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Local Anaesthesia and Vasoconstrictors

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Title: Local Anaesthesia and Vasoconstrictors


1
Local Anaesthesia and Vasoconstrictors
  • Dr. Hassan Abdin
  • Division of Oral Maxillofacial Surgery

2
Local anaesthesia
  • Anaesthesia is the loss of consciousness and all
    form of sensation.
  • Local Anaesthesia is the local loss of pain,
    temperature, touch, pressure and all other
    sensation.
  • In dentistry, Only loss of pain sensation is
    desirable. Local Analgesia.

3
Local anaesthetic agents
  • Are drugs that block nerve conduction when
    applied locally to nerve tissues in appropriate
    concentrations, acts on any part of the nervous
    system, peripheral or central and any type of
    nerve fibres, sensory or motor.

4
Local anaesthesia
  • Methods
  • Reducing temperature.
  • Is used only to produce surface anaesthesia e.g.
    ethyl chloride spray.
  • Physical damage to nerve trunk e.g. nerve
    sectioning.
  • Unsafe for therapeutic uses, only in Trigeminal
    Neuralgia.
  • Chemical damage to nerve trunk e.g. neurolytic
    agents.
  • Silver nitrate, Phenol - Unsafe for therapeutic
    use.

5
Local anaesthesia
  • Methods Cont
  • Anoxia or hypoxia resulting in lack of oxygen to
    nerve.
  • Unsafe as well.
  • Stimulation of large nerve fibres, blocking the
    perception of smaller diameter fibres.
  • includes Acupuncture and TENS (Transcutaneous
    Electronic Nerve Stimulation)
  • Drugs that block transmission at sensory nerve
    endings or along nerve fibres.
  • There action is fully reversible and without
    permanent damage to the tissues.

6
Local anaesthesia
  • Properties of Ideal local Anaesthetic
  • Possess a specific and reversible action.
  • They stabilize all excitable membrane including
    motor neurones
  • CNS is extremely sensitive to its action.
  • Non-irritant with no permanent damage to tissues.
  • No Systemic toxicity
  • High therapeutic ratio.
  • Rapid onset and long duration
  • Active Topically or by injection

7
Local anaesthesia
  • Chemistry
  • They are weak bases, insoluble in water
  • converted into soluble salts by adding Hcl for
    clinical use.
  • They are composed of three parts
  • Aromatic (lipophilic) residue with acidic group
    R1.
  • Intermediate aliphatic chain, which is either
    ester or amide link R2.
  • Terminal amino (hydrophilic) group R3 and R4.
  • R3
  • R1CO R2 N
  • R4

8
Classification
  • Classified according to their chemical structures
    and the determining factor is the intermediate
    chain, into two groups
  • Ester Amide
  • They differ in two important respect
  • Their ability to induce hypersensitivity
    reaction.
  • Their pharmacokinetics - fate and metabolism.

9
Physiochemical properties
  • These are very important for local anaesthetic
    activity.
  • Ionization
  • They are weak base and exist partly in an
    unionized and partly in an ionized form.
  • The proportion depend on
  • the pKa or dissociation constant
  • The pH of the surrounding medium.
  • Both ionizing and unionizing are important in
    producing local anaesthesia.

10
Physiochemical properties (cont.)
  • pKa is the pH at which the ionized and unionized
    form of an agent are present in equal amounts.
  • The lower the pKa , the more the unionized form,
    the greater the lipid solubility.
  • The higher the pKa , the more the ionized form
    and the slower the lipid solubility

11
Physiochemical properties (cont.)
  • Cont
  • Unionized form is able to cross the bi-lipid
    nerve membrane.
  • The ionized form then blocks conduction.
  • Some of the unionized inside the cell will become
    ionized depending upon the pKa and the
    intracellular pH (lower than extracellular)

12
Physiochemical properties (cont.)
  • Cont
  • In general the amide type have lower pKa, and
    greater proportion of the drug is present in the
    lipid-soluble (unionized) form at the
    physiological pH
  • This produces faster onset of action.
  • Lignocaine 1 2 minutes
  • Procaine 2 5 minutes.
  • The lower the pKa the faster the onset.

13
Physiochemical properties (cont.)
  • Partition coefficient
  • This measures the relative solubility of an agent
    in fat and water.
  • High numerical value means
  • High lipid-soluble
  • less water-soluble.
  • More fat solubility, means rapid crossing of the
    lipid barrier of the nerve sheath.
  • The greater partition coefficient, The faster the
    onset

14
Physiochemical properties (cont.)
  • Protein binding
  • Local anaesthetic agents bind with
  • a1-acid glycoprotein, which possess high affinity
    but low capacity.
  • Albumin, with low affinity but high capacity
  • The binding is simple, reversible and tend to
    increase in proportion to the side chain.
  • Lignocaine is 64 bound, Bupivacaine is 96
  • The duration of action is related to the degree
    of binding.
  • Lignocaine 15 45 minutes, Bupivacaine 6 hours

15
Physiochemical properties (cont.)
  • Vasodilatory ability
  • Most Local anaesthetics possess a vasodilatory
    action on blood vessels except Cocaine.
  • It influence the duration of action of the agent.
  • Prilocaine is 50 bound to proteins but has a
    longer duration than Lignocaine (64) since it
    possess no strong vasodilatory effect.
  • Affect the duration of action of the agent

16
Physiochemical properties (cont.)
  • Summary
  • Rapid Onset
  • Low pKa value more unionized Amides
  • Higher Partition coefficient more lipid soluble
  • Long duration of action
  • High protein binding.
  • Low vasodilating property.

17
Physiochemical properties (cont.)
18
Pharmacodynamics Pharmacological actions
  • Reversible block of conduction in nerve.
  • Direct relaxation of smooth muscle inhibition
    of neuro-muscular transmission in skeletal muscle
    producing vasodilatation.
  • Intra-arterial procaine reverse arteriospasm
    during I.V. Sedation
  • Class I antidysrhythmic-like action on the heart.
  • Stimulation and/or depression of the CNS.

19
Pharmacodynamics Mechanism of Action
(cont.)
  • The site of action is the nerve cell membrane
  • Theories
  • The membrane expansion theory.
  • The specific binding theory.

20
Pharmacodynamics Mechanism of Action
(cont.)
  • Membrane expansion theory
  • A non-specific mechanism similar to the action of
    general anaesthetic agents.
  • Relies upon the lipophilic moiety of local
    anaesthetic agent.
  • The molecules of the agent are incorporated into
    the lipid cell membrane.
  • The resultant swelling produces physical
    obstruction of the sodium channels, preventing
    nerve depolarization.

21
Pharmacodynamics Mechanism of Action
(cont.)
  • Specific receptor theory
  • Local anaesthetic drug binds to specific receptor
    within the sodium channel producing physical
    obstruction to entry of sodium ions.
  • The act of binding produces a conformational
    changes within the channel.
  • It bind to a closed gate and maintain it in the
    closed position.
  • It is, then, essential that the nerve fires, and
    the gate assumes the closed position.
    (Use-dependant phenomenon

22
Fate Metabolism
  • Absorption
  • Many factors influence entry of local anaesthetic
    into the circulation
  • Vasodilating ability of the drug.
  • Volume and concentration.
  • Vascularity of the tissues.
  • The route of administration.
  • The presence of vasoconstrictor.

23
Ester-type drugs
  • Cocaine
  • The first and most potent local anaesthetic
    agent, rarely used because of the problems of
    misuse.
  • It is unique in it is ability to produce intense
    vasoconstriction. Half life 30 minutes.
  • Dosage
  • Used as topical 4 10 solution
  • Maximum dose is 1.5 mg/kg 100mg max.
  • Used intranasally during apical surgery.

24
Ester-type drugs
  • Procaine
  • The only indication for its use in dentistry is
    in patients with proven allergy to the amide
    group.
  • Used intra-arterially, as part of the recognized
    regimen, to treat the arteriospasm which might
    occur during intravenous sedation.
  • It has an excellent vasodilatory properties.

25
Ester-type drugs Procaine (cont)
  • Onset duration of Action
  • Has a very shot duration (5 minutes) and a long
    onset time of 10 minutes
  • Dosages
  • The maximum dose is 6 mg/kg, 400 mg max.
  • Used as 2 with 180 000 epinephrine to increase
    efficacy.
  • Metabolism
  • Rapidly by plasma esterase.

26
Ester-type drugs
  • Benzocaine
  • Used mainly as topical, due to its poor water
    solubility, and because of its low toxicity, it
    is used in concentration up to 20.
  • Hydrolyzed rapidly by plasma esterase to
    p-aminobenzoic acid accounting for its low
    toxicity.

27
Fate Metabolism
  • Metabolism of Ester drugs
  • Metabolized in plasma by peudocholinesterase
    enzyme, and some in the liver.
  • People, who lack the enzyme, are at risk of an
    overdose by the ester type local anaesthetic
  • Para-aminobenzoic acid (PABA) is the major
    metabolite of ester with no anaesthetic effect.
  • It is the agent responsible for ester allergies.
  • Rapid metabolism procaine half-life is 2 minutes

28
Amide-type drugs
  • Lignocaine (Lidocaine)
  • Synthesized in 1943 and used in dentistry since
    1948 and is also known as Xylocaine
  • It highly lipophilic (partition coefficient 3) ,
    rapidly absorbed.
  • Metabolized only in the liver and its metabolites
    are less toxic with no action.
  • Has half-life (t0.5) of 90 minutes

29
Amide-type drugs Lignocaine (cont)
  • Dosage
  • 4.4 mg/kg 300 mg max
  • Used as 2 plain or with 180 000 epinephrine
  • 4 and 10 spray, 2 gel and 5 ointments.
  • Onset duration of action
  • Rapid onset 2 3 minutes
  • Plain- short duration (10 minutes)
  • With epinephrine- intermediate duration (45 60
    minutes)

30
Amide-type drugs
  • Prilocaine
  • A very potent local anaesthetic and is less toxic
    than Lignocaine.
  • It produces less vasodilatation than lignocaine
  • Rate of clearance is higher than other
    amide-types, suggesting extra-hepatic metabolism
    with relatively low blood concentration.
  • Its metabolite o-toluidine lead to
    methaemo-globinaemia (more than 600 mg in adults)

31
Amide-type drugs Prilocaine
  • Used either plain 4 or 3 combined with
    0.03IU/mL of Felypressin as vasoconstrictor.
  • Onset Duration
  • Slower onset 4 minutes.
  • Its duration of action is similar to Lignocaine.
  • Dosage
  • 6.0 mg/kg max. 400 mg.
  • Combined with Lignocaine as a topical anaesthetic
    agent to be used prior to vene-section and during
    dental sedation in children.

32
Amide-type drugs
  • Mepivacaine
  • Possess the least vasodilating effect.
  • Metabolized in the liver and has t0.5 of 120
    minutes.
  • Its main indication is when local anaesthetic
    without vasoconstrictor is needed. 3 plain is
    more effective than lignocaine.
  • Onset duration
  • Rapid onset but slightly shorter duration.

33
Amide-type drugs
  • Bupivacaine
  • A long-acting local anaesthetic agent, with a
    t0.5 of 160 minutes due grater binding capacity
    to plasma protein and tissue proteins
  • Metabolized in the liver.
  • Used mainly in Oral surgical procedures for its
    long-lasting pain control.
  • Longer onset and longer duration (Regional 6 8
    hors)
  • Dosage
  • 1.3 mg/kg Max 90 mg
  • 0.25 0.75 with or without adrenaline 1200 000

34
Amide-type drugs
  • Etidocaine
  • A long-acting agent similar to Bupivacaine but
    with faster onset.
  • Metabolized in the liver.
  • Dosage
  • 8 mg/kg Max 400 mg
  • 1.5 with 1200 000 epinephrine.
  • Lignocaine is the most common used agent both
    topically and by injection as 2 with or without
    adrenaline, with a maximum dose of 4.4 mg/kg.

35
Fate Metabolism
  • Amide Drugs
  • metabolized in the liver, except Prilocaine which
    undergo some biotransformation in the kidney and
    lungs.
  • Some of the metabolites possess local anaesthetic
    and sedative properties.
  • Normal local anaesthetic dose in patient with
    impaired liver function will result in relative
    overdosage.
  • Old age patient shows reduction in liver function
  • Reduce dose

36
Vasoconstrictors
  • Originally added to reduce systemic uptake in an
    attempt to limit toxicity.
  • Prolong the duration
  • Produces profound anaesthesia.
  • Reduce operative bleeding.
  • Two types
  • Sympathomimetic naturally occurring.
  • Synthetic polypeptides, Felypressin

37
Vasoconstrictors
  • Epinephrine (Adrenaline)
  • Uses in dentistry
  • Local anaesthetic solution.
  • Gingival retraction cords.
  • In the ER as life-saving drug in anaphylaxis.
  • Mechanism of action
  • Interact with adrenergic receptors in the vessels
  • a1 a2 producing vasoconstriction in skin MM
  • ß2 stimulation causing vasodilatation in skeletal
    muscles.

38
Vasoconstrictors Epinephrine
  • Metabolism
  • Appears very rapidly in the systemic circulation
    !!!
  • Exogenously administered epinephrine is
    metabolized extraneuronal and 1 is excreted in
    the urine unchanged.
  • Dosage
  • 180,000 is the commonest dose used, 12.5
    µg/ml

39
Vasoconstrictors Epinephrine
  • Systemic effect
  • Being a naturally occurring hormone, it exert a
    number of physiological responses on the
    different systems.
  • The heart
  • Has direct and indirect action.
  • Direct action on ß1 receptors increases the rate
    and force of contraction raising cardiac output.
  • Indirect action, increase pulse and cardiac
    output, lead to rise in systolic blood pressure,
    (not with dental dose)

40
Vasoconstrictors Epinephrine
  • Blood vessels
  • Contain a1, a2 and ß2 adrenoreceptors in the
    vessels of the skin, mucous membrane and skeletal
    muscles.
  • a1 receptors causes vasoconstriction since they
    are susceptible to endogenous nor-epinephrine and
    exogenous epinephrine. Reduce operative bleeding

41
Vasoconstrictors Epinephrine
  • a2 receptors are only susceptible to circulating
    epinephrine.
  • ß2 found in the skeletal muscles, and very
    uncommon in the skin and mucous membrane. ß2
    stimulation result in vasodilatation, lowering
    peripheral resistance and a fall in the diastolic
    blood pressure. (with dental dose)

42
Vasoconstrictors Epinephrine
  • Haemostasis
  • The vasoconstricting effect.
  • Adrenaline promote platelets aggregation in the
    early stages.
  • Fibrinolytic activity compromise clot stability.
  • Lungs
  • Stimulation of ß2 receptors in the lung lead to
    bronchial muscle relaxation, life-saving in
    bronchial (spasm) constriction during
    anaphylactic reaction.
  • Wound healing
  • Reduced local tissue oxygen tension.
  • Epinephrine-induced fibrinolysis.

43
Vasoconstrictors
  • Felypressin
  • It is an analogue of the naturally occurring
    Vasopressin.
  • Bind to vasopressin V1 receptor in the vascular
    smooth muscle producing vaso-constriction and
    reduce local blood flow.
  • Less potent than the catecholamines poorer
    control of bleeding during operative procedures.
  • Acts on the venous side rather than the arterial
    side.
  • Dose
  • 0.03 IU/ml (0.54 µg/ml)
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