Just as the computational power of yesterday’s desktop computer has been miniaturized to fit inside your mobile phone, bioengineers have shrunk traditional laboratory instruments to the size of a dime. To assemble a “snap lab” like the one you see above, all scientists have to do is click together some plastic components in much the same way that kids snap together the plastic bricks in their toy building sets.
The snap lab, developed by an NIH-funded team led by Noah Malmstadt at the University of Southern California (USC) Viterbi School of Engineering, Los Angeles, is an exciting example of a microfluidic circuit—tiny devices designed to test just a single drop of blood, saliva, or other fluids. Such devices have the potential to make DNA analysis, microbe detection, and other biomedical tests easier and cheaper to perform.
Malmstadt’s cool design was born from his frustration with existing 2D microfluidic devices, which can be expensive and often take months to produce because they have to be built in a special “clean room,” a controlled environment with low levels of airborne dust, microbes, particles, and chemicals. His new modular microlab is made of 1-centimeter, transparent plastic cubes that are fabricated in a regular lab using a simple 3D printer. These cubes can be quickly snapped together by hand to form a wide range of configurations, enabling researchers to create their own custom-designed 3D microlabs in just a matter of hours .
In addition to convenience and cost savings, there are scientific advantages to this modular design approach. It allows scientists to mix, split, and route biological samples in various ways to combine them with particular reagents.
The views, opinions and positions expressed by these authors and blogs are theirs and do not necessarily represent that of the Bioethics Research Library and Kennedy Institute of Ethics or Georgetown University.