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Title: CONTROLLED DRUG RELEASE


1
CONTROLLED DRUG RELEASE
  • Department of Chemical Engineering, University Of
    Waterloo, Waterloo, Ontario
  • Chemical Engineering Concepts 1
  • Professor Mario Ioannidis
  • The University of Waterloos Web Page
  • Mike Di Fabio, 20060432
  • Claire Allen, 20060497
  • Andrea Lekawski, 20064395
  • Christopher Takacs, 20082405
  • K section -03

2
WHAT IS CONTROLLED DRUG RELEASE
  • This site contains information about the
    history of controlled drug release, its different
    applications, mainly intravenous, oral, and
    transdermal, and the future of controlled drug
    release. The underlying theory behind controlled
    drug release is to maintain a level concentration
    of medicine in the body that will allow more
    effective treatment.
  • The goal of controlled drug release is to
    minimise the use of invasive instruments in
    patient care. This concept is still relatively
    new and there is a lot of excitement surrounding
    its possible applications.

3
WHERE IT ALL STARTED...
  • 1950s- Wursters Process was developed at the
    University of Wisconsin. When the idea to
    control the release first came about, they needed
    a way to encapsulate the drugs. The next slide
    shows a picture of this machine. The machine
    uses a fluid bed and a drying devices to surround
    particles. It was the first machine invented for
    this purpose. The main idea behind this is
    microencapsulation.
  • 1953- Coavercation. This allowed drugs to be
    encapsuled when in the liquid form.
  • 1956-1966 Over 50 patents were filed for
    different types of microencapsulation.
  • 1970s- Implants were developed.
  • 1980s- Transdermals were created.
  • 2001 And the future- focus on site directed
    delivery systems.

4
INTRAVENOUS DRUG DELIVERY
  • Most people will encounter some form of
    intravenous drug delivery during the course of
    their lifetime. More often than not, it is
    considered an unpleasant intrusion. What many
    people do not realize though, is that the
    alternative could be much worse.
  • Because the human body has the ability to
    completely circulate blood throughout the system
    within one minute, injecting medicine directly
    into the blood stream distributes medicines
    throughout the body quickly. Combined with
    advanced control methods, the performance of
    drugs can be increased by regulating the flow
    rate into the body by maintaining a specific
    concentration or delivering drugs at regular
    intervals.
  • There are three main types of intravenous
    infusion therapy
  • i) Gravity Flow
  • ii) Mechanical Pump
  • iii) Syringe Pump

5
INTRAVENOUS DRUG DELIVERY
  • Gravity Flow Intravenous Therapy delivers
    drugs, contained in a resevoir above the patient,
    by allowing gravity to force the drugs contained
    in the fluid to flow into the circulatory system.
    The hydrostatic pressure caused by the elevation
    creates a greater pressure into the venous blood
    stream. As the arterial system has a relatively
    higher pressure, a gravity delivered drug
    introduced via the arteries is not possible.
  • Similar to gravity fed systems, Mechanical
    pumps drive medicines into the body via a
    catheter inserted into a vein. Using a pipe
    allows more control over flow rate. Minor
    adjustments can also be made according to how the
    patient is responding to the medicine.
    Additionally, it allows doses to be administered
    at regular intervals if a steady concentration is
    undesirable.
  • Syringe pumps have been vitally important in
    delivering drugs to the body throughout the last
    century. New developments have allowed syringes
    to better control the delivery of drugs to
    localized areas (ie. Delivering Novacane before
    extracting a tooth)

6
Oral Release Systems
  • Delivery Rates
  • There are four different rates through which the
    drug can be delivered to the body sustained
    release, modified release, pulsatic release, and
    chrono release (i.e. chronotherapy).
  • Sustained Release (Fig. A)
  • The drug is released in the body at a specific
    rate over an extended period of time, allowing
  • optimal therapeutic effects. This is a very safe
    process that allows the patient to reduce the
  • number of doses.
  • Modified Release (Fig. B)
  • A relatively large portion of the drug is
    released immediately to provide immediate
    effects.
  • The remainder is released in a sustained fashion.
    This method of release is applicable to
  • pain relief medication, since the patient will
    receive immediate and continuous comfort .
  • Pulsatic Release (Fig. C)
  • Designated amounts of the drug are released
    according to a schedule defined by time
  • delays. This method of drug release is very
    useful for certain cardiovascular compounds to
  • optimize the drugs effects.
  • Chrono Release (Fig. D)

7
These graphs represent the amount of drug
delivered to the body over a period of time for
each of the delivery rates.
Oral Release Systems
Sustained Release (Fig A)
Modified Release (Fig B)
Pulsatic Release (Fig C)
Chrono Release (Fig D)
8
Oral Release Systems
  • Delivery Methods
  • Diffusion
  • The diffusion system is either composed of a
    polymer membrane encapsulating the drug, or a
    polymer matrix in which the drug is suspended.
    Water diffuses through the polymer and dissolves
    the drug, which then diffuses out of the polymer.
    The rate of release of the membrane system is
    time dependent, while the matrix system is
    dependent on the concentration of drug present.
  • Solvent-Activated Release
  • This system is composed of a semi-permeable
    membrane with a small, laser drilled hole.
    Inside is an osmotic agent, either the drug
    itself or a salt, that causes water to enter the
    system. The resulting increase in pressure
    forces the drug to leave the system through the
    hole. The rate of release for this system is
    constant.
  • Degradation
  • The degradation packaging system involves either
    water-soluble polymers made insoluble through
    cross linking, water-insoluble polymers made
    soluble by hydrolysis or ionization of side
    groups, or water-insoluble polymers that are
    cleaved into soluble monomers. In all of these
    types, the main theory behind the system is that
    as they are exposed to water, the polymers break
    up, releasing the drug. The rate of release for
    this system is unpredictable, and entire dose
    dumping can occur.

9
TRANSDERMAL DRUG RELEASE 1
  • Transdermal drug release is a system that uses a
    small patch that is placed on the skin.
  • The skin then absorbs the liquid within the
    patch. This concept was first discovered at the
    turn of the century, when dimethyl sulfoxide was
    found to reach the systemic circulation when
    placed on the skin. Since that time there have
    been several advances in the field of transdermal
    controlled drug release.
  • There are two fundamental types of transdermal
    drug release (i) skin-controlled device, this
    type relies on the skin to control the rate at
    which the drug is absorbed (ii)
    system-controlled device, this type relies on the
    system to control the rate at which the drug
    enters the body. (1) These two different designs
    correspond to two different dosing systems, (i)
    reservoir system and (ii) monolithic system.
  • The reservoir system is made up of four layers a
    water-resistant backing layer, the drug
    reservoir, the rate controlling membrane, and the
    adhesive layer which directly contacts the skin.
    As this system releases a constant amount of the
    drug over a specified amount of time, the rate of
    delivery must always be less than what the skin
    can absorb in that time period.

10
TRANSDERMAL DRUG RELEASE 2
  • The monolithic design has only three layers a
    water-resistant backing, a polymer matrix
    containing the drug and the adhesive layer that
    comes into direct contact with the skin. For this
    system, the skin controls the rate of absorption
    therefore the rate of delivery must always be at
    exactly what the skin can absorb. As this level
    decreases, the rate of delivery decreases as
    well.
  • The advantages of transdermal drug release
    systems are
  • Avoids drug interactions
  • Substitute for oral drugs
  • Several day therapy with a single application
  • The disadvantages of transdermal drug release
    systems are
  • Cannot be used with all drugs
  • Limited time that a patch can remain on the skin
  • Skin sensitivities

11
RELATED DIAGRAMS
Fig. 2 Monolith
Fig. 1 Wursters Process
Fig. 3 Membrane
12
THE FUTURE
  • This industry is just starting to grow, and many
    changes are taking place.
  • Researchers are trying to provide more control
    over the release of the drug, improve the
    efficency, safety, and convience, and to decrease
    side effects. The possibilities for controlled
    drug release are quite broad.
  • So much research is being done that it is hard
    to pin point what will happen in the future. To
    see what direction some people are heading, look
    at theJournal of controlled Drug Release
    (http//www.elsevier.nl/locate/inca/502690)
    research is also being done by many societies,
    such as the Controlled Release Society, and the
    Japanesse Society of Drug Delievery Systems
    (http//www.engr.umbc.edu/chaubal/com.html).
    Research being done by pharmacies can also be
    found on this site.
  • There are hurdles that must be overcome in order
    to make controlled drug release a more effective
    tool, but researchers around the world are trying
    to find solutions to problems that still persist
    today.

13
REFERENCES
  • Ansel, HC. 1995. Pharmaceutical Dosage Forms
    and Drug Delivery Systems. Malvern, PA Williams
    and Wilkins. Available Online
    http//www.cop.ufl.edu/safezone/prokai/pha5110/tdd
    s.htm
  • Bronzino, Joseph D. 1995. Parenteral Infusion
    Devices. In The Biomedical Engineering Handbook,
    ed Butterfield, Robert D (1311-1321). Boca
    Raton, Florida CRC Press Inc.
  • Eurand Corporation. Customised Release.Available
    online http//www.eurand.com/wt/tert.php3?page_na
    mecustomized_rls
  • Maria Jose' Alonso, Dept. Pharmaceutical
    Technology. University of Santiago de Compostela,
    Spain. Controlled Release Of Peptides And
    Antigens From Biodegradable Polymer
    Microspheres. Available online
    http//www.medfarm.unito.it/pharmaco/itcrs/erasmus
    /erasm20.html
  • Ms. Tesheia Johnson, PhD at Yale University.
    Available online http//www5.bae.ncsu.edu/bae/res
    earch/blanchard/www/465/textbook/otherprojects/dru
    gDeliver_97/intro.htm

14
REFERENCES
  • Segal, Marian. October 1991. Patches, Pumps,
    and Timed Release new ways to deliver drugs.
    Available at http//www.fda.gov/bbs/topics/CONSUM
    ER/CON000112.html
  • Thrash, T. 1995. Controlled-Release Drug
    Delivery Systems Mechanisms of
    Intestinal-Specific Polymeric Degradation.
    Available online http//www.denison.edu/chem/DCS/
    journal/thrashv1n1.shtml
  • Wendy Chan. 1999/2000. Nicotine Patches What
    quitters use to win. Journal of young
    Investigators Undergraduate Science Journal.
    Available online http//jyi.org/issues/issue3/fea
    tures/chan.html.
  • Figure 1 Available Online http//www.bae.ncsu.
    edu/bae/research/blanchard/www/465/textbook/otherp
    rojects/drugDeliver_97/wurster.html
  • Figure 2 and 3. Ansel, HC. and Allen, Lv Jr.
    1999. Pharmaceutical Dosage Forms and Drug
    Delivery Systems. Seventh Edition.
    Philadelphia, PA Lippincott Williams and
    Wilkins. Available online http//www.bae.ncsu.e
    du/bae/research/blanchard/www/465/textbook/otherpr
    ojects/drugDeliver_97/
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