Semantic encoding during language comprehension at single-cell resolution.
Mohsen JamaliBenjamin L GrannanJing CaiArjun R KhannaWilliam MuñozIrene CapraraAngelique C PaulkSyndey S CashEvelina FedorenkoZiv M WilliamsPublished in: Nature (2024)
From sequences of speech sounds 1,2 or letters 3 , humans can extract rich and nuanced meaning through language. This capacity is essential for human communication. Yet, despite a growing understanding of the brain areas that support linguistic and semantic processing 4-12 , the derivation of linguistic meaning in neural tissue at the cellular level and over the timescale of action potentials remains largely unknown. Here we recorded from single cells in the left language-dominant prefrontal cortex as participants listened to semantically diverse sentences and naturalistic stories. By tracking their activities during natural speech processing, we discover a fine-scale cortical representation of semantic information by individual neurons. These neurons responded selectively to specific word meanings and reliably distinguished words from nonwords. Moreover, rather than responding to the words as fixed memory representations, their activities were highly dynamic, reflecting the words' meanings based on their specific sentence contexts and independent of their phonetic form. Collectively, we show how these cell ensembles accurately predicted the broad semantic categories of the words as they were heard in real time during speech and how they tracked the sentences in which they appeared. We also show how they encoded the hierarchical structure of these meaning representations and how these representations mapped onto the cell population. Together, these findings reveal a finely detailed cortical organization of semantic representations at the neuron scale in humans and begin to illuminate the cellular-level processing of meaning during language comprehension.
Keyphrases
- single cell
- working memory
- autism spectrum disorder
- rna seq
- prefrontal cortex
- advanced cancer
- spinal cord
- endothelial cells
- cell therapy
- high throughput
- induced apoptosis
- oxidative stress
- air pollution
- hearing loss
- white matter
- healthcare
- resting state
- stem cells
- gene expression
- genome wide
- brain injury
- spinal cord injury
- functional connectivity