Dopaminergic modulation of neuropathic pain: analgesia in rats by a D2-type receptor agonist.

Experimental studies have shown that dopaminergic mechanisms can modulate both nociception and chronic pain perception, but such property is not exploited pharmacologically at the clinical level. We have previously shown that levodopa produces D2-receptor-mediated antiallodynic effects in rats with peripheral mononeuropathy. Here, we test the effects of a D2-type receptor (D2R) agonist, quinpirole, on neuropathic pain in rats. Allodynic responses to cooling and light touch were measured in the hind limbs of rats with chronic constriction injury of one sciatic nerve. Single intraperitoneal injection of quinpirole (1 mg/kg) totally inhibited cold and tactile allodynic responses for over 3 and 48 h, respectively. At that dose, quinpirole had no effect on nocifensive responses to heat. Lumbar intrathecal injection of quinpirole produced short-term inhibition of the responses to cold and tactile stimuli, suggesting that spinal mechanisms may contribute to the antiallodynic activity of quinpirole. Chronic subcutaneous infusion of quinpirole by implanted Alzet pumps (0.025 mg/kg·day) provided a slowly progressing inhibition of cold and tactile allodynic responses, which re-emerged after the pumps were removed. These experiments show the involvement of dopaminergic systems in the modulation of chronic allodynias and provide experimental support for proposing the use of D2R agonists for neuropathic pain relief.

Levodopa analgesia in experimental neuropathic pain.

Levodopa has been shown to produce analgesia in various clinical and experimental settings, but its use for chronic pain treatment has not been established. We have undertaken a study of the antiallodynic actions of levodopa in a rat model of painful mononeuropathy. When administered systemically, levodopa produced a decrease in tactile and cold allodynia lasting at least 3h. Direct intrathecal (i.t.) levodopa injection at lumbar levels produced a similar, though shorter, antiallodynic effect. This effect was blocked by the D2-type receptor antagonist sulpiride, which supports the involvement of the spinal dopaminergic system in the analgesic action of levodopa on neuropathic pain. These results provide experimental support on the antiallodynic effect of levodopa in neuropathic pain and suggest that at least part of the analgesic action takes place in the spinal cord and involves dopaminergic D2-type receptors.

Use of transduced adipose tissue stromal cells as biologic minipumps to deliver levodopa for the treatment of neuropathic pain: possibilities and limitations.

Subarachnoidal grafting of monoamine-producing cells has been used with success to treat chronic pain in animal models. In the search for a source of autologous transplantable cells, capable of delivering neuroactive substances to the cerebrospinal fluid (CSF) to treat pain, we have tested adipose tissue-derived stromal cells (ADSCs) transduced to produce levodopa. Intrathecally grafted ADSCs survive for long term adhered to spinal cord and nerve root meninges. Cultured ADSCs were retrovirally transduced with tyrosine hydroxylase (TH) and/or GTP cyclohydroxylase 1 (GCH1) genes and stably expressed them for at least 6 weeks in culture. Singly transduced cultures did not produce measurable levodopa but doubly transduced or a mixture of singly transduced ADSCs were able to efficiently synthesize and release levodopa. When 0.5-1 x 10(6) TH- and GCH1-expressing ADSCs were intrathecally grafted in rats, elevated levels of levodopa and dopamine metabolites were found in CSF at 3 days, although at lower concentrations than expected. Unexpectedly, no levodopa was measurable in CSF at 6 days. In a rat model of neuropathic pain, intrathecal grafting of doubly transduced cells did not produce antiallodynic effects at 2 or 6 days, even when histological analysis revealed the presence of weak TH-immunoreactive subarachnoidal cell clusters. These results suggested that doubly transduced cells could indeed function as biological minipumps to enhance the dopaminergic neurotransmission at the spinal cord level but transgenes were rapidly silenced after intrathecal grafting. Transgene silencing was mimicked in culture by serum deprivation for 3 days. Serum addition at this point recovered transgene expression in just 6 h, as did, to a smaller degree, dbcAMP or histone deacetylase inhibitors. Transgene expression silencing in serum deprivation conditions was prevented by 5'-terminal IRES sequences. The present study does not discard the use of transduced cells as a strategy to treat chronic pain but shows that controlling transgene silencing in implanted cells needs to be achieved first.