Pharmacokinetics Lecture 1 Lecture Notes PDF

Summary

This document contains lecture notes on pharmacology, specifically focusing on pharmacokinetics. It covers the processes of absorption, distribution, metabolism, and elimination of drugs, along with examples and relevant details.

Full Transcript

**Subject**

**Pharmacology**

**Lecture 1**

**Pharmacokinetics**

**Name: Anas Suleiman**

**Number: 0790028580**

**Pharmacokinetics:**

**Pharmacokinetics (PK)** involves the movement of drugs within the body
and is described by four primary processes: absorption, distribution,
metabolism, and elimination (ADME). Understanding these processes is
crucial for determining appropriate drug dosages and routes of
administration.

**1. Absorption**

- **Overview**: Absorption is the process by which a drug enters the
bloodstream from its site of administration (e.g., oral,
intravenous). Key factors influencing absorption include drug
formulation, route of administration, and physicochemical properties
such as solubility, ionization, and molecular size.

- **Mechanisms**:

- **Passive Diffusion**: The most common process, where drugs move
from a high concentration (e.g., GI tract) to a lower
concentration (e.g., bloodstream) without energy use.
Lipid-soluble and non-ionized drugs favor passive diffusion.

- **Facilitated Diffusion**: Drugs move along a concentration
gradient but require carrier proteins. For example, glucose
transport via GLUT transporters.

- **Active Transport**: Energy-dependent transport that moves
drugs against their concentration gradient, using carriers like
P-glycoprotein (important in the gut and brain).

- **Endocytosis**: Larger molecules (e.g., proteins or antibodies)
are engulfed by cell membranes in vesicles for cellular uptake.
An example is vitamin B12 absorption in the intestines.

- **Example**: Aspirin (a weak acid) is absorbed primarily in the
stomach due to the acidic environment, favoring its non-ionized form
for passive diffusion.

**2. Distribution**

- **Overview**: Distribution describes how drugs move from the
bloodstream into tissues and organs. It is largely influenced by
blood flow, tissue permeability, drug binding to plasma proteins
(like albumin), and the drug\'s lipid solubility.

- **Volume of Distribution (Vd)**: A theoretical volume that
represents how extensively a drug distributes into body tissues
relative to the blood. It helps in determining the loading dose.

- **Low Vd**: Drugs that stay in the bloodstream, such as heparin.

- **High Vd**: Drugs that distribute widely into tissues, such as
lipophilic drugs like chloroquine.

- **Example**: Warfarin, an anticoagulant, binds extensively to
albumin, meaning only the free (unbound) fraction of the drug exerts
its effect, leading to a low Vd.

**3. Metabolism**

- **Overview**: Metabolism primarily occurs in the liver and converts
lipophilic drugs into more water-soluble metabolites for excretion.
It is divided into two phases:

- **Phase I (Functionalization Reactions)**: Introduces or exposes
functional groups on the drug molecule through oxidation (often
via cytochrome P450 enzymes), reduction, or hydrolysis. These
reactions usually increase the drug\'s polarity.

- **Example**: The metabolism of diazepam (Valium) through
oxidation by CYP3A4.

- **Phase II (Conjugation Reactions)**: The drug or its Phase I
metabolite is conjugated with a larger polar molecule (e.g.,
glucuronide, sulfate) to increase solubility and facilitate
renal excretion.

- **Example**: Glucuronidation of morphine increases its
solubility for excretion.

- **Cytochrome P450 (CYP) Enzymes**: CYP enzymes are responsible for
many Phase I reactions. Inducers (e.g., rifampin) can increase
enzyme activity, leading to faster drug clearance, while inhibitors
(e.g., ketoconazole) slow down metabolism, increasing drug levels.

**4. Elimination**

- **Overview**: Drugs are eliminated from the body through metabolism
and excretion (primarily renal and biliary routes). Elimination
kinetics determine how drug levels decline over time.

- **First-Order Kinetics**: The majority of drugs follow
first-order kinetics, where a constant fraction of the drug is
eliminated per unit time. The rate of elimination is
proportional to the drug concentration.

- **Example**: Most antibiotics follow first-order
elimination, where higher concentrations lead to faster
clearance.

- **Zero-Order Kinetics**: In zero-order kinetics, a constant
amount of the drug is eliminated per unit time, regardless of
concentration. This occurs when elimination pathways are
saturated.

- **Example**: Ethanol exhibits zero-order kinetics, where a
constant amount is cleared per hour, regardless of how much
is in the system.

- **Half-life (t½)**: The time required for the drug concentration to
decrease by half in the body. It is key to determining dosing
intervals.

**5. Steady State**

- **Overview**: Steady-state concentration (Css) occurs when the rate
of drug administration equals the rate of drug elimination. For most
drugs, steady state is achieved after approximately 4-5 half-lives.

- **Loading Dose**: Given to rapidly achieve therapeutic
concentration, especially in drugs with a long half-life. For
instance, digoxin requires a loading dose due to its long half-life.

- **Example**: A patient receiving a continuous IV infusion of a drug
like vancomycin will reach a steady state after several half-lives,
and dosing can be adjusted based on therapeutic levels.