# Influence of age on speech-in-noise and spatial processing abilities in middle-aged adults

**Authors:** Pavithra Nayak, Suresh Pillai, Hari Prakash Palaniswamy

PMC · DOI: 10.1371/journal.pone.0341169 · 2026-01-29

## TL;DR

Middle-aged adults' ability to understand speech in noise is more influenced by cognitive function than age, according to a study using hearing and cognition tests.

## Contribution

The study identifies cognition as the strongest predictor of speech-in-noise performance in middle-aged adults, despite no age-related differences in hearing scores.

## Key findings

- Cognitive function (MoCA) was the only significant predictor of speech-in-noise performance in co-located listening conditions.
- The older middle-aged subgroup showed reduced spatial advantage and lower cognitive scores, but no hearing differences were found.
- Variables like noise exposure, mental health, and physical activity did not significantly affect speech-in-noise performance.

## Abstract

Speech perception in noise (SPIN) difficulties are commonly associated with older adults, but emerging evidence suggests they may begin in midlife. This study investigated SPIN and spatial processing abilities in middle-aged adults using the Spatial Separation Sentence Test-Kannada (SSST-K). A cross-sectional design assessed 76 participants aged 41–60 years, divided into two groups (41–50 and 51–60 years). Assessments included: (1) the SSST-K to evaluate SPIN and spatial processing, (2) the Montreal Cognitive Assessment (MoCA) for general cognition, and (3) standardized questionnaires measuring noise exposure (NESI), physical activity (GPAQ), and mental status (PHQ-9). Hierarchical regression analysis revealed two key findings. First, in the co-located (0° azimuth) condition, cognition (MoCA) was the only significant predictor of SPIN performance, overshadowing age and other variables. Second, none of the tested variables predicted spatial advantage. Between-group comparisons showed no age-related differences in SPIN scores for the co-located condition, but the older subgroup (51–60 years) exhibited reduced spatial advantage and significantly lower MoCA scores. These results indicate that among the variables examined in middle-aged adults with self-reported normal hearing, cognitive function emerged as the strongest predictor of SPIN ability. However, the absence of audiometric verification, particularly extended high-frequency assessment, limits definitive conclusions about peripheral versus central contributions. The other variables, like noise exposure, mental health, and physical activity, had no significant influence. Future research with longitudinal designs and objective hearing assessment is needed to determine optimal ages and methods for SPIN screening in community and clinical settings.

## Full-text entities

- **Genes:** SPIN1 (spindlin 1) [NCBI Gene 10927] {aka SPIN, TDRD24}
- **Diseases:** SPIN (MESH:C535473), EHF (MESH:D006316), auditory processing decline (MESH:D001308), cardiovascular diseases (MESH:D002318), MoCA (MESH:D003072), depression (MESH:D003866), neurological and psychological disorders (MESH:D020018), MCI (MESH:D060825), speech understanding difficulty (MESH:D013064), auditory decline (MESH:D006311), difficulties in (MESH:D051346), tinnitus (MESH:D014012), hearing loss (MESH:D034381), peripheral hearing loss (MESH:C537626), Age-related hearing loss (MESH:D010024), MDD (MESH:D003865)
- **Chemicals:** EHF (-)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12854412/full.md

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Source: https://tomesphere.com/paper/PMC12854412