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Local anaesthetics

Local anaesthetics. Dr. S. Parthasarathy MD., DA., DNB, MD ( Acu ), Dip. Diab . DCA, Dip. Software statistics PhD ( physio ) Mahatma Gandhi medical college and research institute , puducherry – India . What is it ?? .

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Local anaesthetics

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  1. Local anaesthetics Dr. S. Parthasarathy MD., DA., DNB, MD (Acu), Dip. Diab. DCA, Dip. Software statistics PhD (physio) Mahatma Gandhi medical college and research institute , puducherry – India

  2. What is it ?? • A drug reversibly blocks the nerve conduction beyond the point of application, if applied in appropriate concentrations . • Other drugs !! • Quinidine, phenergan, TCADs --- no

  3. History • Koller is credited with introducing local anesthetics into medical practice when he used cocaine to numb the cornea before operating on the eye. • Isolation of cocaine by Neimann, in 1860 • Procaine was first synthesized in 1904, • In lidocaine 1943 -- but the hierarchy is

  4. History ESTERS AMIDES

  5. The basic chemical structure- 3 parts: • 1. Lipophilic group- an aromatic group, usually an unsaturated benzene ring. • 2. Intermediate bond- a hydrocarbon connecting chain, either an ester (-CO-) or amide (-HNC-) linkage. The intermediate bond determines the classification of local anesthetic. • 3. Hydrophilic group- a tertiary amine and proton acceptor.

  6. COO - ester OR CONH – amide

  7. Amides Esters • BupivacaineBenzocaine • EtidocaineChloroprocaine • Levobupivacaine Cocaine • Lidocaine Procaine • MepivacaineTetracaine • Prilocaine • Ropivacaine

  8. Isomerism • Many medications contain chiral molecules which exist as stereoisomers. • Chiral molecules are asymmetrical and the direction of the configuration helps to categorize the isomer. R and S • Polarized light to right – D • Polarized light to left - L

  9. Bupi and ropi • Bupivacaine is a long acting amide local anesthetic that can be associated with significant toxicity issues. • S-bupivacaine is almost as potent as the racemic preparation but is less toxic. It takes larger doses of S-bupivacaine to cause cardiac arrest and seizure activity than racemic preparations. • Ropivacaine is a second local anesthetic that is a pure S-ropivacaine.

  10. Structure Activity Relationships (Onset, Potency, Duration) p L P = O P D p = pKa = onset L = lipophilicity = potency P = protein binding = duration

  11. Frequency dependent block

  12. Local anesthetics are prepared as a water soluble hydrochloride salt and generally have a pH of 5-6. • If the preparation contains epinephrine, the solution must be acidic to create a stable environment. pH of 3-4. • . To enhance clinical onset, carbonated solutions of epinephrine containing local anesthetics have been used instead of HCL solutions.

  13. pKa • Because local anesthetics are weak bases, increasing the pH (“alkalinization”) of solution increases the ratio of base to cation. • Henderson-Hasselbalch equation can be used to quantitate the ratio: • pKa(local anesthetic) – pH(solution) = Log ([cation]/[base]) NH3 + HCl = NH4+ + cl-

  14. pKa(local anesthetic) – pH(solution) = Log ([cation]/[base]) • If pH is less , the cationic form is more • If the pH is more the unionized form is more

  15. Local anaesthetic

  16. Exceptions to pKa • Two notable exceptions are chloroprocaine and benzocaine. • Chloroprocaine has a high pKa and rapid onset. • Benzocaine does not exist in an ionized form and exerts its effects by alternate mechanisms.

  17. Lipophilic

  18. Nerve cell membrane

  19. Pharmacodynamics • Analgesic effect has been reported following intravenous lidocaine administration in many acute and chronic conditions. • Other than Na channels • inhibition of G-protein coupled receptor signaling • Inhibit NGF

  20. Differential blockade • Bupivacaine and etidocaine are both potent, long acting local anesthetics. • Bupivacaine exhibits a more potent sensory than motor block. • Etidocaine exhibits an equally effective sensory and motor block. • Ropivacaine, on the other hand, exhibits a potent sensory block similar to bupivacaine but motor blockade appears less intense.

  21. most common clinical use of local anesthetics • Regional anesthesia and analgesia. • Topical • Infiltration • Blocks • Neuraxial etc

  22. Other actions • Blunt responses to tracheal instrumentation • attenuating increases in intraocular pressure, intracranial pressure, and intra-abdominal pressure during airway instrumentation.

  23. Other actions • The primary site of action is the myocardium, where decreases in electrical excitability, conduction rate, and force of contraction occur. • Depressed NMJ • The local anesthetics depress contractions in the intact bowel and in strips of isolated intestine. • also relax vascular and bronchial smooth muscle,

  24. Additives • Carbonation of local anesthetics results in a more rapid onset and a more profound degree of conduction blockade, ph higher , More nonionized form, speeder onset , CO2 released diffues inside – acidic- more ionized better action Less tachyphylaxix • Sodabicarb • 1 ml / 20 ml of lignocaine • 0.1 ml /20 ml of bupivacaine

  25. Additives • Vasoconstrictors – epinephrine – 1 in 2 lakh – 5 mic/ ml. • Mixtures of local anaesthetics – • EMLA • Ligno + bupi = OK but ?? • A solution containing 50% of the toxic dose of local anesthetic A, and 50% of the toxic dose of local anesthetic B, will have the same implications as 100% of the toxic dose of either local anesthetic alone.

  26. Additives • Glucose • The specific gravity of hyperbaric (or ‘heavy’) bupivacaine is 1.026 at 20 ◦C. • The specific gravity of cerebrospinal fluid is 1.005 at 37 ◦C, • Warming of the local anesthetic solutions can also bring about a modified onset time

  27. Additives • Hyaluronidase, supplied as a white fluffy powder, is used to facilitate the spread through connective tissues following subcutaneous or intramuscular injection.

  28. Additives • Drug Receptor Uses • Opioids / mu and kappa Central ,periph • Clonidine 2-adrenoceptor Central periphe • Ketamine NMDA Central

  29. Duration of Action . Local anesthetics are classified as follows: • Short acting: procaine and chloroprocaine • Moderate acting: lidocaine, mepivacaine, prilocaine • Long acting: tetracaine, bupivacaine, etidocaine, ropivacaine, levobupivacaine

  30. Pharmacokinetics

  31. Metabolism • The metabolism : ester vs. amide. • Ester local anesthetics undergo extensive hydrolysis in the plasma by pseudocholinesterase enzymes (plasma cholinesterase or butyrylcholinesterase). - - rapid, resulting in water soluble metabolites which are excreted in the urine. • The ester that is an exception is cocaine. In addition to ester hydrolysis cocaine is partially metabolized in the liver (N-methylation).

  32. Metabolism Procaine and benzocaine are metabolized to p-aminobenzoic acid (PABA), which has been associated with allergic reactions When ester local anesthetics are placed in the CSF, metabolism does not occur until there has been vascular absorption of the local anesthetic. CSF does not contain esterase enzymes.

  33. Metabolism • Amide local anesthetics are metabolized primarily by microsomal P-450 enzymes in the liver (N-dealkylation and hydroxylation) and, to a lesser extent, in other tissues. • Most studied lignocaine • Monoethylglycinexylidide --- xylidine

  34. Some drug interactions

  35. Side effects • The hydrolysis of all ester-linked local anesthetics leads to the formation of para-aminobenzoic acid (PABA) or a substituted PABA. • True allergic reactions are associated with amino ester-linked local anesthetics, not amino amide-linked one • Tissue Toxicity • Myotoxicity and neurotoxicity

  36. Cardiovascular Toxicity • bupivacaine exhibits a much stronger binding affinity to resting and inactivated sodium channels than lidocaine • Bupivacaine dissociates from sodium channels during cardiac diastole much more slowly than lidocaine • Hence bupicardiotoxicity is more dangerous

  37. Methemoglobinemia • The metabolism of prilocaine in the liver results in the formation of O-toluidine, which is responsible for the oxidation of hemoglobin to methemoglobin. • The methemoglobinemia associated with prilocaine is spontaneously reversible or may be treated by IV methylene blue.

  38. Toxicity • IV > tracheal > intercostal > caudal > paracervical > epidural > brachial > sciatic > subcutaneous

  39. Treatment of Systemic Toxicity from Local Anesthetics • Prevention • aspiration for blood, • use of a small test dose of local anesthetic • slow injection • fractionation of the rest of the dose of local anesthetic

  40. Treatment of systemic toxicity is primarily supportive • Injection of local anesthetic should be stopped. • Oxygenation and ventilation should be maintained • If needed intubate and ventilate • Midaz, thio if seizures , ephedrine IVF • IV lipid for bupi • Can we give propofol??

  41. Neural Toxicity of Local Anesthetics • local anesthetic–induced injury to Schwann cells, inhibition of fast axonal transport, disruption of the blood-nerve barrier, decreased neural blood flow disruption of cell membrane integrity • radiculopathy to be approximately 0.03% and of paraplegia to be approximately 0.0008%.

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