Skip to main content
PMC home page
Nursing Open logoLink to Nursing Open
. 2020 Mar 31;7(4):1129–1138. doi: 10.1002/nop2.492

Comparing student achievement in traditional learning with a combination of blended and flipped learning

Suhaila Halasa 1, Nimer Abusalim 2,, Mohammad Rayyan 2, Rose E Constantino 3, Omayah Nassar 1, Huda Amre 4, Moayad Sharab 2, Insirah Qadri 1
PMCID: PMC7308688  PMID: 32587732

Abstract

Aim

The aim of this study was to investigate the effectiveness of blended learning with a flipped classroom design on student academic achievement in a Bachelor of Science in Nursing course.

Design

A quasi‐experimental study.

Method

Students were split into an experimental blended learning with a flipped classroom design group and a control group using the traditional, teacher‐centred learning method. Data were collected during spring 2018 (13.3 weeks) and student's grades for the registered course and their grade point average (GPA) were recorded.

Results

Findings showed statistically significant increases in student grades in the experimental group. Predictability calculations also showed better achievement of learning outcomes if a blended learning with a flipped classroom design is continued to be used in the future.

Keywords: academic achievement, blended learning, flipped classroom, nursing education, traditional learning

1. INTRODUCTION

With the advancement of technology and the enrichments of online educational resources, educational institutions worldwide are witnessing a massive trend towards the integration of technology within their education and learning methodology (Harahap, Nasution, & Manurung, 2019). The centre of the learning process is being changed from teacher‐centred, direct instruction to student‐centred learning (Kintu, Zhu, & Kagambe, 2017). One way to achieve student‐centred learning is to make use of technology by incorporating interactive learning, video lessons and online interaction, where students can take the initiative in the learning process. Student‐centred learning can be achieved by either fully online courses or blended learning courses; the choice primarily depends on the institution's goals (Mestan, 2019; Suana, Distrik, Herlina, Maharta, & Putri, 2019; Vertejee, Somani, Allana, & Dias, 2015).

The University of Jordan has recently created a paradigm shift in the teaching–learning process from one based on teacher‐led instruction to one based on student‐centred learning, whereby the instructor's role is as an expert in the field who guides and facilitates students' active engagement in their own learning process. Towards this goal, the university has adopted a flipped learning/classroom approach combined with blended learning in a 2‐to‐1 ratio (2 hr per week in class and 1 hr per week at home) in several courses offered as a pilot study. In such a design, students learn the material they are assigned, at home, via video lessons, online interactions and/or web‐based material, before being presented with applications of what they learned during face‐to‐face class meetings. One such course is offered at the School of Nursing to second‐year nursing students. The focus of this study, therefore, is to test the effectiveness of blended learning (BL) combined with a flipped classroom (FC) approach in a course offered at the School of Nursing, with respect to student's academic achievement as measured through scores attained during course evaluation methods (examinations).

1.1. Background

1.1.1. Blended learning

Blended learning is given several different names in the literature, for instance, mixed learning and hybrid learning (Barry & Abdullah Alhazmi, 2018). There is no set definition for blended learning in the literature (Hrastinski, 2019). Some define it broadly, with no focus on pedagogy changes involved, while others add details regarding the learning methods and pedagogies involved. For instance, Graham (2006, 2013) defines blended learning as a combination of traditional and online learning, while Finn and Bucceri (2004) suggest a combination of the best features of both traditional and online learning. On the other hand, Lotrecchiano, McDonald, Lyons, Long, and Zajicek‐Farber (2013) recognize a blend of structured and unstructured learning as blended learning.

Regarding location, some view blended learning as a learning approach that may occur solely in the classroom, but combining, within classroom time, various methodologies and encompassing various technological and online tools (Driscoll, 2002; Harvey, 2003). Additionally, Boelens, Van Laer, De Wever, and Elen (2015) suggest that blended learning is the combination of the best practices in traditional and online learning, meaning that some portion of class reduction may be involved. Cleary, some researchers consider blended learning to be part of in‐class activities with some distance online activities, while others view it as the integration of technology with traditional classroom education without splitting distance learning activities from classroom learning activities. Despite the body of literature on blended learning (Bliuc, Goodyear, & Ellis, 2007; Finn & Bucceri, 2004; Garrison & Kanuka, 2004; Garrison & Vaughan, 2008; Graham, 2006; Owston, York, & Murtha, 2013; Throne, 2003; Wilson & Smilanich, 2005; Yılmaz & Orhan, 2010; Zacharis, 2015), there is no consensus as to how to “blend” learning.

The advantages and disadvantages of online learning have been reported in the literature (Daniel, 2018; Dellana, Collins, & West, 2000; Hubackova & Semradova, 2016; Jones, Kukulska‐Hulme, & Mwanza‐Simwami, 2006; Kustijono& Zuhri, 2018; Mestan, 2019; Suana et al., 2019; Wang, 2010). Fully online or web‐based learning provides advantages such as flexibility, more student‐centred learning, a variety of learning pedagogies and self‐paced learning, but comes with disadvantages such as inhibiting face‐to‐face communication with other peers and requiring self‐regulated and self‐motivated students (Abrahamson, 1998; Browne, 2005).

Yılmaz and Orhan (2010) suggest that blending traditional face‐to‐face learning with online learning (a blended learning environment) can help solve the lack of interaction faced by learners in online education. However, the results in terms of student achievement regarding online learning vary. While some found positive results with the effectiveness of online learning on student achievement (Terry, Owens, & Macy, 2001), others found that both traditional learning and online learning created near similar results (Dellana et al., 2000; Iverson, Colky, & Cyboran, 2005).

1.1.2. Blended learning and student learning outcomes

Several studies have investigated the effectiveness of blended learning (Akyüz & Samsa, 2009; Allen & Seaman, 2008; Haripersad & Naidoo, 2008; Hsu, 2011; Hsu & Hsieh, 2011a; Hsu & Hsieh, 2011b; Suana et al., 2019; Sugar, Martindale, & Crawley, 2007; Tynan, Ryan, & Lamont‐Mills, 2015; Vernadakis, Antoniou, Giannousi, Zetou, & Kioumourtzoglou, 2011; Woltering, Herrler, Spitzer, & Spreckelsen, 2009). “Effectiveness” generally means the student's academic achievement as measured by student grades in course assessments and examinations. Student grades are thus taken as a measure of the effectiveness of a certain learning model in achieving the desired learning outcomes.

Several studies find significant positive student performance for blended courses (Azizan, 2010; Bloemer& Swan, 2014; Harahap et al., 2019; Hughes, 2007; Jones & Chen, 2008; Lim & Morris, 2009; Woltering et al., 2009). Hughes (2007) increased tutor support and decreased class time and concluded that such a blended method, essentially, was proven beneficial to “at‐risk” students. A study conducted by Woltering et al. (2009) aimed at comparing problem‐based learning in both traditional learning and blended learning environments. They found that problem‐based learning in blended learning environments was significantly better achieved. Some studies report no statistically significant difference between traditional learning and blended learning with respect to achieved learning outcomes (Grandzol, 2004; Hsu & Hsieh 2011a; Hsu & Hsieh 2011b). Grandzol (2004) was interested in testing whether traditional and blended learning differed with regard to student achievement as evidenced by their grades in examinations. Grandzol, however, found no conclusive evidence that one method achieved more favourable results regarding learning outcomes. Hsu and Hsieh (2011a) and Hsu and Hsieh (2011b) study also showed no statistically significant difference between traditional and blended learning in terms of effectiveness towards learning outcomes achieved.

1.1.3. Flipped learning

There is a growing body of research focusing on the flipped classroom (FC) design (Albert & Beatty, 2014; Kim, 2014; Kim, Khera, & Getman, 2014; O'Flaherty & Phillips, 2015), although the concept has been around for many years (Baepler, Walker, & Driessen, 2014; Bishop & Verleger, 2013; Gilboy, Heinerichs, & Pazzaglia, 2015). Several authors stress how flipped classrooms foster student engagement, resulting in better learning outcomes (Ash, 2012; Bergmann& Sams, 2012; Gilboy et al., 2015; Peterson, 2016; Pierce & Fox, 2012; Tune, Sturek, & Basile, 2013). In higher education, class time becomes time for further discussion of a topic that is already learned by students via pre‐recorded video lectures at home, or, in the case of health sciences, to take time to tackle more complex clinical case scenarios (Pluta, Richards, & Mutnick, 2013). We are left with testing the effectiveness of flipped learning designs on student achievement, given the University of Jordan's recent piloting of blended learning combined with flipped learning. However, as with blended learning, the literature on the effectiveness of flipped learning also shows conflicting results.

1.1.4. Flipped learning and student learning outcomes

With respect to the flipped classroom model, research has produced conflicting results as to its effectiveness with respect to student achievement as measured by student grades. While some show improved measurable benefits to student grades (Johnson, 2013; Kong, 2014; Mason, Shuman, & Cook, 2013; Roach, 2014), others concluded no statistically significant difference (Blair, Maharaj, & Primus, 2016; Muzyk et al., 2015; Ryan & Reid, 2015).

With respect to the effectiveness and impact of the flipped classroom model on scores, Albert and Beatty (2014) compared traditional and flipped learning and found differences in student achievement as measured by student examination grades. The differences were not statistically significant for all examinations; the first and third examinations showed statistically significant differences in student scores favouring flipped learning, while the second examination showed no statistically significant difference. In the same way, Sahin, Cavlazoglu, and Zeytuncu (2015) showed that, in mathematics courses, students achieved significantly higher scores in the flipped section than in the traditional classroom.

However, not all research comparing traditional versus flipped classrooms in higher education turns out to be effective. In this sense, Muzyk et al. (2015) and Ryan and Reid (2015) provided results that do not show statistically significant differences in students' performance through examination scores in both formats and did not improve the students' performance at the end of the course.

Focusing attention more precisely on the health field, several higher education health‐related courses are, just as many institutions in general, seeking to enhance student‐centred learning (Melton, Chopak‐Foss, & Raychowdhury, 2008). Despite the popularity of flipped learning, research on flipped learning focusing on health sciences is scarce (Alemán, de Gea, & Mondéjar, 2011; Brettle& Raynor, 2013; Chen & Chuang, 2012; Dhir, Verma, Batta, & Mishra, 2017; Frith& Kee, 2003; Ruckert et al., 2014). According to Betihavas, Bridgman, Kornhaber, and Cross (2016), those studies regarding technology‐enhanced learning in nursing programmes yielded conflicting results: some neutral and some positive, and that none of the relevant studies evaluated the process of implementation of flipped classrooms combined with blended learning involving part at‐home and part in‐class tasks in a nursing setting, hence the significance of this study.

2. THE STUDY

2.1. Research questions

This study aimed to test the differences in the effectiveness of blended learning combined with flipped classrooms on the one hand, with traditional, face‐to‐face learning without a flipped classroom design. In particular, this research was concerned with the following research question.

  • RQ1: Are there statistically significant differences concerning achievement as assessed through student grades between the experimental group using blended learning with flipped learning and the control group using the traditional method without flipped learning?

This research is also concerned with how reliable a predictor; the results obtained for RQ1 are of future achievement of students if blended learning with flipped classrooms were to continue to be implemented. The following research question addresses this matter.

  • RQ2: To what extent can the results be predictable of academic achievement for the end GPA (graduation GPA), reflecting thus on the predictability of student achievement and effectiveness of each method. In other words, can the results of RQ1 be translated into future predictions regarding students' graduation GPA if BL + FC were implemented throughout the remainder of degree semesters?

2.2. Design

A quasi‐experimental method was used with an experimental and control group in the post‐test only. The first group was the control group, where the students studied the material through traditional learning. They were tested three times (first, second and final examination). The second group was the experimental group. Students studied the material via blended learning combined with a flipped classroom design and were tested with the same examinations (unified for control and experimental groups administered in large classrooms).

Accordingly, the design scheme of this study is:

  • Experimental Group (EG): X ON = 59.

  • Control Group (CG): O; N = 66.

where “O” stands for academic achievement and “X” stands for processing using the blended learning method.

Details regarding the differences between the two groups are presented in Table 1.

TABLE 1.

Details of differences in course activities and schedules between experimental and control groups

Course design particulars Experimental group Control groups
Learning Method Blended + flipped learning Traditional learning without flipped classrooms
Course Components and Schedule

Step 1: Students learn about that week's particular topic at home with the deduction of a third of actual class meetings (amounting to 2 actual face‐to‐face meetings out of 3).

Step 2: Students meet face to face, in class for the remainder (2 out of 3 classes per week for 16 weeks)

 New topics are offered in class only, during 3 one‐hour face‐to‐face lectures per week for 16 weeks
Activities
Students perform at‐home and in‐class activities, as follows:
  • At‐home: Students prepare the material via watching a pre‐recording lecture online posted for them on the institution‐adopted learning management system, known as MOODLE.
  • In‐class: Class begins with a student‐led discussion of key points; then, instructor offers more advanced questions and discussion given the additional time gained from not having to repeat nor teach the basics of that week's topic.

  • Students are first exposed to a certain week's topic from the instructor during 3 weekly face‐to‐face in‐class lectures.

  • Students are given weekly assignments to do at home after being taught the material during class.
Assessment strategies First, second and final examinations First, second and final examinations
Open in a new tab

The control group met face to face in class three times a week (1 hr each), on Sundays, Tuesdays and Thursdays, and were given traditional teacher‐led lectures, with no online tasks. The control group was not asked to perform any extra coursework at home. They were only given the course syllabus, distributed via uploading to the Moodle platform (the university's LMS).

The experimental group met only twice a week (also 1 hr each), on Sundays and Tuesdays, and were given distance online tasks to complete the three‐credit‐hour course requirement (i.e. instead of Thursday's class). The course syllabus was uploaded for students on the Moodle, and all the topics, interactive strategies, videos and flipped classroom material were uploaded and available for students. Specifically, items concerning next week's topic were uploaded to the LMS on Tuesday nights with instructions for students to complete certain flipped classroom tasks, in preparation for the next class meeting (Sundays), where the topic they prepared at home would be discussed. This was to ensure that students prepared and attempted to learn the material on their own before arriving to the face‐to‐face meeting in class on Sundays, thus achieving a flipped classroom design and creating a student‐centred learning environment. Students were reminded via the LMS, to perform the tasks assigned to them and be ready for a class discussion on the topic during the first ten minutes of the class. Online tasks included watching an e‐lecture and reading material related to the upcoming topic.

3. METHODS

3.1. Participants

The participants of this study were second‐year nursing students who registered in the Foundation of Growth and Development course for the first time (4 sections), spring 2018, during the period of 28/1/2018–8/5/2018. All the students who registered in the 4 sections had agreed to participate in the study and were oriented about the purpose of the study before they registered in the course sections. Two of these sections were designed to apply the experimental method (blended learning with flipped classrooms), while the other two followed the traditional method of learning. Students had the choice to register in any section, thus achieving natural randomization; the result of which was 59 students in the experimental group and 66 in the control group.

3.2. The course invoked in the study

This study focused on a course offered for second‐year nursing students in the School of Nursing at the University of Jordan. The course title is “Foundation of Growth and Development” (Course Number: 0702102) and is one of the compulsory courses in the Bachelor of Science in Nursing programme with three credit hours per week. Students must take this course as a prerequisite to the “Children and Adolescent Health Nursing” course. The rationale for selecting this course is because students generally tend to have difficulties in achieving the course intended learning outcomes due to a lack of knowledge and understanding of the growth and development concepts and theories. The details of the course are offered in Table 2.

TABLE 2.

Course details

Name of Course Foundations of Growth and Development
Location The University of Jordan—School of Nursing—Maternal & Child Health Dept.
Level 2nd‐year level—Core Course—Prerequisite to “Children and Adolescents Health Nursing Course”
Semester Spring 2018
Total Number of Students 125
Course description This course is designed to introduce students to the main concepts that are related to growth and development of humans throughout their life span. It focuses on the biological, psychosocial, cognitive, moral and spiritual characteristics of each developmental stage. The course introduces students to the strategies that can be used to help individuals of a particular developmental period attain optimal health. The framework of the course is based on the concept of health maintenance and promotion
Open in a new tab

3.3. Data collection instruments and procedures

Data were collected during the spring semester of 2018 (13.5 weeks), and students' grades (first, second and final examinations) for both groups were recorded. Before beginning the course, it was necessary to ensure that the two groups were equivalent in terms of previous student academic achievement levels (i.e. that, for instance, it was not the case that all of the high achievers were coincidently registered in one particular section). To verify the equivalence of the experimental and control group, the cumulative GPAs of the students were recorded at the beginning of the semester. As stated earlier, all students were second‐year students. Their GPAs included a cumulative average of their grades for previously taken courses throughout the preceding three semesters of their studies. Students' past cumulative GPAs were accessed by the university's intranet network available for faculty, which shows all student enrolments, their achieved grades and their overall cumulative GPAs at any given moment for all semesters completed combined. Students, as mentioned earlier, were briefed beforehand that this was going to be part of the participation in the experiment. Accordingly, for further confirmation of equivalency of control and experimental groups, a t test of the independent samples was conducted to verify the equivalence between the two groups according to the students' cumulative GPAs. Table 3 shows these results.

TABLE 3.

Means, standard deviations and t test of independent samples of the cumulative average of students according to the experimental and control groups

Group N Mean SD T df Sig.
Experimental 59 2.77 0.566 1.684 123 .095
Control 66 2.60 0.535
Open in a new tab

Abbreviations: N, Number of students; Sig., significant; T, t test.

Table 3 shows that the t‐value of the cumulative averages (entering overall GPAs) of students in the experimental and control groups was 1.684, which is not statistically significant. There are, therefore, no statistically significant differences concerning the entering cumulative averages between the experimental and control groups. This indicates that the two groups were equivalent in terms of previous academic achievement levels before applying the teaching method to the experimental group.

3.4. Data analysis

The data were analysed using the average, standard deviation and t test. The software used was SPSS Statistics.

3.5. Ethical considerations

This study was approved by the IRB Ethics Committee at the School of Nursing at the University of Jordan. The Foundation of Growth and Development course during spring 2018, was offered to students through 4 sections. At the beginning of the semester and before students registered the course, they were informed that two sections will be taught as blended learning and the other two by traditional methods. Students had the choice to register in any section they preferred. Furthermore, students were informed that all sections will cover the same course topics and have the same assignments and examinations to achieve the course intended learning outcomes. Students were informed that the researcher will review their grades and their previous cumulative grade point averages (GPAs) for the purpose of examining the effect of blended learning on their overall grades. Therefore, written consent explaining the purpose of the study was obtained from them.

4. RESULTS

4.1. Demographics

The demographic data showed that the total number of students in the 4 sections was 125 (99 females (79.2%) and 26 males (20.85), with an average age for males and females of 19 years old. All the students in the experimental group were Jordanian, while around 97% were Jordanian and 3% were Palestinian in the control group. The demographic characteristics of the participants (both groups) are shown in Table 4.

TABLE 4.

Demographic characteristics of the participants (N = 125)

Group N Gender Age Nationality
Experimental 59 M: 13 (22.03%) M: 19.6 59 (100%) Jordanian
F: 46 (77.66%) F: 19
Control 66 M: 13 (19.70%) M: 19.8 64 (96.96%) Jordanian
F: 53 (80.30%) F: 18.8 2 (3.03%) Palestine
Open in a new tab

4.2. Results related to the first research questions

  • RQ1: Are there statistically significant differences concerning achievement as assessed through student grades between the experimental group using blended with flipped learning and the control group using the traditional method without flipped learning?

To answer this question, the averages, standard deviations and t test for independent samples of students' academic achievement were calculated for both groups, as illustrated in Table 5. Students' total for all three examinations (first, second and final examination) was calculated, and the mean for each section was calculated. This is different from the method used by Albert and Beatty (2014), whereby achievement was taken separately for each examination (as discussed above). The intention for considering the total of all examinations was to avoid any external variables that may affect the data and avoid conflicting results (cf. Albert & Beatty, 2014). The mean for each group of total grades for these examinations (experimental and control) was also calculated. Table 5 details the results.

TABLE 5.

The means, standard deviations and t test for independent samples of students' academic achievement between the experimental and control groups

Group N Mean SD T df Significance level
Experimental 59 77.77 7.985 2.968 123 .004*
Control 66 72.33 11.892
Open in a new tab

Abbreviations: N, Number of students, T, t test, Sig., significant.

*

Statistically significant at level .05.

Table 5 shows that the value of "T" of the achievement of students between the two groups according to the teaching method applied was 2.968, which is statistically significant. This indicates that there are statistically significant differences concerning the academic achievement of students between the experimental and control groups. The differences were in favour of the experimental group with a higher average than that of the control group. This means that the blended learning method improved the achievement of the experimental group. To calculate the effect of the teaching method, the following equation was used:

SC=n1-1S12+n2-1S22n1+n2-22
d=X¯1-X¯2SC

d: effect size.

Mean of the first sample.

Mean of the second sample.

Standard deviation for both samples.

Sc = ((3698.09305 + 9192.27816)/123)1/2 = 10.23717568.

= (77.77 − 72.33)/10.23717568 = 0.531.

The application of the effect size equation on the two independent groups using the t test showed that the value of the effect size was 0.531 and this is a medium effect size as indicated by Cohen (1988). This indicates that 53.1% of the differences concerning academic achievement between the experimental and control groups were due to the learning method using blended learning with a flipped classroom design.

4.3. Results related to the second question

  • RQ2: To what extent can the results offer a predictability of academic achievement for the end GPA (graduation GPA), reflecting thus on the predictability of student achievement and effectiveness of each method. In other words, can the results of RQ1 be translated into future predictions regarding students' graduation GPA if BL + FC were implemented throughout the remainder of degree semesters?

The aim of this question was to understand whether students' graduating GPA can be predicted to increase (as compared with traditional learning method) if the blended learning with flipped classroom design were applied throughout the remainder of the semesters of study (roughly 4 additional semesters). In other words, can it be predicted based on the results for RQ1 that students' graduating GPAs will increase if the experimental method (instead of the traditional learning method) were applied throughout the remainder of the semesters of study? To find the predictability of academic achievement, a linear regression analysis was conducted (Table 6).

TABLE 6.

The predictability of academic achievement for the GPA

Model Unstandardized Coefficients t Sig. R R Square Adjusted R Square F Sig.
B SE
(Constant) 0.014 0.263 0.053 .958 0.678 0.460 0.455 104.667 .000*
Achievement 0.036 0.003 10.231 .000*
Open in a new tab
*

Statistically significant at level .05.

Table 6 shows that the correlation coefficient between achievement and cumulative averages was 0.687, statistically significant at 0.05. This indicates that achievement affects and predicts the cumulative average of the students. The predictability of academic achievement for the GPA was 0.460, indicating that achievement accounts for 46% of the student's cumulative average. This is statistically significant at the level of significance. This indicates that 46% of the variation of the cumulative means accounts for students' achievement. Conversely, 46% of the variation in achievement is accounted for by students' cumulative average; 0.54% is accounted for by other variables. Accordingly, if blended learning with a flipped classroom design were to be implemented for the remainder of semesters until graduation, it is predicted that students' overall GPAs would increase (a separate study will need to be conducted to predict the extent of increase in detail).

5. DISCUSSION

Regarding the first question, the results revealed that students achieved higher grades in the blended learning group, and this is congruent with the study conducted by Harahap et al. (2019). The findings of a study conducted by Peterson (2016) were congruent with the results of this recent study where students had better academic achievements and were more satisfied with the overall statistics course in that study compared with students who had been taught the course through the traditional learning strategies. Nursing students who had been taught the clinical skills via blended learning received higher scores in relation to motivation and attitude towards learning professional skills (Coyne et al., 2018). Regarding the second question, the student's academic achievement in the course significantly predicts their overall GPA. Given such results of predictability coupled with the previous result of blended learning students achieving significantly higher grades than the non‐blended learning group, it can be said that blended learning is predicted to increase students' GPAs by the end of their university studies, if implemented throughout the remainder of their studies.

These findings concerning students achieving higher grades in blended learning classes are consistent with the findings of other related research (Azizan, 2010; Fortin, Viger, Deslandes, Callimaci, & Desforges, 2019; Hughes, 2007; Jones & Chen, 2008; Lim & Morris, 2009; Woltering et al., 2009; Yu & Du, 2019). Furthermore, an experimental study conducted by Sung, Kwon, and Ryu (2008) revealed that blended groups had a higher statistically significant level of knowledge and satisfaction related to administration of medication skills and knowledge compared with the control group, while there were no statistically significant differences between the groups in relation to self‐efficacy. Choi and Kim (2018) conducted a quasi‐experimental design to evaluate the effectiveness of an educational programme related to smoking cessation based on blended learning in improving nursing students' competence and motivation to conduct a smoking cessation intervention for smokers. The results showed that the educational programme adopting blended learning was significantly effective in developing nursing students' competences and motivation in conducting a successful programme.

None of the previously mentioned studies, however, entertained the idea of combining both blended learning and flipped classrooms. The statistically significant differences found between the two groups can be summarized as follows. First, students seem to understand the material better when having previously prepared it or for it at home (Gaughan, 2014; Roach, 2014). This, in turn, leads to the second point, namely that students in the experimental group are engaged to envision higher levels of Bloom's taxonomy given the extra time derived from freedom from face‐to‐face meetings; this is supported by the study conducted by Becker et al., (2017); Park, Woo, and Yoo (2016). Higher‐order thinking skills and more advanced activities are easily achieved in class when students have already prepared the basics of the topic at home (Gilboy et al., 2015; Johnson, 2013; Kong, 2014). The third point clearly noticed is the fact that blended learning offers student‐paced learning catering to the differences in learning styles and speed of each student, along with the added benefit of a flipped classroom which nudges students to become familiar with the material weekly, instead of the night before an examination, which tends to happen with traditional learning.

Given the results previously outlined, we suggest that the best teaching practices that create engaged students, taking the lead in their acquisition of knowledge, come from models of learning that are quite different from the traditional model. In educating nurses and healthcare providers, integrating blended learning within diverse learning methodologies enhances communication skills and improves self‐efficacy among nursing students (Shorey et al., 2018). As discussed earlier, blended learning alone does not ensure student‐centred learning; for instance, teaching a certain topic to students throughout the week in class only to give them the last day of the week off to perform homework on the same topic at home does not alone achieve student‐led learning, but, in fact, maintains the spoon‐feeding method, as evidenced by the literature citing negative results with blended learning mentioned above. Our research indicates that when students prepare the material at home via a flipped learning design, by watching a pre‐recorded lecture video, for instance and in some cases, being moved or inspired to search the Internet for more information on the topic before coming to class, we can then safely say that students are learning on their own and teachers only serve as guides or helping experts in the field.

5.1. Limitations

The main limitation of this study is the relatively small sample size (125 students in only 4 sections). Given that the blended learning and flipped classroom method was in the piloting phase at the University of Jordan, not many sections, nor blended learning strategy‐trained faculty members were available at the time. Another limitation is related to the students. In particular, students self‐selected which section they registered in; this may have had some influence on the study outcomes, even though the statistical analysis of previous GPAs shows no statistically significant difference between the two groups. A further limitation regarding students' self‐allocation to the sections was the fact that, since it was announced beforehand which sections were going to be taught as blended learning, it could be the case that the more technology‐comfortable students registered in the blended learning sections. If they were not given such information, then we would expect that each section would have some tech‐savvy students and some that are not comfortable with technology use. Could students have achieved the same results regardless of whether they were comfortable with technology use or not? Again, such a factor may have affected the results of this study.

5.2. Suggestions for future research

Future research may wish to replicate this study on a larger scale. Future studies could also aim to test, compare and contrast, in similar or dissimilar settings, the differences in student achievement between blended learning (with class time reduction) and flipped learning combined on the one hand, with flipped learning without reducing class time. Replicating this study in settings other than nursing schools is also recommended. In particular, researchers may wish to see whether similar results hold for other disciplines, such as medicine, pharmacy, social work, dentistry, rehabilitation science and other health disciplines. Moreover, researchers may focus on younger study participants to examine whether similar results could be obtained.

6. CONCLUSION

Despite the importance of using blended learning and online learning in general, there are many challenges facing educational programmes in the application and implementation of blended and online programmes in the educational curriculum. These challenges could be technical (the ability of the students and educators to use the technology successfully) and/or organizational (understanding, encouraging and facilitating of the manager for the implementation of blended learning). For the instructional design, when technology is adopted, more attention needs to be provided on how to teach, matching the best technology to achieve the indented learning outcomes, thus producing more well‐equipped nursing professionals. Professional nurses, educators and clinicians need to integrate and adopt blended learning as a learning strategy. Blended learning combined with flipped classrooms, as this study shows, allows nursing students to become self‐directed autonomous learners, thus enhancing nursing competencies effectively.

CONFLICT OF INTEREST

The authors declare no conflict of interest to report.

AUTHORS' CONTRIBUTIONS

Suhaila Halasa: Discussion, submission and corresponding author. NimerAbusalim: Results and analysis. Mohammad Rayyan: Results and analysis. Rose E. Constantino: Design, methods, data collection and review of the final draft. OmayahNassar: Discussion. Huda Amre: Introduction and background. MoayadSharab: Conclusion and background. InsirahQadri: Conclusion and review of the first draft.

ACKNOWLEDGEMENTS

We would like to thank our students who participated in the study. Our thank goes to the Maternal and Child Health Department at the School of Nursing who gave us the chance to conduct this study.

Halasa S, Abusalim N, Rayyan M, et al. Comparing student achievement in traditional learning with a combination of blended and flipped learning. Nursing Open. 2020;7:1129–1138. 10.1002/nop2.492

Funding information

This research study did not receive any specific grant from funding agencies in the public, commercial or not‐for‐profit sectors.

REFERENCES

  1. Abrahamson, C. E. (1998). Issues in interactive communication in distance education. College Student Journal, 32(1), 33–42. [Google Scholar]
  2. Akyüz, H. İ. , & Samsa, S. (2009). The effects of blended learning environment on the critical thinking skills of students. Procedia‐Social and Behavioral Sciences, 1(1), 1744–1748. [Google Scholar]
  3. Albert, M. , & Beatty, B. J. (2014). Flipping the classroom applications to curriculum redesign for an introduction to management course: Impact on grades. Journal of Education for Business, 89(8), 419–424. [Google Scholar]
  4. Alemán, J. L. F. , de Gea, J. M. C. , & Mondéjar, J. J. R. (2011). Effects of competitive computer‐assisted learning versus conventional teaching methods on the acquisition and retention of knowledge in medical surgical nursing students. Nurse Education Today, 31(8), 866–871. [DOI] [PubMed] [Google Scholar]
  5. Allen, I. E. , & Seaman, J. (2008). Staying the course: Online education in the United States, 2008. Newburyport, MA: Sloan Consortium. [Google Scholar]
  6. Ash, K. (2012). Educators evaluate flipped classrooms. Education Week, 32(2), S6–S8. [Google Scholar]
  7. Azizan, F. Z. (2010). Blended learning in higher education institution in Malaysia In Proceedings of regional conference on knowledge integration in ICT (Vol. 2010, pp. 454–466). [Google Scholar]
  8. Baepler, P. , Walker, J. D. , & Driessen, M. (2014). It's not about seat time: Blending, flipping, and efficiency in active learning classrooms. Computers & Education, 78, 227–236. [Google Scholar]
  9. Barry, A. , & Abdullah Alhazmi, F. (2018). A blended learning model used to prepare Saudi Arabian doctoral students to be knowledge‐based educational leaders In Proceedings of the 9th International RAIS Conference on Social Sciences and Humanities. [Google Scholar]
  10. Becker, S. A. , Cummins, M. , Davis, A. , Freeman, A. , Hall, C. G. , & Ananthanarayanan, V. (2017). NMC horizon report: 2017 higher education edition (pp. 1–60). Austin, TX: The New Media Consortium. [Google Scholar]
  11. Bergmann, J. , & Sams, A. (2012). Flip your classroom: Reach every student in every class every day. Washington, DC: International society for technology in education. [Google Scholar]
  12. Betihavas, V. , Bridgman, H. , Kornhaber, R. , & Cross, M. (2016). The evidence for ‘flipping out’: A systematic review of the flipped classroom in nursing education. Nurse Education Today, 38, 15–21. [DOI] [PubMed] [Google Scholar]
  13. Bishop, J. L. , & Verleger, M. A. (2013). The flipped classroom: A survey of the research In ASEE National Conference Proceedings (Vol. 30, No. 9, pp. 1–18). Atlanta, GA. [Google Scholar]
  14. Blair, E. , Maharaj, C. , & Primus, S. (2016). Performance and perception in the flipped classroom. Education and Information Technologies, 21(6), 1465–1482. [Google Scholar]
  15. Bliuc, A. M. , Goodyear, P. , & Ellis, R. A. (2007). Research focus and methodological choices in studies into students' experiences of blended learning in higher education. Internet and Higher Education, 10(4), 231–244. [Google Scholar]
  16. Bloemer, W. , & Swan, K. (2014). Investigating informal blending at the University of Illinois Springfield. Blended Learning Research Perspectives, 2, 52–70. [Google Scholar]
  17. Boelens, R. , Van Laer, S. , De Wever, B. , & Elen, J. (2015). Blended learning in adult education: towards a definition of blended learning. Adult Learners Online! Blended and Online Learning in Adult Education and Training. WP2 – 15.06.2015 – Project Report.
  18. Brettle, A. , & Raynor, M. (2013). Developing information literacy skills in pre‐registration nurses: An experimental study of teaching methods. Nurse Education Today, 33(2), 103–109. [DOI] [PubMed] [Google Scholar]
  19. Browne, E. (2005). Structural and pedagogic change in further and higher education: A case study approach. Journal of Further and Higher Education, 29(1), 49–59. [Google Scholar]
  20. Chen, H. Y. , & Chuang, C. H. (2012). The learning effectiveness of nursing students using online testing as an assistant tool: A cluster randomized controlled trial. Nurse Education Today, 32(3), 208–213. [DOI] [PubMed] [Google Scholar]
  21. Choi, S. H. , & Kim, Y. H. (2018). Effects of smoking cessation intervention education program based on blended learning among nursing students in South Korea. Osong Public Health and Research Perspectives, 9(4), 185–191. [DOI] [PMC free article] [PubMed] [Google Scholar]
  22. Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd ed.). Hillsdale, NJ: Erlbaum. [Google Scholar]
  23. Coyne, E. , Rands, H. , Frommolt, V. , Kain, V. , Plugge, M. , & Mitchell, M. (2018). Investigation of blended learning video resources to teach health students clinical skills: An integrative review. Nurse Education Today, 63, 101–107. [DOI] [PubMed] [Google Scholar]
  24. Daniel, O. T. T. O. (2018). Using virtual mobility and digital storytelling in blended learning: Analysing students' experiences. Turkish Online Journal of Distance Education, 19(4), 90–103. [Google Scholar]
  25. Dellana, S. A. , Collins, W. H. , & West, D. (2000). Cyber dimensions: On‐line education in a management science course—effectiveness and performance factors. Journal of Education for Business, 76(1), 43–47. [Google Scholar]
  26. Dhir, S. K. , Verma, D. , Batta, M. , & Mishra, D. (2017). E‐learning in medical education in India. Indian Pediatrics, 54(10), 871–877. [DOI] [PubMed] [Google Scholar]
  27. Driscoll, M. (2002). Blended learning: Let's get beyond the hype. E‐Learning, 1(4), 1–4. [Google Scholar]
  28. Finn, A. , & Bucceri, M. (2004). A case study approach to blended learning. Los Angeles, CA: Centra Software. [Google Scholar]
  29. Fortin, A. , Viger, C. , Deslandes, M. , Callimaci, A. , & Desforges, P. (2019). Accounting students' choice of blended learning format and its impact on performance and satisfaction. Accounting Education, 28(4), 353–383. [Google Scholar]
  30. Frith, K. H. , & Kee, C. C. (2003). The effect of communication on nursing student outcomes in a web‐based course. Journal of Nursing Education, 42(8), 350–358. [DOI] [PubMed] [Google Scholar]
  31. Garrison, D. R. , & Kanuka, H. (2004). Blended learning: Uncovering its transformative potential in higher education. Internet and Higher Education, 7(2), 95–105. [Google Scholar]
  32. Garrison, D. R. , & Vaughan, N. D. (2008). Blended learning in higher education: Framework, principles, and guidelines. Hoboken, NJ: John Wiley & Sons. [Google Scholar]
  33. Gaughan, J. E. (2014). The flipped classroom in world history. History Teacher, 47(2), 221–244. [Google Scholar]
  34. Gilboy, M. B. , Heinerichs, S. , & Pazzaglia, G. (2015). Enhancing student engagement using the flipped classroom. Journal of Nutrition Education and Behavior, 47(1), 109–114. [DOI] [PubMed] [Google Scholar]
  35. Graham, C. R. (2006). Blended learning systems In Bonk C. J., & Graham C. R. (Eds.), The handbook of blended learning (3–21). San Francisco, CA: Pfeiffer Publishing. [Google Scholar]
  36. Graham, C. R. (2013). Emerging practice and research in blended learning In Moore M. G. (Ed.), Handbook of distance education (3rd ed., pp. 333–350). New York, NY: Routledge. [Google Scholar]
  37. Grandzol, J. R. (2004). Teaching MBA statistics online: A pedagogically sound process approach. Journal of Education for Business, 79(4), 237–244. [Google Scholar]
  38. Harahap, F. , Nasution, N. E. A. , & Manurung, B. (2019). The effect of blended learning on student's learning achievement and science process skills in plant tissue culture course. International Journal of Instruction, 12(1), 521–538. [Google Scholar]
  39. Haripersad, R. , & Naidoo, R. (2008). Errors made by first year students in an integral calculus course using web‐based learning In WSEAS International Conference. Proceedings. Mathematics and Computers in Science and Engineering (No. 7). Athens, Greece: World Scientific and Engineering Academy and Society. [Google Scholar]
  40. Harvey, S. (2003). Building effective blended learning programs. Educational Technology, 43(6), 51–54. [Google Scholar]
  41. Hrastinski, S. (2019). What do we mean by blended learning? TechTrends, 63(5), 564–569. [Google Scholar]
  42. Hsu, L. L. (2011). Blended learning in ethics education: A survey of nursing students. Nursing Ethics, 18(3), 418–430. [DOI] [PubMed] [Google Scholar]
  43. Hsu, L. L. , & Hsieh, S. I. (2011a). Effects of a blended learning module on self‐reported learning performances in baccalaureate nursing students. Journal of Advanced Nursing, 67(11), 2435–2444. [DOI] [PubMed] [Google Scholar]
  44. Hsu, L. L. , & Hsieh, S. I. (2011b). Factors associated with learning outcome of BSN in a blended learning environment. Contemporary Nurse, 38(1–2), 24–34. [DOI] [PubMed] [Google Scholar]
  45. Hubackova, S. , & Semradova, I. (2016). Evaluation of blended learning. Procedia‐Social & Behavioral Sciences, 271, 551–557. [Google Scholar]
  46. Hughes, G. (2007). Using blended learning to increase learner support and improve retention. Teaching in Higher Education, 12(3), 349–363. [Google Scholar]
  47. Iverson, K. M. , Colky, D. L. , & Cyboran, V. L. (2005). E‐learning takes the lead: An empirical investigation of learner differences in online and classroom delivery. Performance Improvement Quarterly, 18(4), 5–18. [Google Scholar]
  48. Johnson, G. B. (2013). Student perceptions of the flipped classroom. Doctoral dissertation. Vancouver, BC: University of British Columbia. [Google Scholar]
  49. Jones, A. , Kukulska‐Hulme, A. , & Mwanza‐Simwami, D. (2006). Portable learning‐experiences with mobile devices. Journal of Interactive Media in Education, 2005(2), 19. [Google Scholar]
  50. Jones, K. T. , & Chen, C. C. (2008). Blended‐learning in a graduate accounting course: Student satisfaction and course design issues. Accounting Educators' Journal, 18, 15–28. [Google Scholar]
  51. Kim, M. K. , Kim, S. M. , Khera, O. , & Getman, J. (2014). The experience of three flipped classrooms in an urban university: An exploration of design principles. Internet and Higher Education, 22, 37–50. [Google Scholar]
  52. Kim, S. D. (2014). Effects of a blended learning program on ethical values in undergraduate nursing students. Journal of Korean Academy of Nursing Administration, 20(5), 567–575. [Google Scholar]
  53. Kintu, M. J. , Zhu, C. , & Kagambe, E. (2017). Blended learning effectiveness: The relationship between student characteristics, design features and outcomes. International Journal of Educational Technology in Higher Education, 14(1), 7. [Google Scholar]
  54. Kong, S. C. (2014). Developing information literacy and critical thinking skills through domain knowledge learning in digital classrooms: An experience of practicing flipped classroom strategy. Computers & Education, 78, 160–173. [Google Scholar]
  55. Kustijono, R. , & Zuhri, F. (2018). The use of Facebook and WhatsApp application in learning process of physics to train students' critical thinking skills In IOP Conference Series: Materials Science and Engineering (Vol. 296, No. 1, p. 012025). Bristol, UK: IOP Publishing. [Google Scholar]
  56. Lim, D. H. , & Morris, M. L. (2009). Learner and instructional factors influencing learning outcomes within a blended learning environment. Journal of Educational Technology & Society, 12(4), 282–293. [Google Scholar]
  57. Lotrecchiano, G. R. , McDonald, P. L. , Lyons, L. , Long, T. , & Zajicek‐Farber, M. (2013). Blended learning: Strengths, challenges, and lessons learned in an interprofessional training program. Maternal and Child Health Journal, 17(9), 1725–1734. [DOI] [PubMed] [Google Scholar]
  58. Mason, G. S. , Shuman, T. R. , & Cook, K. E. (2013). Comparing the effectiveness of an inverted classroom to a traditional classroom in an upper‐division engineering course. IEEE Transactions on Education, 56(4), 430–435. [Google Scholar]
  59. Melton, B. F. , Chopak‐Foss, J. , & Raychowdhury, S. (2008). Using blended learning in health education instruction. Georgia Association of Health, Physical Education, Recreation and Dance Journal, 41(3), 22. [Google Scholar]
  60. Mestan, K. (2019). Create a fine blend: An examination of institutional transition to blended learning. Australasian Journal of Educational Technology, 35(1), 70–84. [Google Scholar]
  61. Muzyk, A. J. , Fuller, S. , Jiroutek, M. , Grochowski, C. O. C. , Butler, A. C. , & May, D. B. (2015). Implementation of a flipped classroom model to teach psychopharmacotherapy to third‐year Doctor of Pharmacy (PharmD) students. Pharmacy Education, 15, 44–53. [Google Scholar]
  62. O'Flaherty, J. , & Phillips, C. (2015). The use of flipped classrooms in higher education: A scoping review. Internet and Higher Education, 25, 85–95. [Google Scholar]
  63. Owston, R. , York, D. , & Murtha, S. (2013). Student perceptions and achievement in a university blended learning strategic initiative. Internet and Higher Education, 18, 38–46. [Google Scholar]
  64. Park, J. Y. , Woo, C. H. , & Yoo, J. Y. (2016). Effects of blended cardiopulmonary resuscitation and defibrillation e‐learning on nursing students' self‐efficacy, problem solving, and psychomotor skills. Computers, Informatics, Nursing, 34(6), 272–280. [DOI] [PubMed] [Google Scholar]
  65. Peterson, D. J. (2016). The flipped classroom improves student achievement and course satisfaction in a statistics course: A quasi‐experimental study. Teaching of Psychology, 43(1), 10–15. [Google Scholar]
  66. Pierce, R. , & Fox, J. (2012). Vodcasts and active‐learning exercises in a “flipped classroom” model of a renal pharmacotherapy module. American Journal of Pharmaceutical Education, 76(10), 196. [DOI] [PMC free article] [PubMed] [Google Scholar]
  67. Pluta, W. J. , Richards, B. F. , & Mutnick, A. (2013). PBL and beyond: Trends in collaborative learning. Teaching and Learning in Medicine, 25(sup1), S9–S16. [DOI] [PubMed] [Google Scholar]
  68. Roach, T. (2014). Student perceptions toward flipped learning: New methods to increase interaction and active learning in economics. International Review of Economics Education, 17, 74–84. [Google Scholar]
  69. Ruckert, E. , McDonald, P. , Birkmeier, M. , Walker, B. , Cotton, L. , Lyons, L. , … Plack, M. (2014). Using technology to promote active and social learning experiences in health professions education. Journal of Online Learning, 18(4), 51–72. [Google Scholar]
  70. Ryan, M. D. , & Reid, S. A. (2015). Impact of the flipped classroom on student performance and retention: A parallel controlled study in general chemistry. Journal of Chemical Education, 93(1), 13–23. [Google Scholar]
  71. Sahin, A. , Cavlazoglu, B. , & Zeytuncu, Y. E. (2015). Flipping a college calculus course: A case study. Journal of Educational Technology & Society, 18(3), 142–153. [Google Scholar]
  72. Shorey, S. , Kowitlawakul, Y. , Devi, M. K. , Chen, H. C. , Soong, S. K. A. , & Ang, E. (2018). Blended learning pedagogy designed for communication module among undergraduate nursing students: A quasi‐experimental study. Nurse Education Today, 61, 120–126. [DOI] [PubMed] [Google Scholar]
  73. Suana, W. , Distrik, I. W. , Herlina, K. , Maharta, N. , & Putri, N. M. A. A. (2019). Supporting blended learning using mobile instant messaging application: Its effectiveness and limitations. International Journal of Instruction, 12(1), 1011–1024. [Google Scholar]
  74. Sugar, W. , Martindale, T. , & Crawley, F. E. (2007). One professor's face‐to‐face teaching strategies while becoming an online instructor. Quarterly Review of Distance Education, 8(4), 365–385. [Google Scholar]
  75. Sung, Y. H. , Kwon, I. G. , & Ryu, E. (2008). Blended learning on medication administration for new nurses: Integration of e‐learning and face‐to‐face instruction in the classroom. Nurse Education Today, 28(8), 943–952. [DOI] [PubMed] [Google Scholar]
  76. Terry, N. , Owens, J. , & Macy, A. (2001). Student performance in the virtual versus traditional classroom. Journal of the Academy of Business Education, 2(1), 1–4. [Google Scholar]
  77. Throne, K. (2003). Blended learning: Hoe to integrate online & traditional learning. Sterling, VA: Korgan Page Limited. [Google Scholar]
  78. Tune, J. D. , Sturek, M. , & Basile, D. P. (2013). Flipped classroom model improves graduate student performance in cardiovascular, respiratory, and renal physiology. Advances in Physiology Education, 37(4), 316–320. [DOI] [PubMed] [Google Scholar]
  79. Tynan, B. , Ryan, Y. , & Lamont‐Mills, A. (2015). Examining workload models in online and blended teaching. British Journal of Educational Technology, 46(1), 5–15. [Google Scholar]
  80. Vernadakis, N. , Antoniou, P. , Giannousi, M. , Zetou, E. , & Kioumourtzoglou, E. (2011). Comparing hybrid learning with traditional approaches on learning the Microsoft Office Power Point 2003 program in tertiary education. Computers & Education, 56(1), 188–199. [Google Scholar]
  81. Vertejee, S. , Somani, R. , Allana, S. , & Dias, J. M. (2015). Students' cognitive engagement in "Care of Elderly Course" using blended learning methodologies. International Journal of Nursing Education, 7(3), 23. [Google Scholar]
  82. Wang, M. J. (2010). Online collaboration and offline interaction between students using asynchronous tools in blended learning. Australasian Journal of Educational Technology, 26(6). [Google Scholar]
  83. Wilson, D. , & Smilanich, E. M. (2005). The other blended learning: A classroom‐centered approach. Hoboken, NJ: John Wiley & Sons. [Google Scholar]
  84. Woltering, V. , Herrler, A. , Spitzer, K. , & Spreckelsen, C. (2009). Blended learning positively affects students' satisfaction and the role of the tutor in the problem‐based learning process: Results of a mixed‐method evaluation. Advances in Health Sciences Education, 14(5), 725. [DOI] [PubMed] [Google Scholar]
  85. Yılmaz, M. B. , & Orhan, F. (2010). The use of Internet by high school students for educational purposes in respect to their learning approaches. Procedia‐Social and Behavioral Sciences, 2(2), 2143–2150. [Google Scholar]
  86. Yu, W. , & Du, X. (2019). Implementation of a blended learning model in content‐based EFL curriculum. International Journal of Emerging Technologies in Learning, 14(5), 188. [Google Scholar]
  87. Zacharis, N. Z. (2015). A multivariate approach to predicting student outcomes in web‐enabled blended learning courses. Internet and Higher Education, 27, 44–53. [Google Scholar]

Articles from Nursing Open are provided here courtesy of Wiley

RESOURCES