Warm
Greetings!
In
this article, I would like to throw some light on one of the most important
glands in our body which performs a huge range of functions. As you must’ve
guessed it from the title, I’m speaking about the Pancreas. Pancreas is
associated with management of our dietary macronutrients including
Carbohydrates, Proteins and Fat. Based on our eating habits as well as the
frequency of eating meals, pancreas can work either constructively or
destructively. Before we dive deep into the anatomy of pancreas, we must
understand some key definitions;
a) Gland
– A gland is basically an organ of our body which is capable of secreting
chemical substances that are known to perform specific functions.
Based
upon the mode of releasing its chemical contents, we have two types of glands
in general – Exocrine and Endocrine.
Exocrine
glands are known to release certain enzymes for breaking down our macronutrients
and release these enzymes through certain pancreatic
ducts into the small intestine.
Endocrine
glands on the other hand are ductless
glands and release certain Hormones directly into the bloodstream.
b) Hormones:
Hormones are chemical messengers in our bodies that help in communicating
between organs through the bloodstream. It is basically our internal mobile
device which utilizes chemical molecules as a sim-card for signalling. Examples of our Hormones – Growth
Hormone, Sex hormones like Testosterone, Progesterone, Estrogen, glucocorticoids,
mineralocorticoids and many more.
Anatomy:
Pancreas
is an extremely small glandular organ with a length of 15-20cms and weighing
approximately about 75-100gms. It is located on the left side in an oblique
position starting from the Duodenum (Beginning of small intestine) and ending
on the hilum of the spleen.
The
pancreas is differentiated into four main parts – Head, Neck, Body and Tail. As
you can see from the diagram below, the head of the pancreas is located in the
C-loop formed from the Duodenum and the tail attaches to the spleen.
Pancreas
is considered to be an all-rounder as it possesses exocrine as well as
endocrine functions. The pancreatic cell mass consists of 85% Exocrine, 2%
Endocrine, 10% Extracellular matrix and the remaining 3% belongs to Ducts and vessels.
Let’s
talk about the exocrine functions of pancreas which make up such a vast
majority of the pancreatic cell mass. ‘Acinar
Cells’ form the exocrine part of the pancreas. These cells are pyramidal in
shape and are present within the ‘Acinus’
compartment. Each compartment has approximately 40 acinar cells.
These
acinar cells release certain digestive enzymes which breaks down the starches,
proteins and fats present in our meals. These digestive juices are poured into
the small intestine via the main pancreatic duct known as the Duct of Wirsung.
This duct is kept in check by a valve known as the Ampulla of Vater. The common
Bile duct from the gall bladder pours Bile into the small intestine which
breaks down specifically fats in our meal.
The
digestive juice chiefly involves the following enzymes,
|
Enzyme |
Secretion
Form |
Functions |
|
Amylase |
It
is secreted in an active form. |
Amylases
break down the starch in our foods to simple sugars like Dextrins and
Maltose. Maltose is further broken down to ‘Glucose’ by intestinal enzyme –
Maltase. |
|
Proteases
like Trypsin, Chymotrypsin, Carboxypeptidase A and B, Elastase, Intestinal
peptidases etc. |
They
are secreted as pro-enzymes (inactive) and are activated in the duodenum
(Small intestine). If they are activated within the
pancreas, they would start degrading the pancreas itself. |
Proteases
break down the proteins in our meal into individual amino acids (They are the
building blocks of Proteins) and smaller peptides (Small chains of amino
acids). These peptides further activate certain chemicals like
Cholecystokinin, secretin from the endocrine cells which in turn stimulate
the release of more digestive juice. |
|
Lipases |
They
are secreted in an active form. |
Lipases
break down the fats from our foods into individual fatty acids and glycerol. |
Following
diagram would help you understand the release of different enzymes clearly, 
The
pancreas starts a response to a meal in three phases;
a) Cephalic
Phase – This phase accounts for 10% of a meal-induced pancreatic secretion
which occurs in response to sight, smell and taste of a food.
So the next time, someone says they are getting fat just by looking at food,
you know they are completely wrong.
b) Gastric
Phase – It accounts for 10% of a meal –induced pancreatic secretion and
primarily occurs after a stomach distension (Ballooning) after a meal.
c) Intestinal
Phase – It accounts for 80% of all the phases and it results in release of all
the pancreatic juices.
The
acinar cells of the exocrine gland are not specialised as compared to the
endocrine gland, thus produce all the enzymes through a single cell.
Let
us now move on to the Endocrine function of the pancreas which is the most
vital part of the pancreatic cell mass even though it makes up only 2% of the
entire pancreas.
Small
clusters of endocrine cells known as the ‘Islets
of Langerhans’ are located within the acinus compartment of the pancreas
which also possess the acinar cells. These islets are classified into four main
types – α cells, β cells, δ cells and F cells.
β cells – They make up about 75% of the
Islets of Langerhans and produce ‘Insulin’
hormone
α cells – They make up about 20% of the
Islets of Langerhans and produce ‘Glucagon’
hormone which is known as an opposing hormone to Insulin.
δ cells – They make up the remaining 5% of
the Islets and are known to produce ‘Somatostatin’
hormone.
F cells – They produce intestinal
polypeptides (PP).
The β cells are located in the
centre surrounded by the α cells and δ cells. Our body possesses 1 million
islets with approximately 3000 α, β and δ cells in each islet. This seems so
huge but the entire islet cell mass makes up about only 1gm in a single
pancreas. This is just amazing!
Let us now speak about the various
hormones that these cells secrete.
INSULIN
from β Cells :
Insulin, as we have all heard, is
one of the most dominant hormones in our bodies. Insulin is a 56 - amino acid
polypeptide with α chain and β chain linked by two disulphide bridges between
the two chains. Insulin is converted from Proinsulin (Inactive) to its active
form by cleavage of C – peptide between the α and β chains.
Insulin is secreted in response to
high blood plasma concentration of Glucose after a high-carbohydrate meal. The
maximum insulin release is when the blood plasma concentrations of glucose
reaches around 400 mg/dL.
At this moment, glucose enters into
the pancreatic β cells. Now glucose is hydrophilic which means it is water
soluble in nature. It cannot pass the cell membrane which is made of a
phospholipid bilayer (Fat). Hence glucose requires a transporter (not Jason
Statham) to enter into the cells.
There are four different types of
glucose transporters;
GLUT1 is generally expressed in the
state of fasting and it has a much higher affinity for glucose molecules. GLUT2
is generally expressed after a meal when the plasma glucose concentration is
quite high. These receptors have a much lower affinity for glucose. GLUT3 is
expressed in Neuronal Cells and GLUT4 in the muscle cells
When glucose enters into the
pancreatic β cells via the glucose transporter, it primarily undergoes a
phosphorylation (addition of a Phosphate group) which leads to the formation of
Glucose-6-phosphate. This form of Glucose can then undergo various pathways
like Glycolysis (To create energy in the form of ATP), Glycogen synthesis
(Stored form of Glucose in the Liver and the muscles) and finally lipogenesis
(Fat storage).
Once Insulin is released by such triggers, its primary role is to lower the blood glucose concentration. Insulin attaches to the insulin receptor (Heterotetramer) on the cell membranes and allows the entry of glucose, amino acids and other minerals into the cells. Hence, Insulin plays a vital role in the entry of nutrients inside the cells. Thus Insulin also helps in building of muscles by providing the entry of amino acids into the cells.
Insulin has quite an important role in the storage of glucose in the form of Glycogen. Glycogen is stored inside the Liver upto 100gms and inside the muscles upto 400gms. Upon reaching this limit of storage, Insulin starts converting the excess glucose into triglycerides by linking the free fatty acids to a molecule of glycerol in adipocytes (Fat cells)
In order to understand this clearly, Glycogen (Stored Glucose) might be compared to food in our refrigerator to which we have quite an easy access. On the other hand, Fat might be compared to the products in the grocery store that are not readily available to us (But we can surely tap into it). Since insulin is chiefly involved in storage, it would inhibit all other processes that lead to production of new glucose either from Glycogen (Glycogenolysis) or from non-carbohydrate sources (Gluconeogenesis)
Glucagon from α Cells:
Glucagon is a 29 - amino acid single chain peptide that counteracts the working of Insulin. As compared to Insulin which is released during meals, Glucagon is released in the state of fasting. Glucagon maintains the blood glucose levels by creating new glucose from the breakdown of Glycogen or proteins and fats.
Breakdown of Glycogen essentially occurs from the Liver which has around 100gms of stored glucose. This stored form of glucose can be exhausted within 24 hours of fasting.
Glucagon is inhibited by high levels of Insulin as well as high levels of plasma glucose.
Somatostatin from δ cells:
Somatostatin is a peptide that has two bioactive forms – 14 amino acid and 28 amino acid. This hormone specifically blocks the exocrine as well as endocrine secretions from the pancreas.
Pancreatic Polypeptide (PP) from F cells:
Pancreatic polypeptide is a 36 - amino acid peptide that plays a vital role in inhibiting Bile secretion, gallbladder contraction and exocrine pancreatic secretion. Bile helps in the breakdown of fats.
In order to trigger the release of this peptide, one must consume moderate protein and fat in their meals.
As you can clearly understand from the diagram below, our normal blood plasma glucose is in the range of 70-90 mg/dL. The body would do anything and everything to maintain this range as any alterations in the blood glucose levels would be detrimental in the long term.
When the plasma glucose
concentrations rises above the normal range, Insulin is triggered by the
pancreatic β cells and it starts lowering the blood glucose by allowing its
transfer into the cells. Orally taken glucose has a much higher
Insulin response as compared to intravenously administered glucose
chiefly due to additional hormones (GIP, GLP-1) that potentiate Insulin
secretion.
Upon constant Insulin being released
by consumption of high-carbohydrate meals, the number of Insulin receptors
expressed on the Liver start going down. Due to this, less Insulin is accepted
and this creates ‘Insulin resistance’. Insulin resistance is a condition in
which there’s high levels of Insulin (hyperinsulinemia) and high levels of
glucose (hyperglycemia) in the blood.
Overtime chronic hyperglycemia and
hyperinsulinemia (High Insulin) have many adverse effects on the body,
ultimately leading to Diabetes Mellitus (Type 1 and Type 2)
When I say overtime, it means that
the body takes around 20 years to even start showing symptoms of hyperglycemia.
Until then, the body keeps on increasing insulin and cramming sugar, ultimately
resulting in Insulin exhaustion (Type 1 Diabetes)
In this way, the body keeps on
taking hits due to the bad food choices that we take, and we face the
repercussions in the long run.
Am I taking this too far or making
it a big deal? Let’s just look over statistics for a little bit. India is home
to 77 million Diabetics making it the second largest country after China to
have such high cases of Diabetes. I don’t think we are doing fine at all.
On top of this, whenever we try to
get tested for Diabetes, we are only tested for high blood sugars and not
Insulin. Insulin and Blood sugars are both related closely and if there is a
problem with Blood sugars, there would definitely be a problem with Insulin and
vice versa.
So instead of directly taking
external insulin which would make the situation worse, one must focus on
correcting Insulin resistance. I would discuss the ways of doing it in my next
article by improving glycemic control gradually and thus improving Insulin
response.
Reference:
