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Hypokalemia
Hypokalemia is formed in what way?
Hypokalemia refers to a condition where the serum potassium level is below 3.5 millimoles per liter. The primary cause of hypokalemia is the loss of potassium in the body. Hypokalemia can be classified into three types based on its cause: potassium deficiency hypokalemia, redistributive hypokalemia, and dilutional hypokalemia. Potassium deficiency hypokalemia is mainly characterized by insufficient intake or excessive excretion. Insufficient intake is typically seen in patients who are fasting, have selective eating habits, or suffer from anorexia, while excessive excretion is mainly through gastrointestinal or renal loss of potassium. Redistributive hypokalemia usually occurs due to metabolic or respiratory alkalosis, the recovery phase of acidosis, heavy usage of glucose, instances of periodic paralysis, acute emergency situations, and the use of folic acid and vitamin B12 in treating anemia or repeat transfusions of cold stored washed red blood cells. Dilutional hypokalemia, on the other hand, is mainly caused by the retention of extracellular fluid, leading to excessive water or water intoxication-induced hypokalemia.
Hypokalemia can cause
Hypokalemia can manifest as weakness, a bitter taste in the mouth, lack of appetite, irritability, or mood swings. In severe cases, symptoms like nausea, vomiting, drowsiness, reduced orientation ability, and confusion may occur. In terms of muscle and nerve effects, hypokalemia leads to decreased neuromuscular excitability, and when blood potassium levels fall below 2.5mmol/L, clinical symptoms of muscle weakness appear. If blood potassium levels drop below 2.0mmol/L, flaccid paralysis and disappearance or weakening of tendon reflexes may occur. In severe cases, paralysis of the respiratory muscles and even respiratory failure might develop. For the gastrointestinal tract, common symptoms include lack of appetite, nausea, and vomiting, with severe cases leading to intestinal paralysis. Hypokalemia can cause an increase in heart rate and even ventricular fibrillation, which can be fatal. Additionally, it can result in metabolic alkalosis. Hypokalemia can cause metabolic alkalosis, and vice versa, with each condition potentially leading to the other, often coexisting simultaneously.
Hypokalemia is a condition.
Hypokalemia is classified as an electrolyte disorder. When suffering from hypokalemia, patients may experience general weakness and poor appetite. In severe cases, paralysis of the limbs may occur. There are certain causes of hypokalemia, which can be divided into three types. One is reduced intake, the second is excessive loss, and the third is abnormal distribution. Reduced intake mainly refers to patients with poor diets; excessive loss is common in patients with infections, diarrhea, and those who excrete a high amount of potassium in their urine; abnormal distribution refers to potassium moving from the extracellular space into cells, causing hypokalemia.
What medicine should be taken for hypokalemia?
The treatment of hypokalemia primarily involves addressing the underlying disease. Symptomatic treatment should avoid excessive potassium supplementation, which can lead to hyperkalemia. The principle of potassium supplementation is as follows: for mild hypokalemia, such as in patients showing clinical signs, oral potassium can be administered at 40-80 millimoles per day. For patients with severe hypokalemia, or those whose gastrointestinal tract cannot utilize potassium, with potassium levels less than 2.0 millimoles per liter, intravenous potassium can be provided. An initial supplementation rate of 10-20 millimoles per hour is relatively safe. In cases of severe hypokalemia with life-threatening clinical signs, a rapid increase to 40-80 millimoles can be achieved in a short period, but close monitoring is necessary.
Which department to go to for hypokalemia?
Hypokalemia is defined as having a blood potassium level below 3.5 mmol/L. In hospitals, when treating mild hypokalemia, it is essential to identify and treat the primary disease in the corresponding department, such as endocrinology, internal medicine, or gastroenterology. Additionally, timely oral potassium supplementation is necessary to correct the hypokalemia. If severe hypokalemia occurs clinically, with blood potassium levels less than 2.5 mmol/L, treatment in the intensive care unit is required. It is crucial to establish an intravenous access for potassium supplementation immediately. The rate of potassium supplementation should be slow, and blood potassium levels must be monitored continuously.
When supplementing potassium for hypokalemia, what should be paid attention to?
When supplementing potassium for hypokalemia, the following should be noted: 1. Closely monitor the blood potassium levels. Supplement 60-80 mmol/L of potassium, or recheck the blood potassium level within 1-4 hours after supplementation. 2. If the rate of potassium supplementation exceeds 10 moles per hour, continuous ECG monitoring should be maintained, closely observe the changes in the ECG, and prevent the occurrence of life-threatening hyperkalemia. 3. The rate of potassium supplementation for patients with regenerative dysfunction should be 50% of that for patients with normal kidney function. 4. The daily amount of potassium supplementation should not exceed 100-200 millimoles. 5. Try not to use peripheral veins for high-concentration potassium supplementation. 6. Use sodium chloride solution to dilute potassium-containing solutions, and it is not recommended to use glucose or low molecular weight dextrorotatory sugar as the carrier.
The impact of hypokalemia on skeletal muscle
In clinical practice, hypokalemia can affect the muscular and nervous conduction systems. The most prominent symptoms of hypokalemia in the neuromuscular system are flaccid paralysis of the skeletal muscles, loss of tension in smooth muscles, and rhabdomyolysis. If the respiratory muscles are involved, it can lead to respiratory failure. Hypokalemia can also lead to insulin resistance, resulting in significantly abnormal glucose tolerance. If hypokalemia occurs clinically, it is crucial to actively treat the primary disease, appropriately supplement potassium, monitor during the supplementation process to avoid hyperkalemia, and closely monitor blood potassium levels with regular reviews.
Causes and Clinical Manifestations of Hypokalemia
Hypokalemia refers to a condition where blood potassium levels are below 3.5mmol/L. The causes can be due to inadequate intake of potassium, such as prolonged inability to eat without sufficient intravenous supplementation of potassium. It can also result from excessive loss of potassium, through external losses such as vomiting and diarrhea, or through renal losses due to the excessive use of diuretics and certain hormonal imbalances. A third cause involves the shift of potassium into cells, such as during episodes of alkalemia and periodic paralysis. Clinically, mild to moderate hypokalemia is characterized by symptoms like muscle weakness, fatigue, cramps, intestinal obstruction, and some abnormalities in electrocardiograms, including the presence of U waves and flattened T waves. Severe hypokalemia can lead to life-threatening arrhythmias, such as ventricular tachycardia and ventricular fibrillation, which require immediate treatment.
How to treat hypokalemia?
After the occurrence of hypokalemia, there are generally two methods of potassium supplementation clinically. The first is oral potassium supplementation, which is relatively safe, and one can also eat fruits or vegetables rich in potassium. The second method is intravenous potassium supplementation. The first thing to note with intravenous supplementation is the patient's urination status. If the patient’s urination is normal, potassium chloride can be administered intravenously but must be diluted. In clinical practice, the concentration of intravenous potassium chloride generally does not exceed 0.3%, so we must pay attention to the concentration during potassium supplementation.
Causes of hypokalemia
Potassium is one of the essential electrolytes necessary for life. Its physiological functions mainly include maintaining cellular metabolism, regulating osmotic pressure and acid-base balance, and preserving cell stress response, etc. Daily potassium intake is about 100 millimoles, with 90% excreted through the kidneys and the remainder through the gastrointestinal tract. Common causes of hypokalemia include reduced intake, such as long-term inability to eat without timely potassium supplementation. Even though potassium intake decreases, the kidneys continue to excrete potassium, leading to potassium loss. The second cause is increased excretion, which includes losses through the gastrointestinal tract and the kidneys, both of which can lead to hypokalemia. The third cause is the movement of potassium from outside to inside the cells, which can occur during metabolic alkalosis or when glucose and insulin are administered, promoting the transfer of potassium ions into the cells, resulting in hypokalemia.