My understanding, after a lot of internet research this afternoon, is as follows:
A 10 ml bottle contains 1000 units
There are 100 units in a mL
1 cc equals 100 units, so to figure how long a 10mL bottle, (1000 units) will last, you divide the number of units you use per day into 1000, and there you have it.
Actually it depends on the concentration of the bag of solution you have. Yes if you have a 10 mL bottle with 1000 units of Heparin then you would have 100 units per mL. But each bottle/bag is different. You may have a bag that has 1000mLs of fluid and contain 30,000 units of heparin. In which case your units per mL would be 30. The formula is to take your amount of Heparin and divide it by the amount of fluid in mLs you have. This will give you the amount of units per mL.
units/mls= units per mL
The recommended dosage of medication for this prescription is 10 units per milliliter (u/ml).
The concentration of the solution is measured in microliters per milliliter (u/ml), indicating the amount of solute in a given volume of the solution.
To calculate map units between linked genes, you use the formula: map units (number of recombinant offspring / total number of offspring) x 100. This helps determine the distance between genes on a chromosome based on the frequency of recombination events during meiosis.
The protein concentration measured by the Protein Nanodrop is the amount of protein present in a sample, typically expressed in units such as micrograms per milliliter (g/mL) or milligrams per milliliter (mg/mL).
To calculate the grams of urea in 50 ml of urine where 1.8% is urea, first convert the ml to grams using the density of urine (about 1 g/ml). Then, multiply the volume of urine in grams by the percentage of urea (0.018) to find the grams of urea present in 50 ml of urine.
To dilute Taq polymerase from 500 units/ml to a desired concentration, calculate the volume of the enzyme needed to achieve the desired units. For example, if you need 100 units, you would dilute 0.2 ml of the 500 units/ml solution in a total volume to reach your desired concentration.
one, ml is the abbreviation of millilitre.A millilitre is a thousandth of a litre
To calculate the days' supply of Humulin N insulin, you need to determine the total number of units in the 20 mL vial. Humulin N typically has a concentration of 100 units/mL, so a 20 mL vial contains 2,000 units (20 mL x 100 units/mL). If the daily dose is 40 units, the days' supply would be 2,000 units divided by 40 units/day, which equals 50 days. Therefore, the 20 mL vial would last for 50 days at a dose of 40 units daily.
To find out how many ml from the vial are equal to 125 units, we have to first determine the concentration of the solution (units per ml). We can do this by dividing the total units (10,000) by the total volume (10 ml), which gives us 1000 units/ml. Then, we divide the number of units we want (125) by the concentration (1000 units/ml) to find that 0.125 ml from the vial is equal to 125 units.
If you have 1000 mls of stock that contains 50 units of drug in 1000 ml, and you want to calculate how to deliver 7 units per hour (you question wasn't all that clear, but we'll assume that's it.), then..7 U/hr x 1000 ml/50 U = 140 ml/hour for 7 hours.
The number of units administered will depend on the concentration of NPH U-100 insulin. If the patient is receiving 0.25 ml of insulin, you need to know the concentration of the insulin to calculate the units. Typically, 1 ml of U-100 insulin contains 100 units, so in this case the patient would receive 25 units of NPH U-100 insulin.
100 units per ml. so it would be 1000 units in 10 ml.
(375,000 units) / (0.5 units per ml) = 750,000 ml= 750 liters = roughly 198 gallons. Start drinking.
ml
Assuming a circular cylinder, you use the formula pi x radius squared x height. The answer will be in cubic units, for example, cubic millimeters.
4 units
10,000