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histamina

Histamine is an organic amine that functions as both a neurotransmitter in the central nervous system and a mediator of inflammatory and immune responses in peripheral tissues. It is synthesized from the amino acid histidine by the enzyme histidine decarboxylase and stored in granules of mast cells, basophils, and certain enterochromaffin-like cells in the gut.

Histamine exerts its effects through four G protein–coupled receptors, designated H1, H2, H3, and H4. H1 receptors

Metabolism of histamine occurs primarily through diamine oxidase (DAO) and histamine N-methyltransferase (HNMT). DAO degrades extracellular

Clinical relevance includes allergic reactions, rhinitis, urticaria, gastric ulcers, and certain inflammatory conditions. Treatments often target

are
involved
in
vasodilation,
increased
vascular
permeability,
bronchoconstriction,
and
allergic
symptoms.
H2
receptors
regulate
gastric
acid
secretion
by
parietal
cells
and
influence
heart
rate
and
vascular
tone.
H3
receptors
act
as
presynaptic
autoreceptors
and
modulate
neurotransmitter
release
in
the
brain,
while
H4
receptors
are
expressed
on
various
immune
cells
and
participate
in
inflammatory
responses.
Histamine
release
is
triggered
by
physical
injury,
allergens
that
cross-link
IgE
on
mast
cells,
or
other
stimuli,
leading
to
symptoms
such
as
redness,
swelling,
itching,
and,
in
severe
cases,
anaphylaxis.
histamine,
especially
in
the
gut
and
placenta,
while
HNMT
acts
intracellularly
in
many
tissues.
Impaired
breakdown
can
lead
to
histamine
accumulation,
contributing
to
histamine
intolerance
in
some
individuals.
histamine
receptors
using
antihistamines
(H1
blockers)
or,
for
gastric
acid
reduction,
H2
receptor
antagonists.
Diet
and
gut
health
can
influence
histamine
levels,
as
ferments
and
aged
foods
may
contain
or
release
histamine.