clearance concepts
DESCRIPTION
Text: Applied Biopharm. & PK L. Shargel, S Wu-Pong & A. Yu; 5th Ed. Chapter 6 (p131-158) Chapter 11 (p303-348). CLEARANCE CONCEPTS. Math problems? Call 1-800-[(10x)(13i)^2]-[sin(xy)/2.362x]. Clearance -Objectives for Today-. - PowerPoint PPT PresentationTRANSCRIPT
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Text:
Applied Biopharm. & PK
L. Shargel, S Wu-Pong & A. Yu;
5th Ed. Chapter 6 (p131-158)
Chapter 11 (p303-348)
CLEARANCE CONCEPTS
Math problems? Call 1-800-[(10x)(13i)^2]-[sin(xy)/2.362x]
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Clearance-Objectives for Today-
Review of methods to calculate total body clearance .
• Understand the relative contribution of specific eliminating pathways on total body clearance.
• Integration of clearance methods for the calculation of specific organ clearances and elimination rates.
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ClearanceDef’n: PK term to describe the irreversible
removal of drug from the body (drug elimination)
• Most important PK parameter because it determines Dose & Dosing schedule.– Variable parameter- affected by age, disease,
genetics …
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• Can be used to describe drug elimination
from either total body (CLT) or from a
single organ ( ie. CLH ; CLR ; CLbile ; ).
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Total Body Clearance (CLT) • Given in Drug Monographs
• Mechanism of clearance not identified
• Sum total of processes:
CLT = CLM+ CLR+CLBILE +...
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• Rather than describing in terms of amount of drug removed per unit time, Clearance is described as volume of plasma cleared of drug per unit time (volume/time)
10 Litres
1000 mg Drug
L/hr
100 mg/L
Simplest case- a beaker…
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DRUG
URINEke
Metabolites
km
KIDNEY
Bile
kbile
LIVER
BODY
IV
Vd
But the body’s not a beaker- multiple systems involved…..
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Calculation of Clearance
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Clearance calculated using:
Elimination Rate Constants.
CLT = K (V)
CL r (renal) = ke (V)
CL m (metab) = km (V)
CL bile = kbile (V)
Add all processes & cancel out Volume terms …
K = km + ke + kbile + ….
Beaker- Single Tap Analogy
Processescontributing
METHOD 1.
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Model Dependent
• 2 compartment model has distribution & elimination occurring.
K = hybrid value
– Need accurate measurement of K and V
• Assumes First Order Kinetics are followed.
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• In many drug monographs – I can only find information on the half-life and distribution. Isn’t this as good as clearance?
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Relationship between CLT and t½ CLT = KV
CLT = 0.693 *V/ t½
t½ = 0.693 *V / CLT
• t½ inversely related to CLT
• t½ also dependent on volume of distribution.
• K and t½ are dependent on both CLT &V
Model Dependent
K = 0.693/ t½
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DRUGURINE
Ke = 0.147
Metabolites
Km = 0.251
KIDNEY
Bile
Kbile = 0.331LIVER
BODY
IV
Vd = 44 L
Example:
Calculate the CLr, CLT and t ½ for this drug.
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CLr = ke * V
CLT = K * V
T ½ = 0.693/K
Answer:
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METHOD 2
Clearance calculated using drug concentrations:
CL = (dX/dt) / C
• Clearance is defined as rate of drug loss (from total body or organ) relative to the concentration of drug in plasma.
• Model independent
dX/dt = Rate of drug elimination C = Plasma (or blood) concentration
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Rearranging CL = (dX/dt) / C
dX/dt = CL * C
• Clearance can be calculated by plotting elimination rate versus drug concentration.
• Slope will be equal to clearance
• Clearance is a constant.
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Example : Calculation CLr Plot of Urinary Excretion Rate (dAe/dt) versus Drug
Conc (mid-point) can be used to calculate CLr
dAe/dt = CLr•C
dAe/dt
Plasma Drug Concentration
Slope = CLr
• minimum of 2 determinations are needed
calculate slope
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Rather than plotting, clearance can also be calculated by integrating the equation over time.
- This can be any time period, including time zero (t0) to infinity (t∞ )
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Based on previous equation:
dAe/dt = (Clr)C
Integrated to time (t1):
Ae 0-t1 = (Clr) AUC 0-t1
CLr = Ae 0-t / AUC 0-t
Integrated to infinity:
CLr = Ae / AUC
Example : Calculating CLr
should collect urine for 5 t½:
Can be any time period 0-t; t1-t2
*Usually just calculated could also plot intervals
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Drug X- administered IV. Plasma and urine collected for 12 hours. A total of 7.5 mg of Drug X was collected in urine during the 12 hour PK study.
Plasma concentrations determined and AUCs calculated:
AUC 0-12 = 2500 g*hr/L
AUC 0- = 3400 g*hr/L
CLr = ?
Example:
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7.5 mg of Drug X was collected in urine during the 12 hour PK study.
Therefore Ae 0-12 = 7.5 mg
Have to use AUC 0-12
Answer:
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Total body clearance can be obtained by integrating this equation from time zero (t0) to infinity (t ). All drug
eliminated by t
After IV Dose:
CLT = DOSEiv/ AUC
Systemic clearance reflects total amount of time that drug resides in the body.
* Model independent
dX/dt 0-∞ = DOSE
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What if the patient is given an oral dose of the drug!!
How can I calculate clearance?
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Non-IV (Extravascular) Doses
• ** Need to account for bioavailability
• After Oral dose:
CLT= Fpo * DOSEpo/ AUC
Systemic clearance based on amount of drug which gets into the systemic circulation and residence time of drug in body.
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Clearance calculated using:
Physiological parameters of individual organs.
CL organ = Q (ER)
Q = Blood or plasma flow to organ
ER = Extraction Ratio. The efficiency of organ to
clear drug from blood/plasma.
METHOD 3
NB. Can only be used for singleorgans not CLT
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ER= 0 – 1. Can be calculated from differences between amount of drug entering and leaving organ. The proportion of drug entering organ that is eliminated/converted upon each pass through the organ.
Liver
Blood IN Blood OUT
Bile
ER = (Cin - Cout )//
Cin
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Example: The hepatic extraction ratio (ER) for morphine is 0.65 and has a distribution volume of 4 L/kg. Assuming a hepatic flow rate (Q) of 90 L/hr, what would be the expected hepatic clearance for morphine in a 70 kg man after an IV dose.
CL H = Q (ER)
CL H = 90 L/hr *(0.65)
= 58.5 L/hr
Will cover in more detail with more examples in hepatic lectures
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• You will often need to use a combination of these three methods to calculate clearance.
• Look at the information provided and determine which approach you should use for calculations.
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• Organ Clearance often reported in different ways.
• Individual processes/ Organ Clearance may be described and calculated from Total body clearance
. – Addition/Subtraction of Clearance Routes– Fraction of Total Body Clearance
Reporting Clearance
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To Ilustrate : Renal Clearance (CLr)
Renal Clearance (CLr) is one Component of CLT
• Fraction of drug eliminated renally (fe) describes relationship between Renal Clearance (CLr) and Total Clearance (CLT). Also describes the relationship between ke to total body K
fe = CLr = ke CLT K
fraction excreted in urine = Ae/ DOSEIV
(Ae = Total amount of drug excreted in urine)
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Sample Problem. • New Immunosuppressant- Noreject is cleared by
both renal (60%) and non-renal excretion and has a V of 150L. In healthy patients, AUC of 1530 g.hr/L is obtained after a 100 mg IV dose.
a) What is the half-life of Noreject?
b) What is the predicted renal and non-renal clearance of Noreject?
c) What is the urinary elimination rate constant (ke) of Noreject ?
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Solution- A. What is the Half-life?
CLT = Dose/ AUC
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Solution- B. What is CLr and CLnr?
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Solution C.
What is ke ?
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Where are we now?
• Can determine clearance based on:– Plasma concentrations (Cp or AUC)– Elimination rate constants– Extraction efficiency of organ
• Can calculate relative contribution of individual clearance routes from total body clearance.
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Sample Problems to work on at home
Applied Biopharm & PK, 5th edition
p 158 # 3, 4, 5, 6, 9
P 348-50 # 1, 2, 11