 6 experts plus one designated note-taker. Experts were assigned to a sub-group to ensure that each group had representation from each REACH sector. The benefit of having multiple sub-groups rather than a single group discussion. It is easier for each person to contribute their ideas in a small group of people. Combining the information from each small group makes it more likely that diverse points of view are recognized and considered. Two researchers (AA, CB) utilized qualitative research methods to independently analyze the meeting notes from the presentation sessions, large group discussion, and 5 small group discussions. Comments regarding the criteria for a screening task were identified. Based on their expertise in kinesiology (i.e., graduate degree) and experience assessment physical literacy, researchers identified each comment and categorized it by the physical literacy domain represented (overall, physical competence, motivation and confidence, knowledge and understanding, daily behavior) and whether it related to the task performed (e.g., balance on one leg) or the testing environment (e.g., small clinic room). Similar comments were grouped together to represent important concepts. Three researchers (CB, AA, PEL) then met to review the identified concepts, ensure consistency between the two analyses, and identify important themes. A list of statements outlining goals and criteria for potential physical literacy screening assessment tasks was compiled based on the identified themes.

The list of statements developed from the analyses of Round 1 responses was circulated electronically for Round 2. Delphi participants were asked to rate each statement using a 5-point Likert scale (strongly disagree, disagree, neutral, agree, and strongly agree). A priori, the researchers defined positive consensus as ≥75% of participants responding “agree” or “strongly agree” to a statement. It was felt that this would identify tasks and criteria that a majority of experts agreed were important. Similarly, negative consensus was defined as ≥75% of participants responding “disagree” or “strongly disagree” to a statement. Non-consensus statements were defined as those that did not meet either positive or negative consensus criteria. Frequency tabulations determined the degree of consensus for each statement and mean statement ratings were calculated. Additional questions regarding length of time for screening, space requirements for screening, and time for interpretation of results were also included.

The group mean was calculated for each statement based on 1 (strongly disagree) to 5 (strongly agree) points being assigned for each response. Statements from Round 2 were then recirculated to participants, accompanied by the group mean ± standard deviation and their previous individual response. Participants could then retain or change their original response based on further reflection and their knowledge of the group mean response. Final response distributions, to be used to guide future research, were calculated using the Round 3 responses. The same criteria used to define consensus in Round 2 were applied to the Round 3 responses.

Qualitative inductive thematic analysis was used to identify key themes and statements from the written text summarizing the meeting discussions (presentations, large group, 5 small groups). All of the written text was reviewed multiple times by two researchers (CB, AA), and comments related to screening tasks or criteria were identified. Concepts were identified to represent similar comments. Three researchers (CB, AA, PEL) then met to review the identified concepts, ensure consistency in the two analyses, and combine concepts into important themes.

For Rounds 2 and 3, points were awarded to each response: 1=Strongly disagree, 2=Disagree, 3=Neutral, 4=Agree, 5=Strongly agree. Frequency distributions summarized the responses to each item and determined consensus. One-way ANOVA statistics were calculated for final Round 3 data to determine whether response distributions were significantly influenced by the experts’ gender or REACH sector. Analyses were completed using IBM SPSS Version 26 (IBM Corp., released 2019, Armonk, NY), with statistical significance set at alpha=0.01 to account for the large number of comparisons.

Invitations were sent to 53 experts requesting their participation in the 3-round Delphi process, of whom 37 provided consent to participate. Twenty-eight participants (75.7%) attended Round 1, 31 (83.8%) completed round 2, and 28 (75.7%) completed round 3. Those who did not complete all three rounds either did not respond to follow-up, or withdrew from specific rounds due to time constraints. The final panel for each round was composed of at least 7 experts with primary or secondary expertise for each sector (recreation, education, allied health, coaching, and healthcare). Descriptive statistics of participants for each round are provided in Table 1.

The facilitated large group discussion among the 28 participants identified 45 screening task criteria. In addition, the experts agreed that the screening task should be flexible and easy to administer, require limited equipment and space, be accessible to all children and REACH sectors, and be complimentary to existing resources and research. Five small groups, each with representation from multiple REACH sectors, separately developed a “top 10” list of specific screening tasks. Given the number of expert participants (n=32), the variation in their expertise and experience, and the deliberate construction of small groups with representatives from each REACH sector, it is not surprising that there was significant heterogeneity of tasks between groups (see Supplemental File 1). However, all groups agreed that a screening assessment should consist of both physical tasks that can be objectively observed and questionnaires for self-reporting of different aspects of physical literacy. All groups also supported the inclusion of at least one task from each of the four domains within the consensus definition of physical literacy: motivation and confidence, physical competence, knowledge and understanding, and daily behavior. Inductive, qualitative thematic analysis produced a list of 60 criteria for an appropriate screening assessment (e.g. should be suitable for children with and without disabilities, should require minimal space, time, and resources, etc.) and a list of 27 potential screening tasks (e.g. push-ups, motivation questionnaire, vertical jump, throwing, self-reported sedentary screen time, etc.).

Based on the list of criteria and potential tasks compiled from Round 1, a questionnaire (see Supplemental File 2) was developed to include 95 statements to be answered with a Likert scale. The statements were grouped into 6 categories: criteria for a screening tool, components of physical literacy assessed and identified, content of the screening tool, resources and training required for administration, analysis/interpretation of results, and promotion of screening tool use. Positive consensus (≥75% of respondents) was achieved for 42 of 90 statements (46.6%), 2 statements achieved negative consensus (2.2%), and 48 statements (53.2%) demonstrated non-consensus. Results for time and space requirement questions are summarized in Figures 1 and 2.

When the questionnaire was circulated a second time with the mean scores for each question included, positive consensus (≥75% of respondents) was achieved for 47 of 90 (52.2%) statements. Round 3 consisted of statements regarding the screening task criteria (Table 2), what aspects of physical literacy should be measured (Table 3), the results the screening task should provide (Table 4), and details of screening task test administration (Table 4). Negative consensus was achieved for 4 statements (4.3%). The four statements that achieved negative consensus (i.e., consensus of disagreement) indicated that the screening task would require promotion/publication and should include more than one task, more than one component of physical literacy, and not be specific to one domain of physical literacy. 39 statements (43.5%) had diverse responses and did not demonstrate consensus. These diverse opinions were also reflected in the feedback regarding the time and space required to complete the screening task(s). The most frequent response (13/28, 46%) regarding the time required to screen one child was less than 10 minutes, but 11 (39%) experts thought that screening should be completed in less than 2 minutes (Figure 1). Most respondents felt that it would be appropriate to screen a group of 10 children in 25-30 minutes (n=20, 71%). Interpretation of results was recommended to be less than 2 minutes (n=14, 50%) or 5 to 10 minutes (n=14, 50%). The size of space required (Figure 2) was recommended as a small clinic room (n=9, 32%), a classroom (n=14, 50%) or a gymnasium (n=5, 18%). Participant gender did not significantly influence the results. Participant REACH sector also did not influence most results, with two exceptions. Leaders from the education and allied-health were less likely to agree (p=0.003) the screening task should be appropriate for the child’s chronological age. Whether the screening task should measure body composition also differed by sector, with leaders from alliedhealth and coaching being less likely (p=0.01) to agree that the measurement of body composition was important (Table 5).

While, an effort was made to have equal representation from each REACH sector on the panel, agreement for participation and completion of all rounds of the Delphi protocol could not be controlled. This resulted in unequal distribution of experts from the different sectors (Tables 1 & 2) which may have introduced bias into the recommendations and feedback. Variability in the requirements for administration of a screening test may be due to different resources available among REACH sectors, although our analyses did not indicate a systematic difference in recommendations by sector. At the start of the Round 1 meeting, the researchers presented the Canadian consensus definition of physical literacy, which matches that of the International Physical Literacy Association, as the framework for the discussions. It was recognized that there are multiple definitions for the concept of physical literacy, and therefore the Canadian consensus definition was presented and discussed in order to provide a common knowledge base among the participating experts. However, use of this definition may have influenced the direction of the recommendations provided. Finally, the Round 3 panel included more females (n=17, 61%), with higher representation from allied health (n=10, 36%) and healthcare (n=6, 21%) than other sectors (n<5). In addition, over half of the experts were from the allied health or healthcare sector, which may explain why there was a focus on cardiorespiratory fitness and body strength, since these are well-known indicators of physical health.