Addiction is a kind of
medical condition in which the person has unsustainable desire to consume a substance
or engage in an activity, although knowing that it can cause various adverse
effects. Taking that substance or engaging in that activity make the victim feel
good. It case of sugar it is nearly the same. We Indians especially the Bengalis
are very much addictive to sweets. The sweet item after a meal attracts maximum
of us.
Sugar is used daily by
most of the people. Modern food is very rich in sugar. This is one of the many
cause behind the obesity epidemics.
Overconsumption
of sugar can interact with different parts and substances of brain and changes
their normal state and levels. Notably it affects the levels of Dopamine.
The
most common form of sugar in our daily food is sucrose. When ingested this
sugar is split in the digestive system into two constituents, glucose and
fructose. Insulin and glucagon are two most important hormones that regulate
the level of glucose in human body.
After
ingestion and degradation of sugar, glucose molecules and absorbed and
distributed to all organs and cells in our body. A group of proteins called
GLUCs are responsible for transportation of glucose molecules to the brain. It mediates
glucose uptake from ECF into astrocytes, oliogodendroglia and microglia but
GLUT3 which has a much higher transport rate than GLUT1 facilitated neuronal
glucose uptake. When glucose molecules reaches the destination cells, it not to
go into the cell where it is consumed. There are different mechanisms behind
thin. In some cells like RBCs use diffusion toget glucose from the blood
plasma. Many other cell use active transport to transport glucose inside the
cells. The main consumer of the total intake of the glucose is the brain. The
human cortex along requires approx. 3x1023 ATP/S/m3and
energy expenditure to release one synaptic vesicle is roughly calculated to be
1.64x105 molecules of ATP. The reason behind this that brain tissue
or the neurons cannot store glucose thus it cannot use any glucose when the
blood glucose level is low.
Neurological Aspect of Sugar
Intake:
Figure
1: The neuronal network activated by sucrose intake. VII – facial nerve; IX –glossopharyngeal nerve; X – vagus
nerve; Acb – nucleus accumbens; Amy – amygdala; ENP – enteric nervous plexus;
LS – lateral septum; NTS – nucleus of the solitary tract; PB – parabrachial
nucleus; PVT – paraventricular thalamic nucleus; T1R2/3 – sweet taste receptor
subunits; VPM – ventral posteromedial nucleus of the thalamus; VTA – ventral
tegmental area
Recent
progress in molecular biology and genetics has revealed candidates for sweet
perception, the members of T1Rfamily of receptors. More precisely, these
studies showed that perception of sweetness in mammals depends on the
expression of the receptor T1R3 that, at the apical membrane of the taste
receptor cells, forms a complex with a related protein, T1R2. This T1R2-T1R3
heterodimer is a G-protein coupled receptor that binds with sugar and
artificial sweeteners. Binding of sweet molecules to the T1R2-T1R3 receptor
complex triggers a conformational change in the molecules of the complex. This
change activates the G-protein, alpha-gustducin, which in turn activates
adenylate cyclase and phospholipase C. Activation of these signaling molecules
results in an increase in intracellular free calcium. The increase in calcium activates
the transient receptor potential channel M5 (TRPM5), which causes release of
the neurotransmitter and activation of the primary afferent neurons. Taste
information ascends to the brain by the sensory fibers of the facial nerve
(cranial nerve VII), which innervates the anterior tongue, and the glossopharyngeal
nerve (cranial nerve IX) and the vagus nerve (cranial nerve X), which innervate
the posterior tongue. Because the sweet taste buds are more concentrated at the
anterior part of the tongue, the information about sweet taste enters the brain
mostly by the facial nerve. Recent investigations suggest that the
gastrointestinal tract may transfer to the brain information related to sweet
molecules. The expression of all types’ ofT1Rs was found in the gastrointestinal
tract, including the stomach, duodenum, jejunum, ileum, and colon. These taste receptors
signal via the enteric nervous system to the brain.
The enteric nervous system transfers guts
sensory signals to the brain and can participate in forming long-term
representations of gut sensations. These gut feelings, called ‘homeostatic
emotions or even’ extended consciousness may affect our emotional state and
underlie intuitive decision making. From the medullar NTS, the sensory information
is directed to the parabrachial nucleus (PB; Figure 1) located in the pons. In
addition to the main stream from the NTS to the PB, some NTS fibers run directly
to the central amygdala, paraventricular thalamic (PVT), and paraventricular hypothalamic
(PVH) nuclei. The brainstem gustatory centers may generate the mimetic response
to the taste of sucrose in rats. The lesion of
the PB impairs the increase in sucrose licking as a function of sucrose
concentration seen in intact rats. Conversely, stimulation of the cannabinoid
receptors CB1 in the PB selectively stimulates feeding of palatable foods in
rats. From the PB, the gustatory pathway branches to densely innervate the
medial hypothalamus, ventral tegmental area (VTA), and midline thalamic nuclei.
From the parvocellular part of the ventral posterior thalamic nucleus (VPM),
the gustatory information is directed to the primary gustatory insular
cortex(Figure 1).
In the gustatory insular cortex, the neurons responsive to taste
are located in the anterior, dysgranular region. Another thalamic gustatory related
pathway travels from the PB to the PVT, and, after synapsing in the PVT,
reaches the prefrontal cortex (Figure 1). The interconnecting loop formed by
the prefrontal cortex, nucleus accumbens, lateral hypothalamus, and VTA is
intimately related to the rewarding effects of sucrose. The taste of sucrose
activates the dopaminergic neurons of the VTA and elevates dopamine levels in
the nucleus accumbens. The dopamine levels increase in the accumbens in
proportion to the sucrose concentration, and the neurons of the nucleus
accumbens explicitly encode for the hedonic value of sucrose.
For us,
Bengalis eating Rasgulla or Sandesh is one of the happiest moments of the life.
And this phenomenon is totally normal. Sugar increases the release of
neurotransmitter serotonin, which gives a person happy feeling. This also
increases the release of insulin which eventually normalizes the blood sugar
level, and when glucose is back to relatively low levels we will again strive
to take sugar just to feel happy again. This leads to constantly eating sweets
just to feel good. This results in overeating and possible addiction.
Another
problem with sugar addiction is that the fact that human brain reacts
differently to different trigger the impulses that tell us to stop eating. But
for fructose this situation is rather different. Fructose amplifies the reward
circuits much more than glucose, resulting affection of those foods containing
fructose. Thus the human body needs much more fructose to suppress eating.
Scientific studies have shown that glucose reduces the activity in hypothalamus,
whereas fructose does not. The hypothalamus controls the hunger and thirst
along with some metabolic functions.
Compared
to glucose eating fructose also has been found to produce a smaller increase in
satiety hormones. In a study on rats it has also being found that when fructose
is delivered directly to brain the rats begins to eat, whereas glucose
ingestion in the same way reduces their eating.
Recent
studies show that after taking glucose those healthy non obese subjects show
lower activity in the hypothalamus and the reward system and motivation. But
fructose ingestion causes just the opposite, it also activates the nucleus
accumbens which is a part of brain reward circuit resulting increased hunger
and motivation compared to glucose.
The
modern foods and drinks contain much more fructose and as the fructose is addictive
this causes attraction of those foods and drinks. This proves the statistics
that overweight and obese people globally increased from 857 million in 1980 to
2.1 billion in 2013 which is 1/3rd of the world’s population.
