International Journal of Interactive Mobile Technologies (iJIM) – eISSN: 1865-7923 – Vol. 13, No. 12, 2019


Paper—Designing a Theoretical Integration Framework for Mobile Learning 

Designing a Theoretical Integration Framework for 
Mobile Learning 

https://doi.org/10.3991/ijim.v13i12.10841 

Y. Zidoun (*), R. Dehbi, M. Talea, F. El Arroum
Hassan II University of Casablanca, Casablanca, Morocco 

youness.zidoun@gmail.com 

Abstract—New technologies are rapidly changing mobile learning and mak-
ing it difficult to control. In addition to educational factors and learning content, 
a modern mobile learning system must take into account the technical and per-
sonal aspects of learning, the devices and aspects related to its evolution and in-
teroperability. Teaching on the other hand has also evolved involving more 
flexibility in tasks and learning stages, thus using modern technologies that of-
fer more alternatives now. In addition, such tasks may be specific to the learn-
ing content as well as the learning context or furthermore the learner's environ-
ment. Traditionally, mobile platform design relies on the skills of a mobile de-
veloper whose knowledge allows him to design mobile applications that are 
useful to users. But with mobile learning, the design phase involves more than 
just mobile development skills. For example, if you are designing a platform for 
practical work, the instructors responsible for the training should be involved. 
However, the empirical results show that educators do not integrate technology 
effectively into their curricula. To enable these instructors to develop mobile 
learning platforms, it is important to facilitate their integration through a theo-
retical model that will take into account all the ingredients necessary to com-
plete this learning and to balance them in order to ensure its efficiency. In this 
study authors used a thematic synthesis methodology to present a framework 
for mobile devices integration in learning. They focused on three models that 
they think are the most cited in the field of ICT (information and communica-
tion technologies) integration in learning. The five-axis framework consists of 
 enriching the TPACK framework (Technological Pedagogical Content 
Knowledge model in order to more precisely address mobile learning by cover-
ing the following parts: pedagogy, content, mobile technology, learning envi-
ronment and learner’s profile. It describes relatively in depth the various factors 
involved as well as the effective interconnection to be ensured to achieve an op-
timal and efficient integration of m-learning. Balancing those five parts will be 
a matter of plural reflection when designing or consulting on a mobile learning 
platform. 

Keywords—Mobile learning, frameworks, integration model 

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https://doi.org/10.3991/ijim.v13i12.10841
https://doi.org/10.3991/ijim.v13i12.10841
mailto:youness.zidoun@gmail.com
mailto:youness.zidoun@gmail.com


Paper—Designing a Theoretical Integration Framework for Mobile Learning 

1 Introduction 

As its transcending all aspects of learning, mobile learning has been defined differ-
ently by researchers. Shorten in the literature as M-learning or mlearning, it represents 
any kind of learning that occurs when the learner is not at a predetermined fixed loca-
tion, or learning that occurs when the learner takes advantage of the learning opportu-
nities offered by mobile technologies [1]. Many important opportunities are provided 
to users through mobile learning as ownership and personalized control of learning 
process, learners are more comfortable with their own mobile device and less prepara-
tion is needed for learning [2] [3]. Despite all these advantages, there is major empiri-
cal evidence proving that mobile learning has been poorly used in many education 
sectors and research have tended to be more centered about the technical aspects of 
the tools and applications than of the learning approach itself. Integration frameworks 
for mobile learning will enhance its usage, taking to account all aspects of this learn-
ing method including learner’s perception about it.  

This paper investigates different theories and scientific evidence of technology in-
tegration in learning to present an m-learning integration framework. First, a brief 
exposition of the two major scientific current of mobile learning definition is present-
ed followed by a review of technology integration frameworks in general then the 
ones centered specifically on m-learning. While acknowledging all identified features 
in other frameworks as important in mobile learning, an enriched model based on the 
TPACK framework is proposed highlighting a new unique combination of distinctive 
characteristics of current mobile pedagogy to bring a more detailed insights to the 
literature on m-learning. As a conclusion a Webview rendering architecture is finally 
presented to explore the potential experimentation of this theoretical framework. 

2 Background 

Several descriptions of m-learning are present in the literature, but they all take in-
to consideration the close link between the use of mobile devices and learning: the 
learning process mediated by a mobile device [4]. M-learning can be identified for 
this paper as a method of learning that enables learners to access learning materials 
anywhere and anytime using mobile technologies and the Internet [5] [6] [7]. Howev-
er, how to integrate these devices into learning is a thorny issue [8].  

Designed to make it easier for those planning to integrate mobile applications into 
higher education MIT has developed the MIT mobile framework for educational insti-
tutions [9]. Moodbile is also a framework helping integration of multiple learning 
applications into learning management systems [10]. As valuable and informative as 
they are, these frameworks focus precisely on the integration of technology into other 
technological systems and not on broader aspects such as educators, learner profiles 
or contexts of learning. 

Many researchers [11] [12] [4] have used activity theory to analyze individuals' 
development practices and processes, while considering individual and social influ-
ences in the use of mlearning. Uden has developed a framework for mobile applica-

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

tion design for mlearning. While drawing partly from Vygotsky's work on mediation 
and the proximal developmental area, Koole has designed the Framework for the 
Rational Analysis of Mobile Education (FRAME). The work of Kearney et al extends 
Koole's framework, including an understandings of "mobile pedagogy", which is 
based on the socio-cultural understandings presented in her model. For instructors, 
these frameworks do not offer a solid support considering how they should proceed 
with integrating m-learning into the curriculum. 

In line with the work done in the field, we have been interested in the general 
frameworks for the integration of technology into learning as a base of work. Three 
initial frameworks have been identified for further study: the Technological, Pedagog-
ical, and Content knowledge (TPACK) framework by Mishra and Koehler [14], the i5 
framework by Groff and Mouza [13] and the Substitution, Augmentation, Modifica-
tion and Redefinition (SAMR) framework by Puentedura [15].  

3 Integration Frameworks 

3.1 The i5 framework 

Essentially at the origin of this framework, Groff and Mouza (2008) discussed six 
central factors with their different variables. These factors interact with each other 
creating barriers to the successful integration of technologies into learning. The fac-
tors are: 

• Research and policy factors 
• Department / school factors 
• Factors associated with the teacher 
• Factors associated with the enhanced technology project 
• Factors associated with students 
• Factors inherent in the technology itself. 

 
Fig. 1. The i5 Framwork by Groff and Mouza (2008)  

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

The authors of the model explain the teachers' inability to handle all these factors, 
although they are all important. So, they focused on the four factors that can be influ-
enced by instructors through their i5 model which is a tool to help the mainstreaming 
of technologies in learning. 

3.2 The SAMR framework 

The SAMR model is schematized according to four main layers with two margins 
of evolution of learning. The first is a margin for improvement of the learning 
practice, with two layers (Substitution and Augmentation). At this level the 
technology is integrated to replace an old method without changing the functional 
aspect of the activity or improve the practice using the ease of technology introduced. 
The second margin is a transformation phase of educational activity. Indeed, 
represented in two layers (Modification and Redefinition), the learning activity is 
transformed this time through technology by changing its conceptual nature or by 
allowing the accomplishment of an entirely new tasks, inconceivable without the 
integrated technology. 

 

Fig. 2. The SAMR Framework by Puentedura (2009) 

3.3 The TPACK framework 

Based on the model of Shulman, the TPACK framework "the Technological, Peda-
gogical, and Content Knowledge" by Michra and Koehler, presents three circles in-
stead of two in the original model. The first two circles being pedagogy and content, 
Michra and Koehler have added technology as a facilitator of learning. Interactions 
between and among these bodies of knowledge are equally important to the model, 

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

represented as PCK (pedagogical content knowledge), TCK (technological content 
knowledge), TPK (technological pedagogical knowledge) The three circles need to 
interact collaboratively to enable effective integration of technology into learning 

 
Fig. 3. The TPACK Framework by Michra & Koehler (2006) 

Since its first publication in 2006, TPACK has become one of the most powerful 
theories in technology integration in education as the complex components described 
above remain open to a large range of educational circumstances. The flexibility of 
this model can be visible in the multiple junctions of its spheres allowing researchers 
to adapt it to various contexts and cases. 

4 Methodology 

In order to conceive our new m-learning integration model, authors adopted a the-
matic synthesis which allowed us to prioritize the transversal data collected previous-
ly through a manual search, including terms such as "mobile learning", "m-learning", 
"m-learning framework", "ICT integration", "technology in learning". Inspired by the 
method in Ref [16] and in the same scope of Crompton's work on mlearning integra-
tion frameworks [17], the researchers proceeded in three steps explained below: 

• First, authors identified the different themes and fields of our research from the 
studies collected before. Subsequently, they translated these results into a trans-

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

verse metric. At this stage the codification is rather descriptive but still similar to 
the texts previously contained in the studies reported. Next, they used support 
software for qualitative and combined research methods 

• The second step consisted in organizing the identified thematic codes into descrip-
tive themes in order to "develop and articulate relationships between the themes 
and associate conceptually similar themes with one another" [18] 

• The last step was to generate analytical themes. At this stage, the synthesis has 
crossed the limits of the initial content of the original studies proposing new per-
spectives and conceptualizations 

5 Findings and Discussion 

The thematic synthesis made it possible to identify new associations and concep-
tions between the different frameworks that we studied and considered as an entry 
into our new mobile learning integration framework. The framework proposed below 
is an enrichment of the TPACK model also inspired by Koole’s in [12] and Kearney 
et al.‘s [4] frameworks insofar as the close interaction of the new spheres identified 
can be considered as an efficient integration of mobile technology into learning. 

 

Fig. 4. The 5 axes m-learning integration framework 

5.1 Pedagogy: Method 

Mobile technologies can enable the development of innovative pedagogical prac-
tices such as student-centred pedagogies as well as several communication and prob-
lem-solving skills along with critical thinking skill [19]. The teaching method is the 
starting point of this 5 axes mlearning integration framework. With its influence on all 

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

other factors, the teaching method will guide the choices of an m-learning platform as 
well as the required levels of quality and performance. All means will decline them-
selves in service to this major factor to ensure the homogeneity of the platform with 
the educational purposes behind its design. The pedagogical method represents the 
way in which learning will be conveyed, for example: collaborative learning, prob-
lem-based learning, experiential learning. 

Laru insisted on pedagogically grounded instructional design to turn mobile tech-
nologies into effective tools for learning and collaboration [20]. The examples of 
mobile learning related to theories of learning are exposed in table 1 below [21]. 

Table 1.  Theory-based examples of mobile learning practices (rikala, 2015) 

Theory View of the Learning Process  Examples with Mobile Technologies  

Behaviorist 
Change in behaviour and observable 
actions facilitated through the reinforce-
ment of a specific stimulus and response  

Drill and feedback 
activities/classroom response 
systems 

Cognitivist Learning results from organizing and processing information effectively  
Performance support 

Constructivist 

Learners actively construct new ideas or 
concepts based on both their previous 
and current knowledge 

Approaches like experiential learning, 
participatory simulations, discovery 
learning, collaborative learning, situated 
learning mediated bu mobile devices 

Humanistic A personal act to fulfil potential Self-directed learning  

Connectivistic Connecting, navigating and filtering specialized nodes or information sources  
Social networking and media creation  

 
Educators should be totally aware of the consequences of their choices in this 

stage. All pedagogical methods don’t fit necessarily all contents or even all learners 
[22]. This sphere should be considered wisely along with the two adjacent ones in the 
process of designing new forms of teaching and learning through mobile technologies 
[23]. 

Nevertheless, another important factor at this level is the readiness of instructors to 
embrace the mobile technology as a tool for learning not just a support for learning's 
content. Instructors who are not familiar with mobile technologies will not be able to 
conceive learning activities through it or at least effective ones. The pedagogical 
method adopted in mlearning platforms should be open to adaptations through the 
progress of designing all the spheres even if it's the main influence on the global con-
ception. 

5.2 Content  

In this sphere, the same considerations of TPACK framework are noted. Content is 
the material intended to be taught to the learners, it must be compatible with the learn-
ing policy as well as the means made available. For instance, middle school courses 
are very different from undergraduates. Same as subjects of these courses, teaching 
science is very different from arts or history. The knowledge levels, theories and prac-
tices are designed differently.  

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The pedagogical content knowledge by Ref [24] covers much of the considerations 
at this level. It addresses “the core business of teaching, learning, curriculum, assess-
ment and reporting, such as the conditions that promote learning and the links among 
curriculum, assessment, and pedagogy”. 

From a basic or traditional content to a scenario or practical laboratory work, the 
teaching subject generates considerable design choices that can sometimes be a hin-
drance to integration. However, standardization of similar content can be a valuable 
asset to integrating technology into learning. This circle is generally thought and 
stopped at the same time as that of the teaching method in order to conceive strong 
relations and interactions guiding the other considerations for platform design. 

5.3 Mobile technology 

For its part, technology is the nerve of the expected system. By seeking to integrate 
it in an optimal and reasonable way, the technology must be well thought out and well 
framed. Especially with mobile technologies, making full use of its great potential for 
flexibility and ease of use is very delicate, which can sometimes be perceived as a 
complicated task by the instructors and automatically delegated to the technology 
specialists who will then always be consulted for platform administration and tech-
nical design. It is very important to mention that this sphere comes after pedagogy and 
content design. Educators have to first think about a quality course plan and then 
identify the mobile technologies to support that course. The use of mobile devices 
should not be the main purpose of the sessions plan; instead, it should be a good tool 
for making it work [25]. 

Wang, Wu, and Wang indicate in Ref [26] that mobile learning platforms should be 
user-friendly, easy to use, and intuitive to be appropriate, engaging, and accommodat-
ing to learners. Even their motivation can be frustrated if they encounter technological 
problems or if they are not attracted enough by the platform [27]. As observed by Ng 
and Nicholas in Ref [28], students became less engaged and excited. They thought 
that mobile technology didn't help them learn better or facilitate learning or even 
made it more interesting. The researchers find that students’ statements about the 
effectiveness of a mobile learning program decreased between the start of the program 
and 12 months later. 

In a way, the technology in general in such platforms guarantees the level of quali-
ty that will be presented to educators and learners. However, mobile technology is 
now experiencing a remarkable growth in terms of innovation which implies a com-
plexity also for the design of mobile learning platforms. A multi-criteria analysis and 
advanced comparative study between M-learning development approaches was con-
ducted before which can be of a great help to instructors [29]. 

To summarize, this circle encompasses all the technical part of the systems namely 
the platform architecture, the mobile development approach and the extensions and 
technical features. 

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

5.4 Learning environment 

The fourth factor that comes into play is the learning environment, which is all as-
pects of the learning context. This term is very important to note in a mobile learning, 
since it is an integral part of the identity of the latter. We share the same definition 
presented by Dey in Ref [30] concerning the context which is «any information that 
can be used to characterize the situation of an entity. An entity is a person, place, or 
object that is considered relevant to the interaction between a user and an application, 
including the user and application themselves». However, other terms are also at the 
same level of importance and must be considered equally namely time and space, 
after all they are the main elements that constitutes the context. Kearney et al. in Ref 
[4] placed the use of time and space at the centre of their framework, shedding light 
on several interesting interactions of collaboration, authenticity and personalization. 
But they also focused on context same as Koole in Ref [12] did, highlighting it in her 
FRAME model; she think that mobile learning experiences happen within a context of 
information. A dynamic context that encompasses primary, secondary and higher 
education or corporate learning environments, as well as formal and informal learning 
to classroom or distance learning and field studies [31]. 

According to Rikala in Ref [27] Mobile learning can expand the learning environ-
ment meaningfully into authentic contexts, but “the challenges in creating a mobile 
learning environment may lead to situations in which the devices are employed only 
for enhancement-level usage where a computer, booklet, or handout is replaced with a 
ready-made application”. He stated that decisions concerning the learning environ-
ment can have direct influence on the formality and spontaneity of learning experi-
ences. Chu in Ref [32], for instance, argued that mobile learning in authentic contexts 
is not always a great success. He thinks it is important to design different learning 
strategies and to invent new ones that consider the particularities of mobile learning. 

Learning environment constitutes the core of a platform design that’s what make 
its creation challenging. laru's study in Ref [33] highlights several important elements 
for the success of a mobile assisted collaboration and the first of them is the careful 
design of the learning environment for group interaction, the second is the provision 
of scaffolding and also support from educators. Mobile learning platforms can offer a 
variety of services; therefore coordination is crucial, linking different contexts and 
optimizing learning. Big part of that is initiated through context-awareness. 

Schilit, et al. in Ref [34] introduced first the term "context-aware", they think that 
context-aware applications can simply adapt to the context. Byun and Cheverst in Ref 
[35] define it as a system that can extract, interpret and especially adapt to different 
contextual information. Generally in literature, context-aware is mentioned as con-
text-sensitive, situated, contextual, adaptive, located, etc. 

5.5 Learner’s profile 

Part of the bigger picture that is learning context, the learner profile is a key ele-
ment of context consideration. This last circle can be considered as an extension of 
the previous one thus closing the aspect of the context in its entirety. The learner pro-

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file falls into the second category of learning context modelling, being divided in 
general in two parts which are the learning context and the mobile context [36]. The 
learner profile may include and is not limited to [37] [38]: 

• The competency profile of the learner: with all the knowledge, skills and possible 
attitudes, role 

• The semi-permanent personal characteristics of the learner: containing the learning 
style, the different needs and potential learning interests, physical disabilities or 
other personal aspects  

Yau and Joy in Ref [39] proposed a personalized mobile learning application based 
on m-learning preferences where learner profile consists of an initial simple question-
naire which is generated on one-time basis for learners before they commence with 
their learning activities in order to get their m-learning preferences. Data are stored 
into the application and an option to change preferences is allowed although generally 
they are more likely static and set all for once. They adopted three main preferences to 
be considered as inputs, namely location of study, level of noise/distractions and the 
time of day. All of them will be appreciated based on three levels (strong, medium or 
weak) describing the learner feelings towards them. The questionnaire conducted in 
their study were very similar to Felder and Silverman in Ref [40] and Honey in Ref 
[41] learning preferences/styles questionnaires designed to return the learning styles 
of learners prior to the use of mobile learning or web-based applications. 

Personalization mechanisms are one of the main considerations at this stage also. 
The latter makes it possible to manage features such as self-regulation, personaliza-
tion of content, learner’s choices and tendencies. This concerns can be found in both 
[12] and [4] frameworks. 

6 Experimentation 

To further examine the efficiency of this new framework, system architecture is 
proposed to help adapt an existing LAMS (Learning Activity Management System) 
platform to the mobile environment through this latter. As an integral part of an LMS 
(Learning Management System) generally, these systems can very well run separately 
too. This type of platforms allows building interactive game-informed content, educa-
tional activities and simple educational games. This experimentation will be hosted as 
an R&D project of Mohammed VI University of health science since they expressed 
their real need to change the old way of clinical reasoning teaching and learning. 

The main objective through this experiment is to validate the new framework for 
mobile learning integration through the evaluation of its effectiveness to support crea-
tion, adaptation and improvement of mobile learning platforms. Exploring new fields 
of exploitation of mobile technologies in learning is also part of this experiment. 
Throughout the period of research, mobile learning was rare or poorly stated on litera-
ture addressing healthcare sciences learning. So that concern motivated this experi-
mentation also to enrich that field of research. 

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

6.1 Why a LAMS and not LMS? 

Simply because the idea of adapting and integrating mobile devices and education-
al applications with an LMS has already been explored [42], and since they have prac-
tically similar architectures, the idea of mobile adaptation for LAMS presents more 
interesting challenges to such a mobile implementation. 

6.2 OpenLabyrinth 

Our choice fell on a very interesting platform called OpenLabyrinth, which is an 
online Activity Management System that allows users to create interactive and in-
formative educational activities, such as virtual patients, simulations, games, mazes 
and algorithms. It is mostly compared to a flexible online story, similar to the Choose 
Your Own Adventure style of book. Depending on the decisions the learner makes or 
the path he or she chooses, the consequences will be different. 

Launched at the University of Edinburgh in 2004, the project OpenLabyrinth 
aimed to change in a way the expensive and cyclical development of computer-based 
learning packages using tools such as Flash, Adobe's Director and Authorware. The 
main purpose behind it was to design an intuitive and easy to use tool, capable to 
support as many types of case-based activity designs as possible requiring minimal 
time for new case-based activities development [43]. 

This LAMS offers very elaborated functionalities like a visual editor of virtual pa-
tient case in the form of a labyrinth which schematizes the different potential paths for 
the learners, and like an LMS, OpenLabyrinth offers authentication as well as a dis-
cussion forum and several other components. 

6.3 Method 

Having the web-based version submitted to tests by administrators, educators and 
learners. Data was collected through a post-survey and interviews to identify specific 
needs for mobile adaptation design. The results were aggregated into several consid-
erations, which were then integrated based on the 5 axes m-learning integration 
framework into a system design to form mobile-based adaptation. The steps followed 
in the research model of the Mobile Clinical Cases Learning System included: 

Pedagogy (Method): Virtual scenarios are core concept of the OpenLabyrinth 
platform. Based more generally on a sort of PBL (problem-based learning) evolution, 
SBL (Scenario-based learning) is a complex combinations of learning experiences, 
resources and tools constructed in a specific way in order to address the learners’ 
needs. Typically, scenario-based learning (SBL) can be defined as support of active 
learning strategies such as problem-based or case-based learning through interactive 
scenarios. Learners will choose an individual path through an ill-structured or com-
plex problem that should be solved. They will feel the real-world context through a 
well designed storyline in which they have to apply their problem solving skills, prior 
knowledge of the subject and critical thinking. Many feedback opportunities and hints 

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

will be provided depending on the decisions they will be making at each level in the 
process. 

Content: It had to be clear that OpenLabyrinth can tackle and explore any educa-
tional problem and not just virtual patients. However, virtual patients will fulfil the 
need expressed by the great majority of educators and learners interviewed as men-
tioned before. In this case study, virtual patient will replace the old way of teaching 
clinical reasoning which was a classic power point. Another work of collection and 
adaptation to the platform was performed with the help of educators to help designing 
scenarios. A virtual patient is "an interactive computer simulation of real clinical 
scenarios for the purpose of training, education or medical evaluation" [44]. Many 
designs are possible through the platform, however two of them are the most common 
and powerful when it comes to healthcare science teaching and learning namely: line-
ar and branched designs. For instance linear designs can facilitate medical protocols 
learning while branched ones could enhance clinical reasoning throughout advanced 
complexes scenarios. Three themes are mostly chosen to deliver virtual patients de-
signs; storytelling, simulation and gaming. Storytelling allows learners to explore 
roles and patterns, which progresses over time. As for the simulation, it ensures 
grounding in real context. Gaming manages the means by which virtual patients offer 
to learners the possibility to try different strategies to solve the case respecting a well-
defined set of rules. 

Mobile Technology: At this stage more freedom was possible considering the sur-
vey results early mentioned. although, three large considerations had to be respected 
for the design of the mobile application to meet the initial expectations namely ease of 
use, interoperability and full access to all or the majority of the web-based features of 
the platform. A multi-criteria analysis and Advanced Comparative Study between M-
learning Development Approaches was conducted before, helping instructors choose 
between native, web and hybrid development [29]. The better scoring approach will 
be used for this mobile adaptation which is hybrid conception. Considered as one of 
the most powerful frameworks ionic v2 was used to develop this application. Future 
administrators of the platform proposed that design of the application should be very 
simple since it's just an adaptation for mobile and not a complete conception. So a 
decision was made to keep everything as it is on the web based and design a webview 
simply that will be rendering the content and making it easy to encapsulate navigation 
through the platform for different mobile operating systems. Architecture below ex-
plains the approach adopted for the Mobile Clinical Cases application. 

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Fig. 5. Architecture of the Mobile Clinical Cases application 

Learning Environment: The historical context for teaching clinical reasoning has 
been a major point of divergence at this level of design. Being less skilled in ICT 
manipulation, a large part of the educators supposed to become referents of their vir-
tual patients cases were rather sceptical for a formal adoption of this type of learning. 
They were not comfortable to switch directly to learn with the application on class, 
they were discouraged when they discovered the huge efforts they will be making to 
adjust their old power point presentations, also some of them were simply not ready to 
change their way of teaching. In the other hand learner's were very enthusiastic to 
embrace this new way of learning, especially when they discovered that pathways are 
different for each player and that they can play the cases as much as they wish. The 
idea of discussing the cases on the forum was a very positive point too. The final 
decision was made to keep the learning informal at least for a testing period and may-
be adopt it formally later for fifth year medical students and third year of nursing as a 
tool to keep their knowledge updated when they are on clinical rotations. All context-
awareness aspects will be handled later on as an improvement process of the platform, 
after gathering enough data. Source code will be enhanced on server side and new 
distributions of the application will be offered as simple upgrades for users. 

Learner's Profile: As stated above, it was decided to target medical students as 
well as nursing students. Considering the differences of knowledge levels as well as 
the personalized content for each profile, the management of the learner's profile is 
already present on the server side mostly on a standard manner (classic authentication 
with login and password). Many categories of profiles are presented for the adminis-
trator to choose from, offering specific access for each learner. Groups can be formed 
and assigned a number of virtual patients, tracking results is then possible for all 
groups separately. Part of the future upgrade will address learner aspects considering 
context-awareness. 

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6.4 Results 

Directly after authentication, users land on the home page shown in figure 6 which 
can give access to all the other pages: List of public and assigned cases, management 
of the profile, Forum & discussion, personal collection of VP cases, Scenarios as-
signed. 

 
Fig. 6.  MCC Home page 

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The mobile clinical cases application offered a new workflow on the platform. The 
first step in this learning process is the creation of the different user profiles by the 
main administrator. Then, referring authors create cases and build content with all the 
necessary resources, such as CT scans, blood tests, multimedia. Administrators as 
well as referring authors have the right to create new cases, edit respective data and 
delete them. Authors although, have only permission to display data of their own 
cases. The case may also represent a scenario (set of cases), which may include sever-
al related learning topics. Learners assigned to different cases individually or orga-
nized in groups can start the scenario only after completing the pre-test. Then, they 
play the case until the final result of their clinical reasoning by making a precise diag-
nosis of the case. The discussion forum remains accessible to those who have not 
passed the pre-test to discuss and collaborate on the case and the concepts discussed 
in it. Finally after finishing the post-test which is approximately same as the pre-test, 
learners can check the summary of their decisions on the entire pathway and the feed-
back of the quiz in order to improve their skills on the subject the next time. Figure 7 
show this new workflow while figure 8 presents the navigation diagram. 

 
Fig. 7. Mobile Clinical Cases application workflow 

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Paper—Designing a Theoretical Integration Framework for Mobile Learning 

 
Fig. 8. Navigation diagram 

7 Conclusion 

Mobile learning introduces great opportunities for the enhancement of collabora-
tive learning by offering more flexibility and personalization of learning and allowing 
it to be more student-centred. However, this type of learning is still underestimated or 
not used effectively into curriculums. The five axes m-learning integration framework 
aims to propose a thinking guide for mobile devices integration in learning curricu-
lums. This framework can be correlated with other models such as the ADDIE model 
(Analysis, Design, Development, Implementation, and Evaluation) in order to define 
in details the aspects at stake for optimal integration. The main purpose of this study 
is to help educators and instructors with poor technology knowledge to consider every 
aspect involved in mobile learning systems integration. The experimentation is still 
running while researchers are collecting data to further ameliorate the mobile applica-
tion. Feedback from researchers and educators on the impact of this new framework 
would be very valuable in order for authors to evaluate the efficiency of their model 
in various fields of learning. Further studies will be conducted, to first analyze users 
behaviour and data of the application, in a second time the limitations and the amelio-
ration of the framework if there is anything omitted before. 

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9 Authors 

Youness Zidoun is a PhD candidate at the Faculty of Sciences Ben M‘Sik, Infor-
mation Processing Laboratory Hassan II University, Morocco. His research fields: m-
learning frameworks, educational modeling, systems engineering. 

Rachid Dehbi is an associate professor at the Faculty of Science Aïn Chock, 
LIAD, Hassan II University, Morocco. His work focuses on e-learning and model 
driven engineering. 

Mohamed Talea is a professor of higher education at the Faculty of Sciences Ben 
M‘Sik and Research Director of Information Processing Laboratory, Hassan II Uni-
versity, Morocco. His major research interest is on Systems engineering and security 
of information systems. 

Fatima-Zohra Elarroum is a PhD candidate at the Faculty of Sciences Ben 
M‘Sik, Information Treatment and Modeling Laboratory Hassan II University, Mo-
rocco. Her research fields: Serious games, frameworks, educational modeling, sys-
tems engineering. 

Article submitted 2019-05-10. Resubmitted 2019-07-24. Final acceptance 2019-07-27. Final version 
published as submitted by the authors. 

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