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hello everyone in this tutorial we will
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look at some questions to help you to
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understand the calculation for
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intravenous bolus and infusion
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administration first pause the video and
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try to solve the questions and then play
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the video for my explanations let's
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begin this question is related to
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intravenous bolus dose you will need to
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plot the graph using semi-log paper to
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sort the questions so let's pause the
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video and try the questions this is the
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graph
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you should get so let's look at the
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hidden information in this graph so
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first of all if you remember when we
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calculate the gradient for this straight
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line you should able to find rke so this
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is the elimination rate constant once
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you can find this answer you managed to
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convert this to t 1/2 remember this
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equation T 1/2 is equal to lon 2 divided
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by ke so that is a half-life for
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elimination the next information we can
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find from the graph is by extrapolating
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the graph over here into the y-intercept
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so once you find this y-intercept over
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here you can find the initial
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concentration so that is the information
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we can identify from the graph so let's
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move on to the calculation steps I will
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show you how to solve all the questions
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for question number one we need to
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calculate the gradient so I'm going to
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use this equation 1 C 2 minus 1 C 1 T 2
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minus T 1 you can pick any concentration
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or anytime point from the table in this
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case I'm going to use the example 1 2.6
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minus 161 over 8 minus 0.5 so the value
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I obtained will be zero point nine six
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minus four point one one divided by
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seven point five your answer for ke
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should be 0.42 so we soft question one
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the second question is about half-life
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for elimination
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we have is equal to lon 2 divided by ke
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that would be 0.693 divided by 0.4 2 so
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the half-life of elimination should be
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one point six five hour okay for
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question number three you need to
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extrapolate the graph just use your
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ruler placed on the straight line and
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look at the y-intercept you should get a
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value approximately seventy six depend
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on how you read the graph so this is my
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estimation if your answer is slightly
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deviate from my that will be also
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acceptable now proceed to question
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number four you need to identify the
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volume to make it simple since I have
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the initial concentration I'm going to
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use C equal to dose divided by volume
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from the question number three the
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initial concentration is 76 divided
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those three hundred from here you can
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find the volume the volume you should
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get is around three point ninety four
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liter okay for question number five you
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need to identify the concentration a
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chav hour later so T is equal to twelve
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using this equation for IV bolus EK t
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the concentration you need to identify
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the dose is 300 volume is three point
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nine four e- k k is 0.42 x twelve
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solving this equation the concentration
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at T equal to 12 will be 0.49 so that's
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it for question one you can proceed to
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the next question
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this question is very similar to the
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previous questions except you have to
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calculate the area under the curve using
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the trapezoidal rule now you can pause
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the video try the question and I will
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explain to you later this is a graph you
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should get and again by calculating the
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gradient of the straight line you're
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able to find the elimination rate
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constant
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and the next thing is by extrapolating
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the graph the straight line to touch the
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y-intercept you were able to find the
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initial drug concentration the next
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thing I want to remind you is about the
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trapezoidal rule we are going to
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calculate the area under the curve so
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basically the concept is by cutting all
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this time point into tiny little pieces
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and add all the area together so I'm
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going to use this example let's say I'm
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going to calculate the area for time
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point 3 to 4 hour and then the equation
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will be 1/2 C 1 C 2 so what is C 1 and C
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2 that will be the concentration over
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here C 1 and C 2 and then multiplied by
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the height the height will be the time
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so in this case there will be 1 so by
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adding all these tiny pieces together
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you were able to find a you see I will
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show you the calculation in the next
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slide the first part is you have to
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calculate the gradient that would be
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negative ke equal to 1 C 2 minus 1 C 1
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over T 2 T 1 over here I'm going to use
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lon 0.2 minus lon
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7 point 7 divided by 8 minus 0.5 so my
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answer will be 0.49 for the second part
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you need to find the half-life or
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elimination this is simple 0.693 divided
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by 0.49 your answer will be 1 point 4 1
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ok for part 3 is about the y-intercept
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so my one intercept over here 9.2 your
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answer may be slightly different from my
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depends on how you read the graph so now
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we move on to part 4 you need to
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identify the volume using this simple
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equation
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you have to concentration which is 9
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point to those is 500 mg divided by
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volume your volume will be 50 4.3 liter
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and then the next one to identify the
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clearance you use this equation k equal
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to Clarisse divided by volume your ke is
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0.49 equal to clearance divided by
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volume 54.3 your clearance will be 20
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6.6 liter per hour so we solve the five
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question and we will move on to the
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trapezoidal rule to make your
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calculation easier you can generate a
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table like this so I'm going to use the
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time point 0 and 0.5 as example to
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explain to you what is trapezoidal rule
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let's say I have zero zero point five
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the concentration will be nine point two
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and seven point seven I'm going to
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calculate the area for this area under
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the curve the equation will be half C 1
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plus C 2 multiplied by a high-cut in the
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value I will have nine point two plus
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seven point seven multiplied by 0.5 when
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I calculate the answer it should be it
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should be four point two two over here
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you have to do this for all the interval
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and you will get all the area if you sum
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this up you should get nineteen point
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one five
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for the last concentration is going to
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move until infinity how do we calculate
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the area for the last concentration
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point there will be zero point two
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divided by ke remember your ke is 0.49
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so the last piece over here is 0.41 now
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add these two together and you should
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get your answer nineteen point five six
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okay so that is how we calculate a you
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see this question is about intravenous
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bolus administration you can now post
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the video to attempt the questions the
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first part you need to recommend the
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bolus loading dose for this patient and
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the equation I will use is concentration
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equal to those divided by volume the
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concentration will be 80 the dose
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divided by volume so volume is 0.5 x 70
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and you work out the D it should be 2800
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M G so this is question number one for
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question number two you need to
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calculate for how long you can sustain
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above 50 mg bolita so the target level
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previously was 80 so how long will it
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takes to drop from 80 to 50 so first of
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all you need to construct the equation
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that will be 50 equal to 80 multiplied
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by e KP over here you need to solve the
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K before you can solve the t 4k from the
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question we know that the half-life is
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16 hour so over here you can calculate
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the K the K you will find it is zero
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point zero four three so once you
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identify the K you are going to
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substitute back to the equation and then
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you can solve the T now with that I'm
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sure you're able to solve the question
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that he will be 10.9 hour so it will
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sustain for another ten point nine hour
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before it go below the 50 mg per liter
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level in question number three we have
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two different concentration so one is to
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our one is for our and this is 82 that
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is 64
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so over here we need to identify what is
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the concentration at 12 hour later so
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first of all I'm going to calculate the
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ke using these two information over here
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so lon
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64 minus lon 82 that will be 4 minus 2
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calculating the ke that will be 0.125 so
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that is my first information to
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calculate the concentration here I will
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use C 12 is equal to C 4 x EK y it is a
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tower over here because of the interval
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that will be c 12 equal to 64 multiplied
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by e 0.125 multiplied by 8 if that my
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answer to be 23.7 that's it for question
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3 I hope you are familiar with
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intravenous bolus administration from
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this question onwards we will practice
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the calculation for intravenous infusion
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administration now you can post a video
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to attempt the questions to solve this
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question you need to sketch out the
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graph to get a better picture what is
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happening this is to our you have a
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concentration equal to 3 and a
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concentration equal to 6 that will be 16
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and 5 first of all I will need two
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softer ke you can use the lon C 2 minus
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1 C 1 equation divided by T 2 minus T 1
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over here I'm going to use a different
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method there will be 5 equal to 16 x EK
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3 so this is actually C 6 equal to C 3
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multiplied by e k3 so over here
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we need to find a K the 3 is the
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interval between the two concentration
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so over here you should able to find out
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the K E is 0.39 so this is the first
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answer and for the part two you need to
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find volume in order for you to find the
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volume you must remember this equation k
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equal to current divided by volume over
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here you have K but you can find
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clearance from the information over here
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so the equation for me to identify the
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clearance is C equal to sort factor in
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fusion rate 1 minus K time of infusion a
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minus K time - time of infusion over
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here I need to identify the infusion
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rate it is given in the question 10 mg
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per minute that will be equivalent to
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600 mg per hour
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always remember infusion rate is always
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in our so soft factor is not given we
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assume is 1 and over here I'm going to
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use 16 as my example 16 is equal to 600
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and the clearance I need to identify a -
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0.39 x - the infusion time is 2 Alba a -
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3 0.39 time point number 3 - 2 our
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infusion so soft the clearance you will
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get thirteen point seven five liter per
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hour now we have both K and CL you can
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calculate the volume easily using K CL
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volume zero point three nine is equal to
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thirteen point seven five divided by V V
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will be thirty five point three liter so
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that is volume okay part three part
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three you need to identify
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inclusion rate for you to achieve 20 mg
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per liter so this is a steady state you
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need to use CSS equal to as IR /
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clearance the target is 20 soft factor
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is 1 inclusionary unknown the clearance
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thirteen point seven five so easily you
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can identify the infusion rate should be
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275 mg per hour so that's it for this
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question this question is a bit longer
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we have five questions in total I will
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first explain the three questions and
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then follow up by the other two
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questions later
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you can now post a video to attempt the
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questions for part one you need to
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identify the profile using population
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kinetic equation for clearance it is 80
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kg multiplied by 0.04 and there is also
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a factor of 0.8 you should include
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because the patient is suffering from
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Coad the answer for this will be 2 point
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5 6 liter per hour now for volume of
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distribution is zero point four eight
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multiplied by 80 that is 38.4 meter the
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last one the KE you can calculate using
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clearance divided by volume that will be
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zero two point five six two point five
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six divided by thirty eight point four
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the ke will be zero point zero six seven
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so easily you can identify Audis and
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question number two you need to
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recommend the bolus loading dose as well
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as infusion to maintain the level at
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hand mg per litre so for bolus that will
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be concentration shot factor dose
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divided by volume for aminophylline to
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toe for analysis factor of zero point
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seven nine so remember you have to
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include the salt
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factor the target is ten 0.79 x d the
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volume estimate that he study it by for
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the the recommended amount will be 486
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mg for the bolus loading dose to
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maintain the level at 10 mg per liter
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there will be CSS SI r / clearance the
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target is 10 shot factor 0.79 infusion
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rate clearance is two point five six the
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infusion rate should be 32 point 1 mg
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per hour okay so move on to question
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number three for question number three
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it is a bit longer because we are
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combining two different dose we have a
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bolus followed by a continuous infusion
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the graph you should see will be
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something like this this is from the
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bolus and you have a continuous infusion
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and then combined is to you need to find
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what is the concentration at six hour
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later so let us try to solve this
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question the equation is a bit longer
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the concentration at six hour you'll be
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the bolus ekp plus the infusion ir our
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clearance one - EK time of infusion over
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here soft factor zero point seven nine
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multiply the dose four hundred divided
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by the volume 38.4 multiplied by e k
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zero point zero six seven x 6 plus zero
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point seven nine and infusion rate of 40
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divided by clearance the clearance
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2.5 6 y- 0.067 x 6 so over here you
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should get 5.5 1 plus 4 point 0 7 the
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final answer the concentration is five
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nine point five eight okay I hope you
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can understand up to this path question
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four and five to test your understanding
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for continuous steady state infusion you
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can pause the video to attempt the
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questions for question number four your
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patient is given the infusion of 40 mg
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per hour
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after some time you will reach the
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steady state and the measurement for the
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level will be 15 mg per liter so over
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here we need to identify what is the
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actual clearance in order to calculate
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that we use CSS as AI R divided by
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clearance the measured concentration is
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15 sought factor zero point seven nine
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multiplied by infusion rate and the
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clearance over here we can find a
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clearance is two point one ETA power for
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question number five you need to target
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the concentration at 10 mg per liter so
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using the actual clearance in this case
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same equation over here the target is 10
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shot factor zero point seven nine
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infusion rate unknown and the actual
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clearance is two point one solving this
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your answer will be twenty six point six
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mg per hour so that's all for our
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practice question I hope you have
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learned and improve your understanding
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for the calculation thank you very much
