Open-access Time perception and age

Percepção do tempo e idade

ABSTRACT

Our internal clock system is predominantly dopaminergic, but memory is predominantly cholinergic. Here, we examined the common sensibility encapsulated in the statement: “time goes faster as we get older”.

Objective  To measure a 2 min time interval, counted mentally in subjects of different age groups.

Method  233 healthy subjects (129 women) were divided into three age groups: G1, 15-29 years; G2, 30-49 years; and G3, 50-89 years. Subjects were asked to close their eyes and mentally count the passing of 120 s.

Results  The elapsed times were: G1, mean = 114.9 ± 35 s; G2, mean = 96.0 ± 34.3 s; G3, mean = 86.6 ± 34.9 s. The ANOVA-Bonferroni multiple comparison test showed that G3 and G1 results were significantly different (P < 0.001).

Conclusion  Mental calculations of 120 s were shortened by an average of 24.6% (28.3 s) in individuals over age 50 years compared to individuals under age 30 years.

time perception; age; timing; aging

RESUMO

Nosso sistema de relógio interno é predominantemente dopaminérgico, mas a memória é predominantemente colinérgica. Neste estudo, examinamos a assertiva comum que “o tempo passa mais rápido para pessoas mais velhas”.

Objetivo  Medir o intervalo de tempo 2 min contados mentalmente em pessoas de diferentes faixas etárias.

Método  233 pessoas saudáveis (129 mulheres) foram divididos em três grupos: G1, 15-29 anos; G2, 30-49 anos; e G3, 50-89 anos. Foi solicitado que contassem mentalmente, com os olhos fechados, a passagem de 120 s.

Resultados  Os tempos aferidos foram: G1, média = 114,9 ± 35 s; G2, média = 96,0 ± 34,3 s; G3, média = 86,6 ± 34,9 s. A comparação entre os tempos de G3 e G1 (teste de comparação múltipla ANOVA-Bonferroni) foi muito significante (P < 0,001).

Conclusão  Cálculo mental de 120 s foi encurtado em média 24,6% (28,3 s) em pessoas maiores que 50 anos quando comparado com pessoas menores que 30 anos.

percepção de tempo; idade; tempo; envelhecimento

The human body does not have time sensing receptors; thus, there is no association between time and sensory-specific systems1. We have receptors under the skin for sensing touch, temperature, pain, pressure, and vibration. In addition, we have proprioceptors in muscles and tendons, which continuously generate action potentials to the central nervous system with information about the length and tension of muscles; this signaling allows us to make accurate movements. We also have highly specialized sensory systems, such as vision, hearing, olfaction, and gustation, which provide us with environmental information. Although we are not endowed with time receptors2,3, our brains have an inherent ability to process time through the functions of neuronal mechanisms and neurotransmitters.

We carry watches to know the hour precisely, but we do not need similar devices to determine whether it is cold or whether a sound is loud or soft. Similarly, our perception of time refers to subjective experience and depends on an internal clock. The subjective duration of events may be based on brain units that accumulate over time4,5,6,7. It is commonly said that “time passes faster” in older people8, which may be due to central dopamine-related mechanisms and memory9,10. This study aimed to estimate the passage of time in different age groups, to test the truth of this saying.

METHOD

This study included 233 healthy subjects, including 129 women. Three groups were formed according to age: Group 1 comprised 86 subjects, aged 15-29 years; the mean age was 22.4 years. Group 2 comprised 76 subjects, aged 30-49 years; the mean age was 38.9 years. Group 3 comprised 71 subjects, aged 50-89 years; the mean age was 59.7 years. Each of the participants was asked to count mentally with eyes closed the passage of 120 s (2 min). When the participant finished, one of the examiners marked down the actual elapsed time; thus, the mental time or “brain clock” was compared with the actual time interval according to the clock. For instance, if a subject count mentally 120 s (“brain clock”) in just 90 s (“real clock”), he/she time perception is faster. For them, time goes faster. All subjects were conscious, fully oriented with no past history of neurological disease or memory complaints. In all cases, the examiners checked with them before the test if they had an understanding of time and the meaning of 1 second. The use of drugs, in general, was not a criterion for exclusion, because it is difficult to find older individuals that do not take medications. The use of anxiolytics, in small doses, and antidepressants, was accepted, but these individuals represented less than 10% of the study cohort. Individuals were also stratified by education level.

All data were entered in a worksheet and tabulated for the 3 age groups. Statistical analyses for multiple comparisons between groups were performed with the ANOVA-Bonferroni test. The study was approved by the local ethics committee, and all subjects signed informed consent forms.

RESULTS

Within each group, the times elapsed during mental counting followed a normal (Gaussian) distribution. Mean elapsed times were: G1, 114.9 ± 35 s; G2, 96.0 ± 34.3 s; and G3, 86.6 ± 34.9 s. Multiple comparisons with the ANOVA-Bonferroni test showed that G3 times were significantly different from G1 times (p < 0.001; Figure).

Figure
Mental perceptions of the passage of 120 s in different age groups. Group 1: aged 15-29 years; Group 2: aged 30-49 years; Group 3: aged 50-89 years. Values indicate the mean (upper line) and median (lower line) of each group; error bars indicate standard deviations.

DISCUSSION

Our data clearly confirmed the assertion that “time passes faster for older individuals”. We found that the mental perception of the passage of 120 s among older people (> 50 years) was significantly reduced compared to the perception in younger people (< 30 years). The difference between these age groups was 24.6% (28.3 s) for mean times and 28.4% (32.5 s) for median times. These data indicated that the perception of time passage was accelerated in aging. This phenomenon may be related to two mechanisms: (1) a lack of new experiences11 and (2) a reduction in dopamine neurotransmission9,10,12.

New experiences

The time it takes to learn something new (“the first time”) is always subjectively prolonged, such as a first sexual relationship, a first job, a first trip without parents, or the first experience of living away from home13. Novelty has a strong impact on memory. Generally, we can vividly remember the beginning of each new experience that occurred between ages 15 and 25 years. This may partly explain why a random day can seem longer for a child than an adult14. Most external and internal experiences are new to children, and most experiences are repetitive for adults.

Dopamine and neuropathways

The ability of our internal clock to estimate the passage of time depends on both attention and memory9. For example, estimating the time necessary to perform a given task requires both concentration and memorization of a sequence of information. Concentration depends on the function of dopamine neurotransmission in the basal ganglia. Memory depends on acetylcholine neurotransmission in brain areas related to memory in the hippocampal-prefrontal cortex axis2.

The neurotransmitter dopamine was associated with variations in time at the level of seconds and minutes6. Experimental studies have shown that rats can estimate time intervals up to 40 s, despite the removal of their entire cerebral cortex. Those findings indicated that time estimation must be a subcortical process6.

In humans, time intervals are generally overestimated with the use of stimulants and underestimated with the use of depressants and anesthetics. Patients with Parkinson disease, schizophrenia, or attention-deficit hyperactivity disorder, which are all associated with abnormalities in brain dopamine levels, typically exhibit abnormalities in time perception15,16. Stimulants that increase the function of dopamine in the brain have the effect of accelerating the perception of time. Conversely, antipsychotic drugs, or emotions of sadness and depression, block dopamine receptors and have the opposite effect17.

The consciousness of time develops during childhood, when we form the capacities for both attention and short-term memory. The integration of these capacities depend on the slow maturation of the hippocampus and prefrontal cortex18. For example, when we become accustomed to a certain time period, e.g., a class of 30 min, that time depends on memory (and the neurotransmitter, acetylcholine). Indeed, it does not take long for us to notice that a red traffic light is defective after it fails to turn green, because the memory of that time is stored9. On the other hand, when we are at a party and someone asks how long we have been there, we imagine a value in the absence of memory, and variations can be extensive (dependent on dopamine levels).

Imagined time also depends on behavioral mechanisms. The perception of time during a stressful or fearful situation seems much longer than the actual time that passes4,19,20. Terror movie scenes are imagined as lasting 2-fold, and sometimes 3-fold longer than the actual time that passes. This was demonstrated in a classic study, where people with arachnophobia were invited to look for spiders for 45 s – an activity that elicited intense fear; those individuals greatly overestimated the time elapsed13. Similarly, when someone becomes angry with the lengthy service in call centers, the time is substantially overestimated, frequently by two-fold.

Why does time seem to accelerate as we age?

The apparent rapidity of time is a major cognitive illusion8. When we are reminded of school holidays, or for example, when we learn to swim or fly a kite, the memory seems endless. But that is an illusion. Adulthood does not hold the constant, never-ending discovery of new things that is inherent in childhood. Also, the higher the demand required of a cognitive task, the greater the perceived duration. Thus, repeated stimuli appear briefer than new stimuli of equal duration. As a result, it is possible that learning new things can slow the internal sense of time. Moreover, among healthy individuals, aging is typically connected to reduced interest in learning new things that require great effort; thus, a reluctance to learn may contribute to an accelerated internal sense of timing.

In conclusion, we found a significant reduction in the mental perception of the passage of 120 s for older people compared to younger people. The reasons for this phenomenon may be explained by differences in dopaminergic and/or cholinergic pathways or the integration between these two pathways. Future studies should investigate these possibilities.

References

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Publication Dates

  • Publication in this collection
    Apr 2016

History

  • Received
    07 Oct 2015
  • Accepted
    29 Dec 2015
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