Difference between revisions of "Selective Serotonin Reuptake Inhibitors (Clomipramine, Fluoxetine)"

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Any adverse reaction should be reported via the NOAH reporting system.
 
Any adverse reaction should be reported via the NOAH reporting system.
 
==Effects on Anxiety and Panic==
 
Panic is a specific manifestation of anxiety and the mechanism of action of drugs that reduce panic share a common factor. Only drugs that reduce the firing rate of neurons in the Locus Coeruleus (LC) effectively reduce panic.
 
 
Numerous models of anxiety have been tested in animals. Many are not apparently reliable detectors of anxiolytic effect, and have not been applied to more modern anxiolytic/antidepressant drugs like SSRIs/SRIs. Those in which there is a response to TCA/SRI and SSRI drugs include:
 
 
*Approach-avoidance conflict (Stretched approach posture test).
 
*Separation distress vocalisation (guinea pig isolation calls, rat pup isolation ultrasonic vocalisation).
 
*Defensive burying in rodents (only some 5-HT reuptake inhibitors)
 
 
Interestingly no effect has been found in those tests (so far performed) that involve conditioned fear potentiated startle responses.
 
  
 
==Use==
 
==Use==

Revision as of 12:41, 12 September 2014

Also known as: SSRI — SRI — Serotonine Reuptake Inhibitors

Mechanism of Action

Tricyclic group of antidepressants (TCA) are chemically similar to phenothiazines. Amitriptyline and clomipramine are examples of drugs of this type, with clomipramine also being classed as a serotonin re-uptake inhibitor due to its modest serotonergic selectivity.

TCAs have three major effects which vary in degree depending on the specific drug used. These are:

  1. Sedation
  2. Central and peripheral anticholinergic action.
  3. Inhibnition of the presynaptic re-uptake mechanisms of neurotransmitters such as noradrenaline and serotonin (5-HT), leading to raised intrasynaptic concentrations of these neurotransmitters[1].

The main target of action for these drugs are structures in the brain that depend upon nor-adrenaline and serotonin as major neurotransmitters, including:

  • Noradrenaline: Locus Coeruleus (LC)
  • Serotonin: Raphe nuclei

Together the LC and Raphe nuclei form parts of the ascending reticular activating system that has projections throughout the CNS and is involved in mood, wakefulness, sleep cycles and arousal as well as pain modulation and a host of other maintenance functions such as meal patterning.

The effect on neurotransmitter levels is quite rapid, but therapeutic effects take 3 weeks or more to become apparent. This is because although clomipramine and many other serotonergic antidepressants (SRI, selective serotonin reuptake inhibitor (SSRI), TCA, atypical) have immediate effects on synaptic neurotransmission, the lasting changes in emotional response are the result of intracellular changes and in altered receptor expression. This is dependent on secondary messenger systems (cAMP, Ca2+, cGMP, IP3), gene expression and protein synthesis that take time to occur. Receptors for nor-adrenaline and serotonin are linked to metabotropic G-proteins that can induce changes in protein synthesis such as the up- and down-regulation of receptors. There are 14 known classes of 5-HT receptors, of these, in anxiety problems the 5-HT1 receptor is the most relevant.

For example, in states of anxiety and depression the following presynaptic changes are thought to occur:

α2-Adrenergic-autoreceptor α2-Adrenergic-heteroreceptor 5-HT1A-autoreceptor
Nor-adrenergic neuron serotonergic neuron serotonergic neuron
Depression/Anxiety ?
Clomipramine

↓=Downregulation of receptor ↑=Upregulation of receptor

These receptors normally inhibit noradrenaline or serotonin release so down regulation of the receptors increases the release of the neurotransmitters. Postsynaptic changes also occur:

α1 Ad-R 5-HT2A, 2C-R 5-HT1A-R β1,2,3-R 5-HT4,6,7-R
Depression/Anxiety ? ?
Clomipramine ? ?

↓=Downregulation of receptor ↑=Upregulation of receptor

Significant changes in receptor numbers take several weeks to occur. The effect of these postsynaptic receptor number changes is an increase in the levels of two crucial compounds, C-amp Response Element Binding Protein (CREB) and Brain Derived Neurotropic Factor (BDNF). The end results of these presynaptic and postsynaptic changes are:

  • Increase in serotonin in the synaptic cleft.
  • Increase in stimulation of postsynaptic 5-HT1A1A-receptors, leading to an elevation of mood (mechanism unknown)
  • Increase in CREB and BDNF, leading to normally CNS adaptation to external events

The exact reason why CREB, BDNF and other neurotropic factors are central to resolving depression and anxiety is to date unclear but it is thought to relate to adaptability of the CNS to external events. These factors affect the rate of protein synthesis and a host of other intracellular processes that take even longer to become active, hence the long delay in efficacy of these drugs. All typical antidepressant drugs work through the common pathway of increasing BDNF.

Clomipramine and TCAs are far more safely and commonly used in behavioural pharmacology in comparison to benzodiazepines, phenothiazines, barbiturates and sympathomimetic agents.

Selective serotonin reuptake inhibitors (SSRIs)

SSRIs are a group of drugs that all have a greater effect on serotonin reuptake than noradrenaline reuptake. Unlike TCAs, which are named on the basis of chemical structure, the SSRIs are named according to their primary effect on serotonin reuptake. The ratio of serotonin reuptake selectivity in favour varies from around 15:1 (fluoxetine) to more than 150:1 (sertraline). Along with increasing serotonergic selectivity, SSRI drugs also show fewer effects on other neurotransmitter systems. In particular, they are less anticholinergic than TCAs.

Adverse Effects[2]

The main adverse effects of this group of drugs is mediated through their effect on histamine (H1) and muscarinic (M1) acetylcholine receptors, as summarised in the table below.

H1 Blockade Ach (Muscarinic) Blockade
Sedation, hypotension, increased appetite, weight gain, anti-allergic activity Delirium, hyperthermia, insomnia, seizure induction, tachycardia, constipation, decreased bronchial secretion, blurred vision, narrow angle glaucoma (exacerbation), photophobia, dry mouth

Amitriptyline also antagonises α2-adrenoceptors, which can lead to agitation and tachycardia. TCAs can also cause loss of libido (breeding animals) and mild corneal drying. They can cause galactorrhea through increased prolactin secretion (especially in cats). TCAs that predominantly alter noradrenaline re-uptake inhibition may predispose patients to sudden and violent emotional reactions including aggression and should be used with care in aggression cases.

There are large differences in selectivity of re-uptake inhibitor drugs, as can be seen in the following table.

Drug Class 5-HT:NorAdrenaline Blocking ratio H1 Blockade Ach (Muscarinic) Blockade
Amitriptyline TCA 1:4 +++ +++
Clomipramine TCA 5:1 ++ ++
Fluoxetine SSRI 15:1 +
Fluvoxamine SSRI 150:1 +
Sertraline SSRI 150:1 +


The blocking ratio indicates the relative effect of the agent on reuptake of serotonin vs. noradrenaline. Fluoxetine is 3 times more selective for serotonin than clomipramine. Clomipramine was the first TCA whose ratio favours serotonin reuptake inhibition, and hence its title of non-selective serotonin reuptake inhibitor (SRI). The level of anticholinergic effect is usually also decreased with increasing serotonergic selectivity.

Caution should be taken if the animal suffers from any of the following pre-existing medical conditions:

  • Heart disease, especially heart block and arrythmias [3][4]
  • Diabetes: increases hyperglycaemia
  • Glaucoma (closed angle type)
  • Impaired liver function (TCAs metabolised by liver)
  • Hyperthyroidism (enhanced response to TCAs)
  • Urinary retention [5].

Care should be taken if used in conjunction with any of the following drugs, which may interact and cause adverse effects:

  • Morphine: enhanced analgesia and respiratory depression.
  • MAOIs: risk of serotonin syndrome, advise washout period of 2-3 weeks between treatment with these drugs.
  • Phenothiazines: increased shared adverse effects (CVS, etc), mutual increase in serum levels due to competition for cytochrome p450. Definite risk of severe adverse affects and toxicity.
  • SSRIs: Fluoxetine inhibits Cytochrome p450, leading to toxic levels of TCA. Cimetidine also has this effect.
  • Fibre rich diets reduce availability of TCAs.
  • Thyroid medications: can interfere, therefore if simultaneously used must be carefully monitored [6]

If the drug is overdosed/combined with an inappropriate drug (see above) an increased sedation and degree of adverse effects as listed will be seen. If the drug dose is persistently high or the drug is combined with an MAOI, serotonin syndrome is a possible consequence:

  • Gastrointestinal distress
  • Head pain
  • Agitation
  • Increased heart rate, body temperature, respiratory rate
  • Muscular rigidity
  • Convulsions
  • Coma
  • Death

Any adverse reaction should be reported via the NOAH reporting system.

Use

  • Licensed (dog)
  • Separation anxiety[7]
  • Unlicensed

Onset of action is 4 or more weeks. The dose of Clomipramine may need to be increased from an initial dose rate once daily, to a higher dose rate if initial response is insufficient after 6-8 weeks. Higher doses are associated with increased adverse effects such as sedation and it is important that genuine response to therapy is not confused with undesirable profound sedative effects which will suppress all sorts of behaviour. Sensitivity of cats to TCAs is generally higher than in dogs as they use glucuronidation to metabolise them[18].

Once the condition being treated is deemed under control, drug therapy can be gradually phased out over a period of 1 week per month of treatment. Sudden withdrawal of medication can lead to relapse, withdrawal effects or discontinuation syndrome, especially with short half-life SRI/SSRI drugs. Successful drug therapy should produce around 70% reduction in the behaviour and an increase in normal activity as a substitute.

Fluoxetine

Fluoxetine is a selective serotonin reuptake inhibitor (SSRI) which functions by inhibiting the reuptake of serotonin in the pre-synaptic neuron. This inhibition of uptake of reuptake of 5-HT1A into pre-synaptic neurons is highly selective and does not affect noradrenaline, dopamine, acetylcholine, histaminic or alpha-1 adrenergic receptors. 5-HT1A receptors have an effect on mood and behaviour. SSRIs are derived from TCAs, such as Clomipramine. SSRIs act to bring about changes in conformation of receptors, this can take 3-5 weeks[19]. Regulation of second messengers (cAMP, Ca2+, cGMP, IP3) is responsible for the major effect. Their actions on protein kinases then act to change neuronal metabolism and receptor protein transcription[20].

Fluoxetine is largely metabolised in the liver by the cytochrome P450 enzyme system to norfluoxetine, also an SSRI.


Uses

  • Licensed (dog)
  • Unlicensed
  • Compulsive disorders[28]
  • Aggression
  • Panic and anxiety disorders[29]
  • Feline Urine Marking

As with other drugs used to treat behavioural problems it is recommended that fluoxetine be used in conjunction with behavioural modification techniques [27][30][31][32][33][34][35]. Fluoxetine has a long half-life and therefore a minimum of 6-8 weeks should be allowed before making an assessment of efficaciousness. Due to the long half-life of fluoxetine it is not necessary to gradually reduce or taper the dose. Once treatment with fluoxetine has ceased continued behavioural modification is advisable to avoid the reappearance of clinical signs. The long half-life of fluoxetine and its metabolites also mean that a period of at least 6 weeks should be allowed to pass before administration of any drugs which may interact adversely.

Adverse Effects[36]

  • Decreased appetite
  • Depression/lethargy
  • Shaking/shivering/tremor
  • Vomiting and diarrhoea
  • Restlessness and anxiety
  • Seizures
  • Aggression
  • Mydriasis
  • Vocalisation
  • Weight loss
  • Panting
  • Confusion
  • Incoordination
  • Hypersalivation

Caution should be taken in if the animal suffers from any of the following pre-existing medical conditions:

  • Contraindicated for animals with a history of epilepsy or seizures

Care should be taken if used in conjunction with any of the following drugs, which may interact and cause adverse effects:

  • Fluoxetine should not be given at the same time as drugs which lower seizure threshold eg. phenothiazines such as acepromazine or chlorpromazine.
  • Monoamine oxidase inhibitors (MAOI), or within a period of 2 weeks after discontinuation of treatment with a MAOI due to the risk of serotonin syndrome[37]
  • Fluoxetine has not been evaluated with drugs that affect the cytochrome P450 enzyme, care should therefore be taken with any drug that affects the enzyme system eg. ketoconazole.


References

  1. Overall, K.L., 2004. Paradigms for pharmacologic use as a treatment component in feline behavioral medicine. Journal of Feline Medicine and Surgery 6, 29-42.
  2. Wiersma, J., Honig, A. & Peters, F. P. J. (2000). Clomipramine-induced allergic hepatitis: a case report. International Journal of Psychiatry in Clinical Practice 4, 69–71.
  3. Pouchelon, J. L., Martel, E., Champeroux, P., Richard, S. & King, J. N. (2000). Effect of clomipramine hydrochloride on the electrocardiogram and heart rate of dogs. American Journal of Veterinary Research, in press.
  4. Reich, M. R., Ohad, D. G., Overall, K. L. & Dunham, A. E. (2000). Electrocardiographic assessment of antianxiety medication in dogs and correlation with drug serum concentration. Journal of the American Veterinary Medical Association 216, 1571–5.
  5. Overall, K.L. 2001. Pharmacological Treatment in Behavioural Medicine: The Importance of Neurochemistry, Molecular Biology and Mechanistic Hypotheses. The Veterinary Journal, 162, 9-23
  6. Gullikers, K.P., Panciera, D.L., 2002. Influence of various medications on canine thyroid function. Compendium of Continuing Education for the Practicing Veterinarian 24, 511-521
  7. Clomipramine hydrochloride data sheet
  8. Thoren, P., Asberg, M. & Cronholm, B. (1980). Clomipramine treatment of obsessive-compulsive disorder. Archives of General Psychiatry 37, 1281–5.
  9. Flament, M. F., Rappoport, J. L. & Berg, C. J. (1985). Clomipramine treatment of childhood obsessive compulsive disorder. A double-blind controlled study. Archives of General Psychiatry 42, 977–83.
  10. Ananth, J. (1986). Clomipramine: an anti-obsessive drug. Canadian Journal of Psychiatry 31, 253–8.
  11. Perse, T. (1988). Obsessive-compulsive disorder: A treatment review. Journal of Clinical Psychiatry 49, 48–55.
  12. McTavish, D. & Benfield, P. (1990). Clomipramine: an overview of its pharmacological properties and a review of its therapeutic use in obsessive-compulsive behavior and panic attack. Drug 39, 136–53.
  13. Overall, K. L. (1994). Use of clomipramine to treat ritualistic motor behavior in dogs. Journal of the American Veterinary Medical Association 205, 1733–41.
  14. Hewson, C. J., Luescher, A., Parent, J. M., Conlon, P. D. & Ball, R. O. (1998b). Efficacy of clomipramine in the treatment of canine compulsive disorder. Journal of the American Veterinary Medical Association 213, 1760–6.
  15. Moon-Fanelli, A. A. & Dodman, N. H. (1998). Description and development of compulsive tail chasing in terriers and response to clomipramine treatment. Journal of the American Veterinary Medical Association 212, 1252–7.
  16. Dodman, N. H., Donnelly, R., Shuster, L., Mertens, P. & Miczek, K. (1996). Use of fluoxetine to treat dominance aggression in dogs. Journal of the American Veterinary Medical Association 209, 1585–7.
  17. Seksel, K. & Lindeman, M. J. (1998). Use of clomipramine in the treatment of anxiety-related and obsessive-compulsive disorders in cats. Australian Veterinary Journal 76, 317–21.
  18. Overall, K.L., 2004. Paradigms for pharmacologic use as a treatment component in feline behavioral medicine. Journal of Feline Medicine and Surgery 6, 29-42.
  19. Overall, K.L., 2004. Paradigms for pharmacologic use as a treatment component in feline behavioural medicine. Journal of Feline Medicine and Surgery 6, 29–42
  20. Overall, K.L., 2001. Pharmacological Treatment in Behavioural Medicine: The Importance of Neurochemistry, Molecular Biology and Mechanistic Hypotheses. The Veterinary Journal, 162, 9–23
  21. Landsberg, G.M., Melese, P., Sherman, B.L., Neilson, J.C., Zimmerman, A., Clarke, T.P., 2008. Effectiveness of fluoxetine chewable tablets in the treatment of canine separation anxiety. Journal of Veterinary Behavior 3, 12-19
  22. Dodman, N.H., Shuster, L., 1994. Pharmacologic approaches to managing behaviour problems in small animals. Vet. Med. 89, 960-969.
  23. Beaver, B.V., 1999. Canine Behavior: A Guide for Veterinarians. W.B. Saunders Company, Philadelphia, PA, pp. 26-28.
  24. Overall, K.L., 2001. Pharmacological treatment in behavioral medicine: the importance of neurochemistry, molecular biology and mechanistic hypotheses. Vet. J. 162, 9-23.
  25. Landsberg, G., Hunthausen, W., Ackerman, L., 2003. In: Handbook of Behavior Problems of the Dog and Cat, 2nd ed. Elsevier Saunders, Philadelphia, pp. 258-267.
  26. Simpson, B.S., Papich, M.G., 2003. Pharmacologic management in veterinary behavioral medicine. Vet. Clin. North Am.: Small Anim. Pract. 33, 365-404.
  27. 27.0 27.1 Simpson, B.S., Landsberg, G.M., Reisner, I.R., Ciribassi, J.J., Horwitz, D., Houpt, K.A., Kroll, T.L., Luescher, A., Moffat, K.S., Douglass, G., Robertson-Plouch, C., Veenhuizen, M.F., Zimmerman, A., Clark, T.P., 2007. Effects of Reconcile (fluoxetine) chewable tablets plus behavior management for canine separation anxiety. Vet. Ther. 8, 18-31. Sonawalla, S.
  28. Altemus, M., Glowa, J. R. & Murphy, D. L., 1993. Attenuation of food restriction-induced running by chronic fluoxetine treatment. Psychopharmacology Bulletin 29, 397–400.
  29. Meltzer-Brody, S., Connor, K. M., Churchill, E. & Davidson, J. R. T., 2000. Symptom-specific effects of fluoxetine in post-traumatic stress disorder. International Clinical Psychopharmacology 15, 227–31.
  30. Petit, S., Pageat, P., Chaurand, J.P., Heude, B., Beata, C., 1999. Efficacy of clomipramine in the treatment of separation anxiety in dogs: clinical trial. Rev. Med. Vet. 2, 133-140.
  31. King, J.N., Simpson, B.S., Overall, K.L., Appleby, D., Pageat, P., Ross, C., Chaurand, J.P., Heath, S., Beata, C., Weiss, A.B., Muller, G., Paris, T., Bataille, B.G., Parker, J., Petit, S., Wren, J., 2000. Treatment of separation anxiety in dogs with clomipramine: results from a prospective, randomized, double-blind, placebo controlled, parallel-group, multicenter clinical trial. Appl. Anim. Behav. Sci. 67, 255-275.
  32. Seksel, K., Lindeman, M.J., 2001. Use of clomipramine in treatment of obsessive-compulsive disorder, separation anxiety and noise phobia in dogs: a preliminary, clinical study. Aust. Vet. J. 79, 252-256.
  33. Horwitz, D., 2000. Diagnosis and treatment of canine separation anxiety and the use of clomipramine hydrochloride. J. Am. Anim. Hosp. Assoc. 36, 107-109.
  34. Takeuchi, Y., Houpt, K.A., Scarlett, J.N., 2000. Evaluation of treatments for separation anxiety in dogs. J. Am. Vet. Med. Assoc. 217, 342-345.
  35. Landsberg, G., Hunthausen, W., Ackerman, L., 2003. In: Handbook of Behavior Problems of the Dog and Cat, 2nd ed. Elsevier Saunders, Philadelphia, pp. 258-267.
  36. Fluoxetine hydrochloride data sheet
  37. Brown, T.M., Skop, B.P., Mareth, T.R., 1996. Pathophysiology and management of the serotonin syndrome. The Annals of Pharmacotherapy 30, 527–533.