Tuesday, January 13, 2009

Absorption

In pharmacology (and more specifically pharmacokinetics), absorption is the movement of a drug into the bloodstream.
Absorption involves several phases. First, the drug needs to be administered via some route of administration (oral, via the skin, etc.) and in a specific dosage form such as a tablet, capsule, and so on.
In other situations, such as intravenous therapy, intramuscular injection, enteral nutrition and others, absorption is even more straight-forward and there is less variability in absorption and bioavailability is often near 100%.
Absorption is a primary focus in drug development and medicinal chemistry, since the drug must be absorbed before any medicinal effects can take place. Moreover, the drug's pharmacokinetic profile can be easily and significantly changed by adjusting factors that affect absorption.
The Processes by which the concentration of the drug at any moment and in any region can be determined is done by translocation of drug molecule. The drug is translocated in the body by bulk flow and diffusion. If the drugs chemically differ, still the transfer by bulk flow can occur by the same mechanism but if the drugs are moving by diffusion, it means that their movement is markedly different. The transfer of a drug is highly dependent on its solubility in either lipid or water.
For movement of the drug from the GIT to the system the sink condition is playing a vital role. Sink condition means, the drug is always in circulation due to blood circulation. So, the conc. of drug is not reaching at equilibrium. Thus, the drug can be diffused due to no equilibrium state.
The smaller molecules can move faster than larger ones.

Dissolution
In the most standard situation, a tablet is ingested and passes through the esophagus to the stomach. Because the stomach is an aqueous environment, this is the first place where a tablet will dissolve.
The rate of dissolution is a key target for controlling the duration of a drug's effect, and as such, several dosage forms that contain the same active ingredient may be available, differing only in the rate of dissolution. If a drug is supplied in a form that is not readily dissolved, the drug may be released more gradually over time with a longer duration of action. Having a longer duration of action may improve compliance since the medication will not have to be taken as often. Additionally, slow-release dosage forms may maintain concentrations within an acceptable therapeutic range over a long period of time, as opposed to quick-release dosage forms which may result in sharper peaks and troughs in serum concentrations.
The rate of dissolution is described by the Noyes-Whitney equation as shown below:

Where:
dW/dt is the rate of dissolution.

A is the surface area of the solid.
C is the concentration of the solid in the bulk dissolution medium.
Cs is the concentration of the solid in the diffusion layer surrounding the solid.
D is the diffusion coefficient.
L is the diffusion layer thickness.

As can be inferred by the Noyes-Whitney equation, the rate of dissolution may be modified primarily by altering the surface area of the solid. The surface area may be adjusted by altering the particle size (e.g. micronization). The rate of dissolution may also be altered by choosing a suitable polymorph of a compound. Specifically, cystalline forms dissolve slower than amorphous forms.
Also, coatings on a tablet or a pellet may act a barrier to reduce the rate of dissolution. Coating may also be used to modify where dissolution takes place. For example, enteric coatings may be applied to a drug, so that the coating only dissolves in the basic environment of the intestines. This will prevent release of the drug before reaching the intestines.
Since solutions are already dissolved, they do not need to undergo dissolution before being absorbed.

IonizationThe gastrointestinal tract is lined with epithelial cells. Drugs must pass through these cells in order to be absorbed into the circulatory system. One particular cellular barrier that may prevent absorption of a given drug is the cell membrane. Cell membranes are essentially lipid bilayers which form a semipermeable membrane. Pure lipid bilayers are generally permeable only to small, uncharged solutes. Hence, whether or not a molecule is ionized will affect its absorption, since ionic molecules are considered charged molecules by definition.
The Henderson-Hasselbalch equation offers a way to determine the proportion of a substance that is ionized at a given pH. In the stomach, drugs that are weak acids (such as aspirin) will be present mainly in their non-ionic form, and weak bases will be in their ionic form. Since non-ionic species diffuse more readily through cell membranes, weak acids will have a higher absorption in the highly-acidic stomach.
However, the reverse is true in the basic environment of the intestines-- weak bases (such as caffeine) will diffuse more readily since they will be non-ionic.
This aspect of absorption has been targeted by medicinal chemistry. For example, a suitable analog may be chosen so that the drug is more likely to be in a non-ionic form. Also, prodrugs of a compound may be developed by medicinal chemists-- these chemical variants may be more readily absorbed and then metabolized by the body into the active compound. However, changing the structure of a molecule is less predictable than altering dissolution properties, since changes in chemical structure may affect the pharmacodynamic properties of a drug.

Other factors
factors which affecting bioactivity, resonance, inductive effect, isosterism, bio-isosterism, spatial consideration.

Further reading:
Pharmacokinetics Made Easy, Revised by Donald Birkett

Basic Clinical Pharmacokinetics (Basic Clinical Pharmacokinetics (Winter)) by Michael E. Winter
Applied Clinical Pharmacokinetics by Larry Bauer

Tuesday, December 2, 2008

Bougies

Introduction:
Its name came from the town namely “bougie” in Algeria, which was famous for trading in wax. Its original meaning is “A candle made by wax”. These are the types of suppositories intended for insertion into the urethra, nostrils or ears.
It is also a medical instrument in the shape of cylinder, made up of a flexible tube.

Forms of bougie:

Bulbous bougie:
It is a form of bougie with a bulb shaped tip.

Eder-pustow bougie:
It is a form of metal bougie which resembles olive in shape. It may be used in esophageal stricture.

Elastic bougie:
A bougie made of rubber or latex.

Elbowed bougie:
A bougie with a bent near its tip.

Use:
It is used for opening of constricted areas in tubular organs such as urethra or esophagus and rectum, so, that medicines for local application or another instruments can easily be inserted in that part.

Copyright, (c), 2008, http://jeepakistan.blogspot.com

Pharmaceutics

It is a branch of Pharmacy and is the science of the preparation and dispensing of the drugs on the prescription of doctors. Although it also covers the study of drugs in general.

It is derived from the Greek word “pharmakeutikos” which means relating to drugs.

Further reading:
Modern Pharmaceutics by Gilbert S. Banker and Christopher Rhodes

Copyright, (c), 2008, http://jeepakistan.blogspot.com

Monday, December 1, 2008

Maceration

Introduction:
Maceration is the process of softening and separating a substance by proper soaking it in particular liquid.

Procedure:
In this process, the drug previously powdered and weighed, is put alongwith the menstruum, which is that particular liquid such as ethyl acetate, ethanol or methanol, in a stoppered container.

This thing is then placed at a safe place for a definite period of time such as from two to seven days. Shaking must be done along the time.

Then the product is taken and filtered. Here, the residue obtained on the filter is known as the marc and it is pressed thoroughly, so that there will be no loss. The residue be clarified by subsidence or filtration.

References:

Encyclopedia Britannica 2009 Deluxe (Avanquest)

British Pharmacopoeia 2009 (British Pharmacopoeia) by British Pharmacopoeia Commission

Remington: The Science and Practice of Pharmacy

Copyright, (c), 2008, http://jeepakistan.blogspot.com

Gelatin

Introduction:
It is a form of animal protein which is semisolid and transparent in nature. As the name indicates it has gel forming properties.

Preparation of Gelatin:
It is derived from collagen of tissues and is extracted by boiling skin, bone or cartilage of some larger animals such as deer, cow or buffalo after alkali or acid treatment (hydrolysis), which forms a firm gel like structure when mixed in water.

Types of gelatin:

Type A gelatin:
Type of gelatin obtained from acid treated precursor.

Type B gelatin:
Type of gelatin obtained from alkali treated precursor.

Forms of gelatin:

Vegetable gelatin:
A gelatin like substance obtained from gluten (a protein combination found in certain cereals).

Glycerinated gelatin:
It is made by the treatment of equal proportions of glycerin and gelatin. It is mostly used for suppositories and urethral bougies.

Irish moss gelatin:
It is made by the extraction from Irish moss. It is mostly used as a substitute for gum Arabic in the preparation of emulsions.

Properties:
It is not a complete form of protein as it is deficient of certain amino acids. It is found in the form of sheets, flakes or powders. It is tasteless and odorless. It is faint yellow to amber in color.
It swells when placed in cold water but have the ability of dissolution only in hot water. It can be easily digested by the body.

Uses:
It is used mostly in the products of food and in cooking in home. It is also used to make gel foods such as jellied meats.
It is also in use in medicine. In pharmaceutical industry it is used to make capsules, cometics, hemostat and certain plasma substitutes. It is also used as an emulsifying agent.
It is also used in photography.

Storage:
It can be stored for longer periods in dry and airtight containers.

References:
Encyclopedia Britannica 2009 Deluxe (Avanquest)

British Pharmacopoeia 2009 (British Pharmacopoeia) by British Pharmacopoeia Commission

Remington: The Science and Practice of Pharmacy

Copyright, (c), 2008, http://jeepakistan.blogspot.com

Wednesday, November 19, 2008

Ceftaroline

Ceftaroline is considered as fifth generation cephalosporin. (George H. Talbot et al.) It is a
metabolite of Ceftaroline fosamil.

Action:
(George H. Talbot et al.) It is much potent in vitro against Methicillin resistant staphylococcus aureus.(Shazad Mushtaq et al) It shows good anti-pneumococcal activity.

Therapeutic Uses:
It is used for different skin infections and those infections which are related to skin structure (2).

Administration:
It is administered parenterally (1).

Adverse effects:
In phase 2 studies, it shows only mild headache (2).

References:
(1) http://www.lifescience-online.com/CEFTAROLINE_ACETATE,8270.html?portalPage=Drugs

(2) http://www.medicalnewstoday.com/articles/53029.php

George H. Talbot, Dirk Thye, Anita Das, and Yigong Ge. Phase 2 Study of Ceftaroline versus Standard Therapy in Treatment of Complicated Skin and Skin Structure Infections. Antimicrobial Agents and Chemotherapy, October 2007, Volume 51, Number 10, pages 3612-3616.

Shazad Mushtaq, Marina Warner,Yigong Ge, Kone Kaniga, David M Livermore. In vitro activity of ceftaroline (PPI-0903M, T-91825) against bacteria with defined resistance mechanisms and phenotypes. Journal of Antimicrobial Chemotherapy. Volume 60 Number 2: Pages 300-311, August 2007.

Further reading:
Natural Compounds as Drugs, Volume I (Progress in Drug Research) (Progress in Drug Research) by Frank Peterson and RenAc Amstutz

Antimicrobial Resistance: Problem Pathogens and Clinical Countermeasures (Infectious Disease and Therapy) by Jr. Robert C. Owens and Ebbing Lautenbach

Nosocomial Pneumonia: Strategies for Management by Jordi Rello

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Tuesday, November 18, 2008

Non-steroidal anti-inflammatory drugs

Acetic acid derivatives derivatives
Etodolac


Naphthyl acetic acid prodrug
Nabumetone

Cox-1 selective inhibitors
Acetylsalicylic acid ((Aspirin)at low dosage)

SalicylatesAcetylsalicylic acid (at high doses)
Amoxiprin
Benorylate/Benorilate
Choline magnesium salicylate
Ethenzamide
Faislamine
Methyl salicylate
Magnesium salicylate
Na. Salicylate
Na. thiosalicylate
Salicylic acid
Salicyl salicylate
Salicylamide

Difluorophenyl derivatives
Diflunisal

Indole acetic acids (Arylalkanoic acids)Aceclofenac
Acemethacin
Alclofenac
Bromfenac
Indomethacin
Oxametacin
Proglumetacin
Sulindac

Phenylacetic acid
Diclofenac potassium
Diclofenac sodium

Pyrolealkanoic acid
Tolmetin

2-Arylpropionic acids (profens)
Ibuprofen
Alminoprofen
Carprofen
Dexibuprofen
Dexketoprofen
Fenbufen
Fenoprofen
Flunoxaprofen
Flurbiprofen
Ibuproxam
Indoprofen
Ketoprofen (Actron, at least, has been withdrawn from the market.)
Ketorolac
Loxoprofen
Naproxen
Oxaprozin
Pirprofen
Suprofen
Tiaprofenic acid

N-Arylanthranilic acids (fenamic acids)Mefenamic acid
Flufenamic acid
Meclofenamate
Tolfenamic acid

Pyrazolidine derivatives
Phenylbutazone
Ampyrone
Apazone
Azapropazone
Clofezone
Kebuzone
Metamizole
Mofebutazone
Oxyphenbutazone
Phenazone
Sulfinpyrazone

OxicamsPiroxicam
Droxicam
Lornoxicam
Meloxicam
Tenoxicam

COX-2 inhibitorsCelecoxib (FDA has p-recautioned about its use)


OthersLicofelone
Omega-3 fatty acids

Licofelone acts by inhibiting LOX (lipooxygenase) & COX (cyclooxygenase)and hence known as
5-LOX/COX inhibitor.

Disease modifying anti-rheumatic agents (Slow acting anti-rheumatic agents):
Auranofin (Gold salts)
Aurothiomalate (Gold salts)
Chloroquine
Hydroxychloroquine
Leflunomide
Methotrexate
Penicillamine
Sulfasalazine

Anti-cytokines as anti-rheumatic agents:
Abatacept
Adalimumab
Anakinra
Etanercept
Infliximab
Rituximab

Further reading:
Safety and Efficacy of Non-Prescription (OTC) Analgesics and NSAIDs by K. D. Rainsford and M. C. Powanda

New NSAID appears effective for osteoarthritis: LOX-COX inhibitor.(Clinical Rounds)(licofelone): An article from: Family Practice News
by Mitchel L. Zoler

The Goodman and Gilman Manual of Pharmacology and Therapeutics by Laurence Brunton, Donald blumenthal, Iain buxton and Keith Parker

AHFS Drug Information 2008 (Ahfs Drug Information) by American Society of Health-system

Lippincott's Illustrated Reviews: Pharmacology, 4th Edition (Lippincott's Illustrated Reviews Series) by Richard A. Harvey, Pamela C. Champe, Richard Finkel, Luigi Cubeddu and Michelle A. Clarke
Copyright, (c), 2008, http://jeepakistan.blogspot.com