BioTrojans: viscoelastic microvalve-based attacks in flow-based microfluidic biochips and their countermeasures.
Navajit Singh BabanJiarui ZhouKamil ElkhourySukanta BhattacharjeeSanjairaj VijayavenkataramanNikhil GuptaYong-Ak SongKrishnendu ChakrabartyRamesh KarriPublished in: Scientific reports (2024)
Flow-based microfluidic biochips (FMBs) are widely used in biomedical research and diagnostics. However, their security against potential material-level cyber-physical attacks remains inadequately explored, posing a significant future challenge. One of the main components, polydimethylsiloxane (PDMS) microvalves, is pivotal to FMBs' functionality. However, their fabrication, which involves thermal curing, makes them susceptible to chemical tampering-induced material degradation attacks. Here, we demonstrate one such material-based attack termed "BioTrojans," which are chemically tampered and optically stealthy microvalves that can be ruptured through low-frequency actuations. To chemically tamper with the microvalves, we altered the associated PDMS curing ratio. Attack demonstrations showed that BioTrojan valves with 30:1 and 50:1 curing ratios ruptured quickly under 2 Hz frequency actuations, while authentic microvalves with a 10:1 ratio remained intact even after being actuated at the same frequency for 2 days (345,600 cycles). Dynamic mechanical analyzer (DMA) results and associated finite element analysis revealed that a BioTrojan valve stores three orders of magnitude more mechanical energy than the authentic one, making it highly susceptible to low-frequency-induced ruptures. To counter BioTrojan attacks, we propose a security-by-design approach using smooth peripheral fillets to reduce stress concentration by over 50% and a spectral authentication method using fluorescent microvalves capable of effectively detecting BioTrojans.
Keyphrases
- single cell
- high glucose
- aortic valve
- high throughput
- finite element analysis
- circulating tumor cells
- subarachnoid hemorrhage
- global health
- abdominal aortic aneurysm
- mitral valve
- optical coherence tomography
- heart failure
- drug induced
- endothelial cells
- public health
- current status
- oxidative stress
- left ventricular
- aortic valve replacement
- atomic force microscopy
- living cells
- climate change
- high resolution
- atrial fibrillation
- aortic stenosis