Designing the Virtual Laboratory
This post was originally written for LabXchange and was published on April 29, 2019, on their website.
Hubble Studios has teamed up with LabXchange to design a virtual laboratory – a place where learners can have a real lab experience, practice scientific techniques, and perform a range of experiments.
A key priority for LabXchange was to provide learners with greater access to science. Part of this undertaking meant granting students access to laboratories with the necessary equipment. Hence, the idea for a virtual laboratory was born – a real lab experience with real lab techniques, at no cost.
LabXchange partnered with us to design and build these virtual laboratories – or simulations. To start, the team looked at the Amgen Biotech Experience (ABE) curriculum, with its well-tested content and a strong network of teachers. The challenge was to take this curriculum’s experiments and turn them into a range of online scientific simulations that could be used by both high school students and a wider audience.
While this particular set of simulations shows the technique to grow a protein (insulin, in this case), it also provides an opportunity to build out a library of scientific techniques. This includes micropipetting, gel electrophoresis, heat shock protocol, and plating techniques. From these simulations, more complex examples have been built for undergraduate students, including experiments in genome editing and stem cell function.
A crucial part of designing these simulations was to create an environment where students could actively participate in the scientific process, by experimenting, failing, and learning.
At the same time, it was important to introduce learners to proper scientific procedures, including working with a protocol and recording their observations in a lab notebook. The challenge was how to bring this simulation to life in a way that didn’t distract the students from recording their actions and observations. We also needed to find a balance between auto-populating the notebook with a record of the student’s actions while ensuring the student actively engages with the notebook by taking their own notes.
In line with these considerations, the notebook was included as part of each simulation’s interface, making it integral to how a student would navigate through the experiment. This digital lab notebook contained the context of the simulation, the materials used, a prediction by the user of the expected results, and the protocol. The notebook is also where the final results were recorded, and where students were asked to reflect on their experiment.
The protocol itself provided its own set of challenges. There needed to be freedom for students to make mistakes while also maintaining the same level of guidance students would have in a real lab.
Any mistakes also needed to lead to realistic results, so students can see the impact of each action and the importance of accuracy in a lab. To make this happen, decision trees were built for all the potential outcomes of what a student could do, given the variables of a simulation. This was an opportunity to collaborate closely with LabXchange’s team of experts and core ABE teachers to map out the outcomes, as well as hints and warnings to enrich the learning along the way.
Bringing it to life
Of course, it wasn’t only important to consider how the simulation would work, but also how it was going to look. The simulation needed to be realistic for the sake of scientific accuracy, but also take into account the functional limitations around a simulated lab experience. The chosen style was based on the LabXchange branding, with a game-like interface to display gamification elements – especially useful for levelling the simulations to account for students’ different range of prior knowledge and experience. At the same time, equipment was designed with enough detail so that students can equate it with their apparatus in real labs and easily transfer the skills they learn in the simulations.
The simulations needed to be built in a way that guaranteed the apparatus and their functions were reusable, and thus scalable. Hence, they were built directly in HTML5, which enabled coded algorithms to control how aspects of the simulation interacted, and how results were generated. It also allows the simulation to track students’ actions to give them accurate results and rich feedback. A joint effort by our team of learning designers, front-end developers, and user-experience designers brought a range of exciting simulations to life in HTML5. This was done iteratively, with extensive testing both internally within the team and externally by students and teachers to ensure the end product was accurate, intuitive, engaging, and contained real learning value.
Working with an incredible group of passionate ABE teachers, the team have created a scientifically accurate virtual lab experience for students from all backgrounds. We are excited to build the next set of simulations and expand the reach of biotechnology and science even further.
For a chat or a consultation, or just to find out more about the projects we’ve worked on, please get in touch.