Multiplexed temporal SWCNT biosensor combined with convolutional autoencoding identifies ALS-specific serum protein corona signatures

Amyotrophic lateral sclerosis (ALS) lacks a validated blood-based diagnostic, and the field is increasingly moving from single-molecule markers toward integrative, multi-component signatures. Here we present a liquid-biopsy strategy that transduces disease-dependent serum–nanoparticle interactions into a learnable near-infrared spectral phenotype. A sensor array of twelve DNA-functionalized single-walled carbon nanotube (SWCNT) chiralities, functionalized with (GT) ₆ ssDNA coupled with a deep learning model was tested on serum from 20 ALS patients and 19 age- and sex-matched controls (n = 39, TargetALS). Our multiplexed sensor design (12 SWCNT chiralities) and data acquisition strategy based on excitation–emission matrices acquired at three timepoints (0, 6, 24 h) was conceived to maximize sensor carried information. Indeed, we show that the array generates partially independent temporal dynamics across chiralities governed primarily by tube diameter. To decode this multiplexed, time-resolved signal, we trained a dual-objective convolutional autoencoder that jointly optimizes reconstruction and classification, achieving 84.6% cross-validated accuracy (AUC = 0.87). Selected latent features were reproducible across an independent same-subject experimental batch and correlated with serum neurofilament light chain, linking the spectral phenotype to a clinically relevant neurodegeneration marker. Mass spectrometry supported a molecular basis for discrimination, revealing an ALS-biased protein corona enriched in adaptive-immune and inflammatory proteins. Together, these results establish proof of principle that time-resolved, multi-chirality SWCNT spectral sensing can compress complex serum composition into a reproducible near-infrared biomarker signature for ALS.