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Australasian Journal of
Educational Technology

2008, 24(2), 137-142

Quantifying the reuse of learning objects

Kristine Elliott and Kevin Sweeney
The University of Melbourne

An Outstanding Paper Award recipient, ascilite Singapore 2007 Conference

This paper reports the findings of one case study from a larger project, which aims to
quantify the claimed efficiencies of reusing learning objects to develop e-learning
resources. The case study describes how an online inquiry project Diabetes: A waste of
energy was developed by searching for, evaluating, modifying and then integrating as
many pre-existing learning objects as possible into a learning design. Development
times for the reuse approach were recorded and compared to estimates for the de novo
development of an equivalent project. Outcomes suggest that considerable savings can
be made using the reuse approach; we estimate a threefold increase in time to develop
the Diabetes project using new objects in comparison to reuse. In this case study,
gaining permission from owners to reuse objects was not a barrier to reuse. However,
in some circumstances, being unable to source pre-existing objects to meet specific
requirements, or having to modify objects for reuse, could be problematic.

Introduction

One of the major developments in e-learning this decade has been the notion of reuse
of digital resources. This approach sees resources created for one particular learning
context, made available for reuse in another context. To be available, resources should
be searchable and accessible through the Internet (Koper, 2003). Having been derived
from object oriented models of software programming, the basic component of the
reuse approach is the learning object; small, discrete blocks of educational content that
can stand alone, be aggregated to form more complex learning objects, and/or
sequenced to create novel learning experiences. In this paper, we use Wiley’s (2002)
definition of a learning object as “any digital resource that can be reused to support
learning”.

Many benefits are expected from the reuse approach, including improved economic
and time efficiencies for resource development, and more effective learning and
teaching practices. However, the potential of the learning object economy is yet to be
realised. Practical difficulties that educators encounter while sourcing, adapting,
aggregating and sequencing learning objects (Koper, 2003), along with socio-cultural
attitudes towards collaboration and sharing resources have been identified as potential
barriers to the reuse approach (Littlejohn, 2005). Therefore, it is not entirely clear at
present whether it is feasible to expect educators to search for, re-purpose and
integrate existing learning objects into new teaching contexts, in order to create
effective teaching experiences.

In 2004, we began a project to create an online learning environment to enhance the
learning and teaching of biochemistry for second year students undertaking



138 Australasian Journal of Educational Technology, 2008, 24(2)

compulsory biochemistry units in their courses of Bachelor of Pharmacy and Bachelor
of Pharmaceutical Sciences, at a major Australian university. The resulting learning
environment contained a series of inquiry projects that covered a range of topics and
incorporated learner tasks and resources. The rationale behind the development was to
provide a flexible learning tool that focussed on biochemistry principles and concepts
that traditionally students had found difficult to grasp. More generally, the inquiry
projects were designed to promote understanding of the scientific method of inquiry
and development of life long learning strategies.

The development phase of this project was used as an opportunity to investigate
practical aspects of the learning object approach. Rather than developing the inquiry
projects de novo, they were created by searching for, aggregating and sequencing as
much pre-existing material as possible. The main objective of the study was to quantify
the claimed efficiencies of the reuse approach. To do this, the time taken to develop
projects using the reuse approach was documented and then compared to time
estimates for the de novo development of equivalent projects. Furthermore, we sought
to identify the types of problems that educators might encounter during the reuse
approach.

While reuse data was collected during development of all the inquiry projects
contained within the learning environment, this paper presents the findings of one
case study from the larger project; the development of the online inquiry project
Diabetes: A waste of energy.

Method

The process used to develop Diabetes: A waste of energy by reusing learning objects
(LOs) is described below. It is based on Koper’s (2003) top down approach that begins
with a learning design that LOs are searched for, and then integrated into.

Learning design

The first phase involved the development of a learning design, which specified tasks
students were required to perform, the resources and feedback supporting student
activities, and the sequence in which these events occurred. This phase was an iterative
process with gradual refinement of the design over time. While an in depth description
of the learning design is not the focus of this paper, it can essentially be described as a
template for inquiry projects in which students assume the role of professional
scientist to solve real life problems. The design incorporated a standardised scientific
inquiry process that students were guided through in order to solve these problems.
Theories of inquiry learning (de Jong, 2006), problem based learning (Barrows &
Tamblyn, 1980), and constructivist philosophy (Mayes & de Freitas, 2004) informed the
learning design. For further details about the learning design see Elliott, Sweeney and
Irving (in press).

Learning object requirements

With a clear understanding of the tasks, resources and supports composing the
learning design, the next phase was to broadly define the LOs required to develop a
project that addressed the biochemistry principles of bioenergetics and metabolism.
The real life problem of diabetes was an ideal way of introducing these principles to
students (e.g. “Guinevere, a type 1 diabetic, has collapsed at a party – investigate



Elliott and Sweeney 139

details of metabolism to discover why”). Therefore, LOs were required that would set
the context of the problem scenario, present the medical signs and symptoms of
diabetes, explain the biochemistry of normal and starvation metabolism, illustrate the
pathways involved in carbohydrate and lipid metabolism, indicate the sites of
metabolic pathways, demonstrate the role of insulin and what goes wrong in diabetes,
and show how diabetes is treated. LOs could also be used to allow students to reflect
on and test their understanding of the content.

Search

To find LOs, repositories such as ARIADNE, BIOME, Bitstream’s medical links,
CAREO, European Schoolnet, HEAL, LEARNet, MERLOT, TryScience and UCEL were
searched, followed by use of the internet search engine Google. Returned LOs were
evaluated for their pedagogical value (i.e. did their content match the learning
objectives of the project), technical suitability and compatibility with the interface
design. Some latitude was allowed during evaluation; objects that were not quite what
we had sought but where still suitable with minor modification were accepted.
Owners of selected LOs were contacted to obtain permission to reuse their materials.
While the time to obtain permission was not specifically recorded for each LO, it was
our experience that on average this process took 0.5 hr per LO. If existing objects could
not be found that met specific content requirements, then new objects were produced.
The time taken to search for, evaluate, and create all LOs used in the project was
recorded.

Production

LOs identified for use were embedded into HTML pages, along with original content
created by content experts. LOs requiring technical or educational changes were
modified at this stage. Generally, the Diabetes project consisted of HTML pages
containing images in GIF or JPEG format, Macromedia Flash animations and interactive
exercises programmed in Javascript. In terms of the larger study outlined in the
Introduction, all projects were incorporated into the empty shell of HTML templates
used to create The Virtual Laboratory, a pre-existing learning environment developed by
St Vincent’s Institute of Medical Research and the Victorian Department of Education
(Brack et al., 2003). This shell was chosen because its structure and function suited our
purposes and saved us from having to create another learning environment. A license
was obtained to use and modify The Virtual Laboratory shell. A professional multimedia
development unit dedicated to the development of educational technologies carried
out production. The time spent modifying and embedding all reused LOs into HTML
pages was recorded.

De novo development

An estimate was made of the time it would take to develop an equivalent project by
creating all LOs anew, instead of reusing materials. To do this, an experienced web
developer and educational designer together reviewed all the LOs in the Diabetes
project and estimated the time it would take to develop them anew. Estimates were
based on real development times documented for the production of similar materials
by the multimedia development unit. To avoid possible underestimation, a further
20% was added to estimates, resulting in an estimated time range. Time for tasks such
as educational design and writing original content were not included in the estimate as
these tasks were common to both the de novo and reuse methods of development.



140 Australasian Journal of Educational Technology, 2008, 24(2)

Results and discussion

Learning object use in the project Diabetes: A waste of energy is summarised in Table 1.
Searches returned a total of 77 LOs that were broadly consistent with our content
requirements. Following evaluation, 38 (49%) of these were selected for reuse.
Obtaining permission from owners to use their LOs was not an obstacle to reuse. Most
owners were willing to share their materials for non-commercial, education use,
particularly if appropriate acknowledgement was made. In this case study, permission
to reuse was rejected for one LO because the owner requested commercial terms of use
that were unsuitable to us. Two new LOs were created because of specific content
needs; a schematic diagram showing integration of all the metabolic pathways
involved in diabetes, and a close up image of a person monitoring blood glucose
levels. Therefore, the final proportion of reused LOs in the project was 95%.

Table 1: Learning object use in the project Diabetes: A waste of energy
Permission to reuseReturned from

search Selected Rejected Granted New Total

77 38 1 37 2 39

The types of LOs reused in the development of the Diabetes project are shown in Table
2. By far, images were the major type of LO reused (74%). In this case study, images
were used to set the context of the problem scenario, demonstrate metabolic pathways
and chemical structures, indicate sites of metabolic pathways, and graphically
illustrate hormone effects.

Table 2: Type of learning object used in the project Diabetes: A waste of energy
Image Interactive image Animation Tutorial Text Total

29 (74%) 1 (3%) 5 (13%) 2 (5%) 2 (5%) 39 (100%)

Of the 37 LOs reused, 36 (97%) required some form of modification to enhance their
educational value. This type of modification included addition of introductory text,
title, explanatory text, labels or arrows, and was primarily carried out to contextualise
the LO within the inquiry scenario. Technical modifications such as changing file
formats to one more suitable for the web (e.g. from TIFF to PNG), were made to 22
(60%) LOs.

Development times for Diabetes: A waste of energy are shown in Table 3. It took 14 hrs to
search for, evaluate and create the 39 LOs in the Diabetes project. The time taken to
obtain permission to reuse LOs was 19 hrs. The time taken to modify all reused LOs
was 15 hrs, which included 8 hrs for technical modifications and 7 hrs for educational
modifications. Therefore, in total these tasks took 48 hrs to complete (see Table 3). In
comparison, we estimated that an equivalent project developed by creating all LOs
anew, would be in the range of 133-160 hrs to develop (see Table 4).

Table 3: Development times (hrs) for the reuse method
for the project Diabetes: A waste of energy

ModificationSearch Permission Contexual Technical Total
14 (29%) 19 (40%) 7 (15%) 8 (16%) 48 (100%)



Elliott and Sweeney 141

Table 4: Development time for the project Diabetes: A waste of energy
Reuse (actual) De novo (estimate range)

48 (hrs) 133-160 (hrs)

Conclusions

In the context of developing the online inquiry project Diabetes: A waste of energy by
reusing LOs, it was not difficult to find LOs that were broadly consistent with our
needs. However, only 49% of returned LOs met our specific requirements. The search
and evaluate process that was used in this study did not always return suitable LOs the
first time around and needed to be repeated. This meant that many more LOs were
returned from searches, than were actually used in the final product. The search and
evaluate process accounted for 29% of development time.

Most LO owners willingly gave permission to reuse their resources for the non-
commercial, educational purpose of the inquiry project. However, the time taken to
contact and negotiate permissions from owners accounted for 40% of development
time. Many owners made specific requests, for example, as to how copyright
statements should be worded, or to be given access to the learning environment to see
how their resource(s) was being used.

The final proportion of reused LOs in the Diabetes project was 95%. There were only
two instances when pre-existing LOs could not be found to meet the evaluation
criteria. In this case study, the majority of LOs reused were classed as raw assets (74%),
containing no inherent educational context (Koppi et al., 2000). We found that it was
necessary to modify 97% of the pre-existing LOs to match the context of the inquiry
scenario. The time taken to recontexualise LOs accounted for approximately 15% of
development time. Furthermore, technical modifications needed to be made to 60% of
LOs, and accounted for 16% of development time. In total, modifications accounted for
31% of development time.

A comparison of the time taken to develop the inquiry project by reusing learning
objects, with an estimated range of time it would take for the de novo development of
an equivalent project, suggests that considerable savings can be made by reusing LOs.
We estimate that it would take a threefold increase in time to develop the Diabetes
project with newly created LOs as compared to the reuse approach. In this study, the
low proportion of LOs returned from searches that were actually reused (49%) would
have reduced the efficiency of the reuse approach. Therefore, there is potential for
greater savings as the adoption of e-learning catalogues and repositories become more
mainstream and searching for LOs becomes more efficient.

While acknowledging that production using the reuse approach was carried out by a
professional multimedia unit with experienced and skilled staff, and that development
times determined for the de novo approach were estimates based on actual times, this
study has provided an indication of the type of savings that educators can expect by
using the reuse approach. Moreover, it has identified certain circumstances (e.g. being
unable to source a pre-existing LO to meet specific requirements, having to modify
LOs for reuse) that may be problematic for some educators working without the
support of a professional multimedia unit.

Since this article was accepted for publication in Proceedings ascilite Singapore 2007, we
have continued to analyse the reuse data from other inquiry projects developed for the



142 Australasian Journal of Educational Technology, 2008, 24(2)

online learning environment. These results reveal that time efficiencies vary with the
nature of the project. While it appears that efficiency of the reuse approach is
dependent upon the subject matter and complexity of the LOs being sourced, future
research is required to clarify the influence of these factors.

Acknowledgements

The authors would like to thank Dr Helen Irving, Monash University and production
staff from the Biomedical Multimedia Unit, The University of Melbourne for their
involvement in the development of the program that formed the basis of this research.

References

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Elliott, K. A., Sweeney, K. & Irving, H. R. (in press). A learning design to teach scientific inquiry.
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Littlejohn, A. (2005). Community dimensions of learning object repositories. In H. Gross (Ed),
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Mayes, T. & de Freitas, S. (2004). Review of e-Learning theories, frameworks and models. JISC e-
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This article received an Outstanding Paper Award at ascilite Singapore 2007 Conference,
gaining the additional recognition of publication of a revised version in AJET. The
reference for the Conference version is:

Elliott, K. & Sweeney, K. (2007). Quantifying the reuse of learning objects.
In ICT: Providing choices for learners and learning. Proceedings ascilite Singapore 2007.
http://www.ascilite.org.au/conferences/singapore07/procs/elliott-k.pdf

Kristine Elliott and Kevin Sweeney are both Research Fellows in educational technology
at the Biomedical Multimedia Unit, Faculty of Medicine, Dentistry and Health Sciences,
University of Melbourne, 3010 Vic, Australia. Email: kaelli@unimelb.edu.au,
sweeneyk@unimelb.edu.au