Chemistry:Antiparkinson medication

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An antiparkinson medication is a type of drug which is intended to treat and relieve the symptoms of Parkinson's disease. Most of these agents act by either increasing dopamine activity or reducing acetylcholine activity in the central nervous system.

Parkinson's disease

Main page: Medicine:Parkinson's disease

Parkinson's disease is a motor system disorder of the nervous system. It is outlined as a progressive disorder that affects movement and results in the loss of dopamine-producing brain cells, causing tremor in the hands, arms, legs, jaw, and face and/or rigidity or stiffness of the limbs and trunk.[1] The primary symptoms are muscular rigidity, slowness of movement, a resting tremor, and postural instability.[2] Parkinson's disease is caused by degeneration of the nigrostriatal system, which is the dopamine-secreting neurons of the substantia nigra that send axons to the basal ganglia.[2] The basal ganglia controls the automatic, habitual responses performed by the human body.

Depicts the substantia nigra.
This picture shows the Substantia nigra, the part of the brain that is affected in Parkinson's disease.

It is difficult to diagnose Parkinson's disease, as there is no specific test for it. Doctors usually perform other tests in order to rule out other conditions.[3] Often seen in the dopaminergic neurons in the brains of patients who have Parkinson's disease, are Lewy bodies, which are abnormal circular structures found within the cytoplasm. Lewy bodies have a dense protein core, surrounded by a halo of radiating fibers.[2] Mutations on chromosome 4 can cause Parkinson's disease. This gene produces a protein known as a-synuclein. This protein which is normally found in the presynaptic terminals and is thought to be involved in synaptic transmission in dopaminergic neurons. The mutation produces what is known as a toxic gain of function because it produces a protein that results in effects that are toxic to the cell. Parkinson's disease can also be caused by a mutation on chromosome 6. This gene has been named parkin. This mutation causes a loss of function, which makes it a recessive disorder.[2]

Common medication

Dopamine pathways in the brain.
This picture shows the dopamine pathways in the brain. The goal of antiparkinson agents is to restore these pathways to full function.

The goal of the most common Antiparkinson drugs is to either replace the dopamine levels in the brain, or mimic the actions of dopamine. The main categories of Antiparkinson drugs are anticholinergic drugs and dopaminergic drugs. Anticholinergic drugs block the action of acetylcholine, compensating for the low levels of dopamine. As stated before, dopaminergic drugs aim to replace dopamine or inhibit the degradation of dopamine in the brain.[4]

L-DOPA

Once a preliminary diagnosis is made, carbidopa-levodopa can be given as an antiparkinson medication. If this medication shows improvement, doctors will likely confirm their diagnosis. This standard treatment for Parkinson's disease is referred to as L-DOPA, the precursor of dopamine. L-DOPA causes the person's remaining dopaminergic neurons to produce and secrete more dopamine, counteracting the effects of Parkinson's disease. However, eventually the nigrostriatal dopaminergic neurons in the brain drop to a low enough count where the symptoms of Parkinson's disease become worse. This is due to the short half-life of L-DOPA in the body; typically 1.5–2 hours.[5] L-DOPA also activates DA neurons in the mesolimbic/mesocortical system and produces side effects such as hallucinations and delusions.[2]

Deprenyl

A medicine that can be given with L-DOPA, or separately, is deprenyl. Deprenyl inhibits the activity of the enzyme MAO-B, which then will slow the progression of Parkinson's disease. Deprenyl, however, does not completely stop the degeneration of dopaminergic neurons.[2] Deprenyl delays the time before other antiparkinson drugs, like L-DOPA, need to be used.[6]

Tyrosine hydroxylase

Tyrosine hydroxylase catalyzes the formation of L-DOPA, the rate-limiting step in the biosynthesis of dopamine.[7] In other words, it is a precursor to neurotransmitters and increases plasma neurotransmitter levels of dopamine and norepinephrine.[8] This medication should not be used when taking L-DOPA, as L-DOPA interferes with the absorption of Tyrosine.[9]

Apomorphine

Apomorphine has also been used to treat Parkinson's disease. It is referred to as a dopamine receptor agonist. However, it does cause severe side effects when used on its own.[10]

Anticholinergic drugs

Anticholinergic drugs include benzhexol and orphenadrine. These drugs reduce the effect of acetylcholine in the brain by antagonizing cholinergic receptors. This helps restore the acetylcholine/dopamine balance within the brain. Again with these treatments, about 70% of patients taking anticholinergics develop serious side effects, including hallucinations, dyskinetic movements, vision effects, difficulty swallowing, dry mouth and urine retention.[10]

mGluR4

N-phenyl-7-(hydroxylimino)cyclopropa[b]chromen-1a-carboxamide (PHCCC) is now being studied as a selective allosteric potentiator of mGluR4. Metabotropic glutamate receptor 4 (mGluR4) is a potential drug target for Parkinson's disease. PHCCC selectively potentiated agonist-induced mGluR4 activity in cells expressing this receptor and did not itself act as an agonist. PHCCC also potentiated the effect of L-(+)-2-amino-4-phosphonobutyric acid in inhibiting transmission at the striatopallidal synapse. This is significant due to the striatopallidal synapse being proposed as a target for Parkinson's disease treatment. This can hopefully restore balance in the basal ganglia motor circuit.[11]

Research

Recent research for alleviating the symptoms of Parkinson's disease involves stereotaxic procedures. These procedures are typically done when patients no longer respond to antiparkinson drugs. These procedures include transplantation of fetal tissue in an attempt to reestablish the secretion of dopamine in the neostriatum. Researchers have also attempted strategies of gene therapy. A genetically modified virus was inserted into the subthalamic nucleus of patients with Parkinson's disease. This virus delivered a gene for GAD, which is the enzyme responsible for the biosynthesis of the major inhibitory neurotransmitter, GABA. In the study, GAD turned some of the excitatory glutamate-producing neurons in the sub-thalamic nucleus into inhibitory, GABA-producing neurons, improving the symptoms of Parkinson's disease.[2]

Examples

COMT inhibitors block one of two ways levodopa can be inactivated before it reaches the central nervous system (CNS) and is activated to dopamine; peripheral inhibitors of DOPA decarboxylase (AADC) block the second way. (Dopamine in the periphery only causes side effects, no antiparkinson effect.) MAO-B inhibitors slow down degradation of dopamine in the CNS.[12]

References

  1. NINDS. "NINDS Parkinson's Disease Information Page." Parkinson's Disease Information Page: National Institute of Neurological Disorders and Stroke (NINDS). National Institute of Neurological Disorders and Stroke, 12 Mar. 2014. Web. 12 Mar. 2014.
  2. 2.0 2.1 2.2 2.3 2.4 2.5 2.6 Neil Carlson. Pearson Education, Inc.. ed. Psychology of Behavior (11 ed.). pp. 533–538. 
  3. Mayo Clinic Staff. "Parkinson's Disease." Diagnosis at Mayo Clinic. Mayo Foundation for Medical Education and Research, 2014. Web. 12 Mar. 2014.
  4. Parkinson's UK. "Anticholinergics". http://www.parkinsons.org.uk/content/anticholinergics. Retrieved 30 April 2014. 
  5. NIH DailyMed. "Sinemet". http://dailymed.nlm.nih.gov/dailymed/lookup.cfm?setid=be8e535a-2f3a-42b1-bb18-ab88b20eea99. Retrieved 21 August 2014. 
  6. Tetrud, JW; JW Langston (4 August 1989). "The effect of deprenyl (selegiline) on the natural history of Parkinson's disease". Science 245 (4917): 519–522. doi:10.1126/science.2502843. PMID 2502843. Bibcode1989Sci...245..519T. 
  7. Haavik, J; Toska, K. (June 1998). "Tyrosine Hydroxylase and Parkinson's". Mol. Neurobiol. 16 (3): 285–309. doi:10.1007/BF02741387. PMID 9626667. 
  8. Rasmussen, DD; Ishizuka, B; Quigley, ME; Yen, SS (1983). "Effects of tyrosine and tryptophan ingestion on plasma catecholamine and 3,4-dihydroxyphenylacetic acid concentrations". J. Clin. Endocrinol. Metab. 57 (4): 760–3. doi:10.1210/jcem-57-4-760. PMID 6885965. 
  9. University of Maryland Medical Center. "Tyrosine". https://umm.edu/health/medical/altmed/supplement/tyrosine. Retrieved 30 April 2014. 
  10. 10.0 10.1 Donovan, Stephen. "Parkinson's Disease Treatment". http://www.google.com/patents/US6620415. Retrieved 16 April 2014. 
  11. Marino, Michael (11 November 2003). "Allosteric modulation of group III metabotropic glutamate receptor 4: A potential approach to Parkinson's disease treatment". PNAS 100 (23): 13668–13673. doi:10.1073/pnas.1835724100. PMID 14593202. Bibcode2003PNAS..10013668M. 
  12. Mutschler, Ernst; Schäfer-Korting, Monika (2001) (in German). Arzneimittelwirkungen (8 ed.). Stuttgart: Wissenschaftliche Verlagsgesellschaft. pp. 313–316. ISBN 3-8047-1763-2. 
  13. (in German) Arzneistoff-Profile. 10 (13 ed.). Eschborn, Germany: Govi Pharmazeutischer Verlag. 1998. ISBN 978-3-7741-9846-3.