ABSTRACT
Memory, on multiple timescales, is critical to our ability to discover the structure of our surroundings, and efficiently interact with the environment. We combined behavioural manipulation and modelling to investigate the dynamics of memory formation for rarely reoccurring acoustic patterns. In a series of experiments, participants detected the emergence of regularly repeating patterns within rapid tone-pip sequences. Unbeknownst to them, a few patterns reoccurred every ~3 min. All sequences consisted of the same 20 frequencies and were distinguishable only by the order of tone-pips. Despite this, reoccurring patterns were associated with a rapidly growing detection-time advantage over novel patterns. This effect was implicit, robust to interference, and persisted for 7 weeks. The results implicate an interplay between short (a few seconds) and long-term (over many minutes) integration in memory formation and demonstrate the remarkable sensitivity of the human auditory system to sporadically reoccurring structure within the acoustic environment.
Patterns of sound such as the noise of footsteps approaching or a person speaking often provide valuable information. To recognize these patterns, our memory must hold each part of the sound sequence long enough to perceive how they fit together. This ability is necessary in many situations: from discriminating between random noises in the woods to understanding language and appreciating music. Memory traces left by each sound are crucial for discovering new patterns and recognizing patterns we have previously encountered. However, it remained unclear whether sounds that reoccur sporadically can stick in our memory, and under what conditions this happens. To answer this question, Bianco et al. conducted a series of experiments where human volunteers listened to rapid sequences of 20 random tones interspersed with repeated patterns. Participants were asked to press a button as soon as they detected a repeating pattern. Most of the patterns were new but some reoccurred every three minutes or so unbeknownst to the listener. Bianco et al. found that participants became progressively faster at recognizing a repeated pattern each time it reoccurred, gradually forming an enduring memory which lasted at least seven weeks after the initial training. The volunteers did not recognize these retained patterns in other tests suggesting they were unaware of these memories. This suggests that as well as remembering meaningful sounds, like the melody of a song, people can also unknowingly memorize the complex pattern of arbitrary sounds, including ones they rarely encounter. These findings provide new insights into how humans discover and recognize sound patterns which could help treat diseases associated with impaired memory and hearing. More studies are needed to understand what exactly happens in the brain as these memories of sound patterns are created, and whether this also happens for other senses and in other species.