Pharmacology Lab PDF

Summary

This document provides an overview of drug distribution, covering concepts like absorption, metabolism, excretion, and tissue distribution. It includes interactive diagrams and examples of drug interactions. Key pharmacokinetic parameters and their clinical relevance are discussed.

Full Transcript

31
 1.
drug moves freely

2 bounded
drugs.

Albumin – Acidic drugs
Alpha 1-acid glycoprotein – Basic drugs

memorize numbers
don't

Plasma protein are
huge molecules
so doesn't transport easily

In the bloodstream, drugs are transported partly as
free (unbound) drug and partly reversibly bound to
blood components ( eg , plasma proteins, blood
cells).
Of the many plasma proteins that can interact
with drugs, the most important are albumin,
glycoprotein, and lipoproteins. Acidic drugs are
usually bound more
extensively to Albumin; basic drugs are usually
bound more to glycoprotein, lipoproteins, or both.
Only unbound free drug is available for diffusion
to tissues to achieve pharmacologic effects of the drug
bound to then gets distributed
Major Plasma protein that drugs
bound to it
Albumin : basic plasma protein , acidic drugs

Alpha 1 adid glycoprotein
:

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 and bound
drug
non
difference between bound

Free/Unbound drug – Available for therapeutic (and
adverse) effects; Also metabolized by liver.

Bound drug – Do not move out of the systemic
circulation; Not metabolized.

Higher the protein binding, longer is the drug
action.

Protein-binding is a reversible process.
not permenant
Drug A: 20% protein bound
Drug B: 60% protein bound
smost likely to exibit longer
duration

When the drug is distributed in the systemic circulation, it is the free form of the drug
that can move out of the blood vessels and produce therapeutic effect as well also be
metabolized by the liver. The bound form of the drug will stay in the circulation and
acts as a reservoir. Once the free form of the drug reduces, the drug which is bound
to the plasma proteins become free and will be available for action and so the
protein-binding is a reversible process.

33
not reala
Drug-Drug interaction due to plasma protein
displacement
Example 1: Drug A is 20% protein bound Example 2: Drug A is 99% protein bound
8 molecules free
2 molecule bound

Drug A 1 Drug A 2
3

I
Y

Albumin
Albumin S

2 9

g 6
7

Drug B Drug B

When two or more drugs that bind to the same plasma protein are administered,
they interact and result in drug displacement. The effect would be much pronounced
for a drug that has extensive plasma protein binding.

34
 Disease states affecting the protein binding of
drugs Unbound fraction of acidic drugs increase –
May require dose reduction

Unbound fraction of basic drugs decrease –
May require dose increase

In patients with hepatic insufficiency, there is a reduction in the synthesis of plasma
proteins particularly albumin. Hence, there is reduced binding of acidic drugs.
Similarly, in renal failure, more albumin is excreted and so there is reduction in the
plasma albumin concentration. Hence, there is reduced binding of acidic drugs.

On the other hand, in inflammatory states, there is more production of alpha-1
antiglobulin due to which there is an increased binding of the basic drugs.

Patients who develop Kidney or liver

problems , their plasma albumin can be

if acidic
low , so
they're given drugs,
doses should be reduced to reduce

risk of adverse effect

35
 Tissue distribution of drugs

The unbound drug freely moves across the blood vessels and depending on their
lipophilicity and molecular sizes, they enter the tissues either passively or through
active transport.

more fatty =
easier transport big size and no lipophilicity

bigger Size = easier transport
use active transport

blood
when drug is
circulating in

either bound or free form free

form has ability to cross blood

vessels and reach tissue.

36
Organ blood flow varies and so influences the
tissue distribution of the drug.

-
& --

Also, the amount of blood flow to each of the organs in the body varies. As the drug
is present in the blood, due to this variation, there is a difference in the quantity of
drug reaching each of these tissues.

37
 More the
tissue
affinity of
the drug,
more will be
the tissue
distribution.

attraction

More the tissue affinity of the drug, more will be the tissue distribution.

tissu distribution depend on

-
blood flow
affinity of to peripheral +issue
-

drug

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 Central
compartment

Peripheral
compartment

Central compartment is the one in which drug enters from the site of administration
and is metabolized and excreted. Peripheral compartment refers to the tissues in
which the drug freely moves, stays there sometime, and returns to the central
compartment.

lood
X
Central compartment
enters site of administration
drug
-

and is metabolized 3, excreted

all tissues
Peripheral compartment
-
tissue in which
drug moves
freely stays
,
,

then return to central compartment

↑
all tissues that recieves
body
in
drug
from centeral compartment

39
 True or False
v
centeral

Drugs get eliminated from peripheral compartment. F
Drugs enter peripheral compartment directly without
entering central compartment. F > first has to reach central

More number of drug molecules can stay in the
peripheral compartment compared to central
compartment. T

More number of drug molecules can stay in the central
compartment relative to peripheral compartment. T

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What is the parameter used for representing
the rate and extent of drug absorption?

bloavailability
-

41
 Volume of distribution (Vd)

Volume of Distribution (L) = Amount of drug in the body (mg)
Initial plasma concentration of drug (mg/L)
(mg/L)

Volume = 10 mg/10 mg/L
=1L

The volume of distribution (Vd) is a pharmacokinetic parameter representing an
individual drug’s propensity to either remain in the plasma or redistribute to other
tissue compartments. By definition, Vd relates the total amount of drug in the body to
the plasma concentration of the drug at a given time.

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 not understood

Determination of initial plasma concentration

For IV administration, the initial dose can be found out. But for oral? There is a way. If
you plot the concentrations in logarithmic format, it follows a straight line and
extrapolation of that line will help you to find out the initial drug concentration.

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 Vd < 5 L = Confined to intravascular fluid, with less penetrating the extracellular space.

blood vessel
5.
staying
in
-
mostly

S L) are mainly confined to the intravascular
Drugs with a very small Vd (