learning medicine is hard work osmosis makes it easy it takes our lectures and notes to create a personalized study plan with exclusive videos practice questions and flashcards and so much more try it free today in diabetes mellitus your body has trouble moving glucose which is the type of sugar from your blood into your cells this leads to high levels of glucose in your blood and not enough of it in your cells and remember that your cells need glucose as a source of energy so not letting the glucose enter means that the cells star for energy despite having glucose right on their doorstep in general the body controls how much glucose is in the blood relative to how much gets into the cells with two hormones insulin and glucagon insulin is used to reduce blood glucose levels and glucagon is used to increase blood glucose levels both of these hormones are produced by clusters of cells in the pancreas called islets of langerhans insulin is secreted by beta cells in the center of these islets and glucagon is secreted by alpha cells in the periphery of the islets insulin reduces the amount of glucose in the blood by binding to insulin receptors embedded in the cell membrane of various insulin responsive tissues like muscle cells in adipose tissue when activated the insulin receptors cause vesicles containing glucose transporter that are inside the cell to fuse with the cell membrane allowing glucose to be transported into the cell glucagon does exactly the opposite it raises the blood glucose levels by getting the liver to generate new molecules of glucose from other molecules and also break down glycogen into glucose so that I can all get dumped into the blood diabetes mellitus is diagnosed when blood glucose levels get too high and this is seen among 10 percent of the world population there are two types of diabetes type 1 and type 2 and the main difference between them is the underlying mechanism that causes the blood glucose levels to rise about 10% of people with diabetes have type 1 and the remaining 90% of people with diabetes have type 2 let's start with type 1 diabetes mellitus sometimes just called type 1 diabetes in this situation the body doesn't make enough insulin the reason this happens is that in type 1 diabetes there's a type 4 hypersensitivity response or a cell mediated immune response where a person's own T cells at the pancreas as a quick review remember that the immune system has T cells that react to all sorts of antigens which are usually small peptides polysaccharides or lipids and that some of these antigens are part of our own body cells it doesn't make sense to allow T cells that will attack our own cells to hang around until there's this process to eliminate them called self tolerance in type 1 diabetes there's a genetic abnormality that causes a loss of self tolerance among T cells that specifically target the beta cell antigens losing self tolerance means that these T cells are allowed to recruit other immune cells and coordinate an attack on these beta cells losing beta cells means less insulin and less insulin means that glucose piles up in the blood because it can't enter the body's cells one really important group of genes involved in regulation of the immune response is the human leukocyte antigen system or HLA system even though it's called a system it's basically this group of genes on chromosome 6 that encode the major histocompatibility complex or MHC which is a protein that's extremely important in helping the immune system recognize foreign molecules as well as maintaining self tolerance MHC is like the serving platter that antigens are presented to the immune cells on interestingly people with type 1 diabetes often have specific HLA genes in common with each other one called HLA dr3 and another called HLA dr4 but this is just a genetic clue right because not everyone with HLA dr3 and HLA dr4 develops diabetes in diabetes mellitus type 1 destruction of beta cells usually starts early in life but sometimes up to 90% of the beta cells are destroyed before symptoms crop up for clinical symptoms of uncontrolled diabetes that all sound similar our polyphagia glycosuria polyuria and polydipsia let's go through them one by one even though there's a lot of glucose in the blood it cannot get into the cells which leaves cells starved for energy so in response adipose tissue starts breaking down fat called lipolysis and muscle tissue starts breaking down proteins both of which results in weight loss for someone with uncontrolled diabetes this catabolic state leaves people feeling hungry also known as poly fascia Faiza means eating and poly means a lot now with high glucose levels that means that when blood gets filtered through the kidneys some of it starts to spill into the urine called glycosuria glyco surfers to glucose and urea the urine since glucose is osmotically active water tends to follow it resulting in an increase in urination or polyuria poly again refers to a lot and urea again refers to urine finally because there's so much urination people with uncontrolled diabetes become dehydrated and thirsty or polydipsia poly means a lot and dip SIA means thirst even though people with diabetes are not able to produce their own insulin they can still respond to insulin so treatment involves lifelong insulin therapy to regulate their blood glucose levels and basically enable their cells to use glucose one really serious complication with type 1 diabetes is called diabetic ketoacidosis or DKA to understand it let's go back to the process of lipolysis where fat is broken down into free fatty acids after that happens the liver turns the fatty acids into ketone bodies like Osito acetic acid in beta hydroxy butyrate acid a seed of acetic acid is a keto acid because it has a ketone group in a carboxylic acid group beta hydroxy rhetoric acid on the other hand even though it's still one of the ketone bodies isn't technically a keto acid since its ketone group has been reduced to a hydroxyl group these ketone bodies are important because they can be used by cells for energy but they also increase the acidity of the blood which is why it's called ketoacidosis and the blood becoming really acidic can have major effects throughout the body individuals can develop custom all respiration which is a deep and labored breathing as the body tries to move carbon dioxide out of the blood in an effort to reduce its acidity cells also have a transporter that exchanges hydrogen ions or protons for potassium when the blood gets acidic it's by definition loaded with protons that get sent into cells while potassium gets sent into the fluid outside cells another thing to keep in mind is that in addition to helping glucose enter cells insulin stimulates the sodium potassium ATPase --is which help potassium get into the cells and so without insulin more potassium stays in the fluid outside cells both of these mechanisms lead to increased potassium in the fluid outside cells which quickly makes it into the blood and causes hyperkalemia the potassium is then excreted so over time even though the blood potassium levels remain high over all stores of potassium in the body which include potassium inside cells starts to run low individuals will also have a high anion gap which reflects a large difference in the unmeasured negative and positive ions in the serum largely due to the build-up of ketoacids diabetic ketoacidosis can happen even in people who have already been diagnosed with diabetes and currently have some sort of insulin therapy in states of stress like an infection the body releases epinephrine which in turn stimulates the release of glucagon too much glucagon can tip the delicate hormonal balance of glucagon and insulin in favor of elevating blood sugars and can lead to a cascade of events we just described increased glucose in the blood loss of glucose in the urine loss of water dehydration and in parallel and need for alternative energy generation of ketone bodies and ketoacidosis interestingly both ketone bodies break down into acetone and escape as a gas by getting breathed out the lungs which gives us sweet fruity smell to a person's breath in general though that's the only sweet thing about this illness which also causes nausea vomiting and if severe mental status changes and acute cerebral edema treatment of a DKA episode involves giving plenty of fluids which helps with dehydration insulin which helps lower blood glucose levels and replacement of electrolytes like potassium all of which help to reverse the acidosis now let's switch gears and talk about type 2 diabetes which is where the body makes insulin but the tissues don't respond as well to it the exact reason why cells don't respond isn't fully understood essentially the body's providing the normal amount of insulin but the cells don't move their glucose transporters to their membrane in response which remember is needed for the glucose to get into the cells these cells therefore have insulin resistance some risk factors for insulin resistance are obesity lack of exercise and hypertension the exact mechanisms are still being explored for example in excess of adipose tissue or fat is thought to cause the release of free fatty acids in so-called edible kinds which are signaling molecules that can cause inflammation which seems related to insulin resistance however many people that are obese are not diabetic so genetic factors probably play a major role as well we see this when we look at twin studies as well we're having a twin with type-2 diabetes increases the risk of developing type 2 diabetes completely independently of other environmental risk factors in type 2 diabetes since tissues don't respond as well to normal levels of insulin the body ends up producing more insulin in order to get the same effect and move glucose out of the blood they do this through beta cell hyperplasia an increased number of beta cells and beta cell hypertrophy where they actually grow in size all in this attempt to pump out more insulin this works for a while and by keeping insulin levels higher than normal blood glucose levels can be kept normal called normal glycemia now along with insulin beta cells also secrete islet amyloid polypeptide or amylin so while beta cells are cranking out insulin they also secrete an increased amount of amylin over time Emlyn builds up and aggregates in the islets this beta cell compensation though is not sustainable and over time those maxed out beta cells get exhausted and they become dysfunctional and undergo hypo trophy and get smaller as well as hypoplasia and die off as beta cells are lost in insulin levels decrease glucose levels in the blood start to increase in patients develop hyperglycemia which leads to similar clinical signs that we mentioned before like Paul aphasia glycosuria polyuria polydipsia but unlike type 1 diabetes there's generally some circulating insulin in type 2 diabetes from the beta cells that are trying to compensate for the insulin resistance this means that the insulin glucagon balances such that diabetic ketoacidosis does not usually develop having said that a complication called hyperosmolar hyperglycemic state or HHS is much more common in type 2 diabetes than type 1 diabetes and it causes increased plasma osmolarity due to extreme dehydration and concentration of the blood to help understand this remember that glucose is a polar molecule that cannot passively diffuse across cell membranes which means that it acts as a solute so when levels of glucose are super high in the blood meaning it's a hyperosmolar State water starts to leave the body cells and enter the blood vessels leaving the cells were relatively dry in travailed rather than plump and juicy blood vessels that are full of water lead to increased urination and total body dehydration and this is a very serious situation because the dehydration of the body's cells and in particular the brain can cause a number of symptoms including mental status changes in HHS you can sometimes see mild ketone emia and acidosis but not to the extent that it's seen in DKA and in DKA you can see some hyper osmolarity so there's definitely overlap between these two syndromes besides type 1 and type 2 diabetes there are also a couple other subtypes of diabetes mellitus gestational diabetes is when pregnant women have increased blood glucose which is particularly during the third trimester although ultimately unknown the cause is thought to be related to pregnancy hormones that interfere with insulins action on insulin receptors also sometimes people can develop drug-induced diabetes which is where medications have side effects that tend to increase blood glucose levels the mechanism for both of these is thought to be related to insulin resistance like type 2 diabetes rather than an autoimmune destruction process like in type 1 diabetes diagnosing type 1 or type 2 diabetes is done by getting a sense for how much glucose is floating around in the blood and has specific standards that the World Health Organization uses very commonly a fasting glucose test is taken where the person doesn't eat or drink except the water that's okay for a total of eight hours and then has their blood tested for glucose levels levels of 100 milligrams per deciliter to 120 five milligrams per deciliter indicates pre-diabetes and 126 milligrams per deciliter or higher indicates diabetes a non fasting a random glucose test can be done at any time with 200 milligrams per deciliter or higher being a red flag for diabetes another test is called an oral glucose tolerance test where person is given glucose and then blood samples are taken at time intervals to figure out how well it's being cleared from the blood the most important interval being two hours later levels of 140 milligrams per deciliter to 199 milligrams per deciliter indicate pre-diabetes and 200 or above indicates diabetes another thing to know is that when blood glucose levels get high the glucose can also stick to proteins that are floating around in the blood or in cells so that brings us to another type of test that can be done which is the hba1c test which tests for the proportion of hemoglobin in red blood cells that has glucose stuck to it called glycated hemoglobin hba1c levels of 5.7% 26.4% indicate pre-diabetes and 6.5 percent or higher indicates diabetes this proportion of glycated hemoglobin doesn't change day to day so it gives a sense for whether the blood glucose levels have been high over the past two to three months finally we have the c-peptide test which tests for byproducts of insulin production if the level of c-peptide is low or absent it means the pancreas is no longer producing enough insulin and the glucose cannot enter the cells for type one diabetes insulin is the only treatment option for type 2 diabetes on the other hand lifestyle changes like weight loss and exercise along with a healthy diet and an oral anti-diabetic medication like metformin in several other classes can sometimes be enough to reverse some of that insulin resistance and keep blood sugar levels in check however if oral anti-diabetic medications fail type 2 diabetes can also be treated with insulin something to bear in mind is that insulin treatment comes with a risk of hypoglycemia especially if insulin is taken without a meal symptoms of hypoglycemia can be mild like weakness hunger and shaking but they can progress to a loss of consciousness in seizures in severe cases in mild cases drinking juices or eating candy or sugar might be enough to bring blood sugar up but in severe cases intravenous glucose should be given as soon as possible the FDA has also recently approved intranasal glucagon as a treatment for severe hypoglycemia all right now over time high glucose levels can cause damage to tiny blood vessels while the micro vasculature in arterioles a process called hyaline arteriolosclerosis is where the walls of the arterioles develop hyaline deposits which are deposits of proteins and these make them hard and inflexible in capillaries the basement membrane can thicken and make it difficult for oxygen to easily move from the capillary to the tissues causing hypoxia one of the most significant effects is that diabetes increases the risk of medium and large arterial wall damage and subsequent atherosclerosis which can lead to heart attacks and strokes which are major causes of morbidity and mortality for patients with diabetes in the eyes diabetes can lead to retinopathy and evidence of that can be seen on a fundus copic exam that shows cotton-wool spots or flare hemorrhages and can eventually cause blindness in the kidneys the a ferrant and efferent arterioles as well as the glomerulus itself can get damaged which can lead to an F Radek syndrome that slowly diminishes the kidneys ability to filter blood over time and can ultimately lead to dialysis diabetes can also affect the function of nerves causing symptoms like a decrease in sensation in the toes and fingers sometimes called a stocking glove distribution as well as causes the autonomic nervous system to malfunction and that system controls a number of body functions everything from sweating to passing gas finally both the poor blood supply and nerve damage can lead to ulcers typically on the feet that don't heal quickly and can get pretty severe and need to be amputated these are some of the complications of uncontrolled diabetes which is why it's important to diagnose and control diabetes through a healthy lifestyle medications to reduce insulin resistance and even insulin therapy if beta cells have been exhausted while type 1 diabetes cannot be prevented type 2 diabetes can in fact many people with diabetes can control their blood sugar levels really effectively and live a full and active life without any of the complications thanks for watching if you're interested in a 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