Effects of dietary tryptophan and phenylalanine-tyrosine depletion on phasic alertness in healthy
adults - A pilot study
Sammanfattning
Background: The synthesis of the neurotransmitters serotonin (5-HT) and dopamine (DA) in the
brain can be directly altered by dietary manipulation of their relevant precursor amino acids (AA).
There is evidence that altered serotonergic and dopaminergic neurotransmission are both associated
with impaired attentional control. Specifically, phasic alertness is one specific aspect of attention that
has been linked to changes in 5-HT and DA availability in different neurocircuitries related to
attentional processes. The present study investigated the impact of short-term reductions in central
nervous system 5-HT and DA synthesis, which was achieved by dietary depletion of the relevant
precursor AA, on phasic alertness in healthy adult volunteers; body weight–adapted dietary
tryptophan and phenylalanine–tyrosine depletion (PTD) techniques were used.
Methods: The study employed a double-blind between-subject design. Fifty healthy male and female
subjects were allocated to three groups in a randomized and counterbalanced manner and received
three different dietary challenge conditions: acute tryptophan depletion (ATD, for the depletion of 5-
HT; N=16), PTD (for the depletion of DA; N=17), and a balanced AA load (BAL; N=17), which served as
a control condition. Three hours after challenge intake (ATD/PTD/BAL), phasic alertness was
assessed using a standardized test battery for attentional performance (TAP). Blood samples for AA
level analyses were obtained at baseline and 360 min after the challenge intake.
Results: Overall, there were no significant differences in phasic alertness for the different challenge
conditions. Regarding PTD administration, a positive correlation between the reaction times and the
DA-related depletion magnitude was detected via the lower plasma tyrosine levels and the slow
reaction times of the first run of the task. In contrast, higher tryptophan concentrations were
associated with slower reaction times in the fourth run of the task in the same challenge group.
Conclusion: The present study is the first to demonstrate preliminary data that support an association
between decreased central nervous system DA synthesis, which was achieved by dietary depletion
strategies, and slower reaction times in specific runs of a task designed to assess phasic alertness
in healthy adult volunteers; these findings are consistent with previous evidence that links phasic
alertness with dopaminergic neurotransmission. A lack of significant differences between the three
groups could be due to compensatory mechanisms and the limited sample size, as well as the
dietary challenge procedures administered to healthy participants and the strict exclusion criteria
used. The potential underlying neurochemical processes related to phasic alertness should be the
subject of further investigations.