Peripheral decarboxylase inhibitors

The main clinical use of COMT inhibitors is as adjunct (or additional adjunct) in the therapy of Parkinson s disease. The standard therapy of Parkinson s disease is oral L-dopa (as a drug levodopa) given with a dopa decarboxylase (DDC) inhibitor (e.g. carbidopa and benserazide), which does not reach the brain. When the peripheral DDC is inhibited, the concentration of 3-O-methyldopa (3-OMD), a product of COMT, in plasma is many times that of L-dopa. Since the half-life of 3-OMD is about 15 h, compared to about 1 h for L-dopa, the concentration of 3-OMD remains particularly high during chronic therapy, especially if new slow release L-dopa preparations are used. A triple therapy (L-dopa plus DDC inhibitor plus COMT-inhibitor) will... 

Figure 15.4 The central and peripheral metabolism of levodopa and its modification by drugs, (a) Levodopa alone. After oral administration alone most dopa is rapidly decarboxylated to DA in the gut and blood with some o-methylated (COMT) to o-methyl/dopa (OMD). Only a small amount (3%) enters the CNS to be converted to DA. (b) After an extracerebral dopa decarboxylase inhibitor. Blocking just the peripheral dopa decarboxylase (DD) with inhibitors like carbidopa and benserazide, that cannot enter the CNS (extra cerebral dopa decarboxylase inhibitors, ExCDDIs), stops the conversion of levodopa to DA peripherally, so that more enters the CNS or is o-methylated peripherally to OMD.

The deamination of DA to DOPAC can be prevented by MAOb inhibitors such as selegiline while COMT inhibitors stop its further o-methylation to HVA and the conversion of dopa to OMD. COMT inhibitors can act just peripherally (entacapone) or in the CNS as well (tolcapone). DD — dopa decarboxylase MAO—monoamine oxidase COMT—catechol-o-methyl transferase... 

Carbidopa, a dopa-decarboxylase inhibitor, is added to the levodopa in order to decrease the peripheral conversion of levodopa to dopamine. It does not cross the blood-brain barrier and does not interfere with levodopa conversion in the brain. Concomitant administration of carbidopa and levodopa allows for lower levodopa doses and minimizes levodopa peripheral side effects such as nausea, vomiting, anorexia, and hypotension. For most patients, at least 75 to 100 mg daily of carbidopa is required to adequately block dopamine decarboxylase in the peripheral metabolism of levodopa in most patients. Taking extra carbidopa may reduce nausea related to initiating levodopa.8,16... 

The answer is c. (idardman, p 510.) Carbidopa is an inhibitor of aromatic L-amino acid decarboxylase. It cannot readily penetrate the central nervous system (CNS) and, thus, decreases the decarboxylation of L-clopa in the peripheral tissues. This promotes an increased concentration of L-clopa in the nigrostriatum, where it is converted to dopamine. In addition, the effective dose of L-dopa can be reduced... 

There is one further elaboration on this therapeutic scheme well worth knowing about. Dopa decarboxylase occurs in peripheral tissues and blood as well as in the brain. Close to 90% of administered L-dopa can be converted to dopamine by this enzyme before it gets into the brain. That is not good since a huge fraction of the L-dopa is lost. This problem was overcome in a very neat way. Carbidopa is an inhibitor of dopa decarboxylase that does not penetrate the blood-brain barrier ... 

Carbidopa therefore inhibits the conversion of L-dopa to dopamine in the peripheral tissues and the blood while leaving it unchanged in the brain. The combination of L-dopa and carbidopa is marketed as Sinemet and was the treatment of choice for parkinsonism for many years. Note the structural similarity between carbidopa and L-dopa. Carbidopa looks enough like L-dopa to occupy the L-dopa site on the decarboxylase. At the same time, the subtle structural differences render carbidopa indifferent to the enzyme. It is an inhibitor, not a substrate. 

Chlorpromazine is an aliphatic phenothiazine antipsychotic used in schizophrenia and which may exacerbate parkinsonism. Co-careldopa is a combination of levodopa and the peripheral dopa-decarboxylase inhibitor, carbidopa. Co-careldopa, amantadine, entacapone and bromocriptine are all indicated in the management of parkinsonism. 

L-Dopa. Dopamine itself cannot penetrate the blood-brain barrier however, its natural precursor, L-dihydroxy-phenylalanine (levodopa), is effective in replenishing striatal dopamine levels, because it is transported across the blood-brain barrier via an amino acid carrier and is subsequently decarboxy-lated by DOPA-decarboxylase, present in striatal tissue. Decarboxylation also takes place in peripheral organs where dopamine is not needed, likely causing undesirable effects (tachycardia, arrhythmias resulting from activation of Pi-adrenoceptors [p. 114], hypotension, and vomiting). Extracerebral production of dopamine can be prevented by inhibitors of DOPA-decarboxylase (car-bidopa, benserazide) that do not penetrate the blood-brain barrier, leaving intracerebral decarboxylation unaffected. Excessive elevation of brain dopamine levels may lead to undesirable reactions, such as involuntary movements (dyskinesias) and mental disturbances. 

Levodopa, the metabolic precursor of dopamine, is the most effective agent in the treatment of Parkinson s disease but not for drug-induced Parkinsonism. Oral levodopa is absorbed by an active transport system for aromatic amino acids. Levodopa has a short elimination half-life of 1-3 hours. Transport over the blood-brain barrier is also mediated by an active process. In the brain levodopa is converted to dopamine by decarboxylation and both its therapeutic and adverse effects are mediated by dopamine. Either re-uptake of dopamine takes place or it is metabolized, mainly by monoamine oxidases. The isoenzyme monoamine oxidase B (MAO-B) is responsible for the majority of oxidative metabolism of dopamine in the striatum. As considerable peripheral conversion of levodopa to dopamine takes place large doses of the drug are needed if given alone. Such doses are associated with a high rate of side effects, especially nausea and vomiting but also cardiovascular adverse reactions. Peripheral dopa decarboxylase inhibitors like carbidopa or benserazide do not cross the blood-brain barrier and therefore only interfere with levodopa decarboxylation in the periphery. The combined treatment with levodopa with a peripheral decarboxylase inhibitor considerably decreases oral levodopa doses. However it should be realized that neuropsychiatric complications are not prevented by decarboxylase inhibitors as even with lower doses relatively more levodopa becomes available in the brain. 

All of the more recent compounds have been tested in randomized double-blind clinical trials using the Unified Parkinson s Disease Rating Scale (UPDRS). We do not however have studies comparing the different drugs nor different treatment durations. In addition, the length of these trials is totally different from that of the natural disease course (20 years). It is paradoxical that levodopa, developed in the sixties, remains today the mainstay treatment for Parkinson s disease (levodopa is always associated with a peripheral decarboxylase inhibitor, either car-bidopa or benzerazide). 

If levodopa is administered alone, it is extensively metabolized by L-aromatic amino acid decarboxylase in the liver, kidney, and gastrointestinal tract. To prevent this peripheral metabolism, levodopa is coadministered with carbidopa (Sinemet), a peripheral decarboxylase inhibitor. The combination of levodopa with carbidopa lowers the necessary dose of levodopa and reduces peripheral side effects associated with its administration. 

Evidence on the potential antidepressant efficacy of L-dopa is more voluminous, but also discouraging [Kapur and Mann 1992 Oren et al. 1994). Despite the definite effects of L-dopa on mood, its antidepressant efficacy, given with or without a peripheral decarboxylase inhibitor, is not established even in the subset of patients with psychomotor retardation and low pretreatment CSF HVA who are supposed to be particularly sensitive to its effects. Standard antidepressants or electroconvulsive therapy are the methods of choice in treating depression in patients with Parkinson s disease, in whom L-dopa appears to have limited or no antidepressant efficacy and has been suspected of producing depression [Cummings 1992). Furthermore, pro-... 

Carbidopa (4.75), a hydrazine analog of a-methyldopa, is an important DOPA decarboxylase inhibitor. It is used to protect the DOPA that is administered in large doses in Parkinson s disease (section 4.4.4) from peripheral decarboxylation. DOPA concentrations in the CNS will therefore increase without requiring the administration of extremely high, toxic doses of DOPA. The exclusive peripheral mode of action of carbidopa is due to its ionic character and inability to cross the blood-brain barrier. Because of this effect, carbidopa is co-administered with DOPA in a single tablet formulation as a first-line therapy for Parkinson s disease. Benserazide (4.76) has similar activity. 

Since Parkinson s disease arises from a deficiency of DA in the brain, the logical treatment is to replace the DA. Unfortunately, dopamine replacement therapy cannot be done with DA because it does not cross the blood-brain barrier. However, high doses (3-8 g/day, orally) of L(-)-DOPA (levodopa), a prodrug of DA, have a remarkable effect on the akinesia and rigidity. The side effects of such enormous doses are numerous and unpleasant, consisting initially of nausea and vomiting and later of uncontrolled movements (limb dyskinesias). The simultaneous administration of carbidopa (4.75) or benserazide (4.76)—peripheral DOPA decarboxylase inhibitors—allows the administration of smaller doses, and also prevents the metabolic formation of peripheral DA, which can act as an emetic at the vomiting center in the brainstem where the blood-brain barrier is not very effective and can be penetrated by peripheral DA. 

Levodopa and peripheral dopa-decarboxylase inhibitor, carbidopa or benserazide in the treatment of parkinsonism. 

Carbidopa and benserazide are peripheral decarboxylase inhibitors used in combination with levodopa. They do not penetrate blood-brain barrier and do not inhibit the conversion into dopamine from levodopa in brain. 

When levodopa is given without a peripheral decarboxylase inhibitor, anorexia and nausea and vomiting occur in about 80% of patients. These adverse effects can be minimized by taking the drug in divided doses, with or immediately after meals, and by increasing the total daily dose very slowly antacids taken 30-60 minutes before levodopa may also be beneficial. The vomiting has been attributed to stimulation of the chemoreceptor trigger zone located in the brain stem but outside the blood-brain barrier. Fortunately, tolerance to this emetic effect develops in many patients. Antiemetics such as phenothiazines should be avoided because they reduce the antiparkinsonism effects of levodopa and may exacerbate the disease. 

A variety of cardiac arrhythmias have been described in patients receiving levodopa, including tachycardia, ventricular extrasystoles and, rarely, atrial fibrillation. This effect has been attributed to increased catecholamine formation peripherally. The incidence of such arrhythmias is low, even in the presence of established cardiac disease, and may be reduced still further if the levodopa is taken in combination with a peripheral decarboxylase inhibitor. 

Pharmacologic doses of pyridoxine (vitamin B6 ) enhance the extracerebral metabolism of levodopa and may therefore prevent its therapeutic effect unless a peripheral decarboxylase inhibitor is also taken. Levodopa should not be given to patients taking monoamine oxidase A inhibitors or within 2 weeks of their discontinuance because such a combination can lead to hypertensive crises. 

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