Isoquinolines, beta-carbolines and alcohol drinking: Involvement of opioid and dopaminergic mechanisms (original) (raw)

References

1. Adachi, J., Mizoi, Y., Fukunaga, T., Kogame, M., Ninomiya, I., and Naito, T., Effect of acetaldehyde on urinary salsolinol in healthy man after alcohol intake. Alcohol_3_ (1986) 215–220.
   Article CAS PubMed Google Scholar
2. Adachi, J., Mizoi, Y., Fukunaga, T., Ueno, Y., Imamichi, H., Ninomiya, I., and Naito, T., Individual difference in urinary excretion of salsolinol in alcoholic patients. Alcohol_3_ (1986) 371–375.
   Article CAS PubMed Google Scholar
3. Airaksinen, M. M., Mahonen, M., Tuomisto, L., Peura, P., and Eriksson, C. J. P., Tetrahydro-β-carbolines: effect of alcohol intake in rats. Pharmac. Biochem. Behav.18 (1983) 525–529.
   Article CAS Google Scholar
4. Alari, L., Lewander, T., and Sjoquist, B., The effect of ethanol on the brain catecholamine systems in female mice, rats, and guinea pigs. Alc. clin. exp. Res.11 (1987) 144–149.
   Article CAS Google Scholar
5. Altshuler, H. L., Phillips, P. E., and Feinhandler, D. A., Alteration of ethanol self-administration by naltrexone. Life Sci.26 (1980) 679–688.
   Article CAS PubMed Google Scholar
6. Blum, K., and Topel, H., Opioid peptides and alcoholism: genetic difficiency and chemical management. Estratto da: New Trends funct. Neurol.1 (1986) 71–83.
   CAS Google Scholar
7. Blum, K., Briggs, A. H., Trachtenberg, M. C., DeLallo, L., and Wallace, J. E., Enkephalinase inhibition: Regulation of ethanol intake in genetically predisposed mice. Alcohol_4_ (1987) 449–456.
   Article CAS PubMed Google Scholar
8. Blum, K., Briggs, A. H., Elston, S. F. A., Hirst, M., Hamilton, M. G., and Verebey, K., A common denominator theory of alcohol and opiate dependence: review of similarities and differences, in: Alcohol Tolerance and Dependence, pp. 371–391. Eds J. Crabbe and R. Rigter. Elsevier/North-Holland Biomedical Press, 1980.
9. Blum, K., Briggs, A. H., DeLallo, L., Elston, S. F. A., and Ochoa, R., Whole brain methionine-enkephalin of ethanol-avoiding and ethanol-preferring C57BL mice. Experientia_38_ (1982) 1469–1470.
   Article CAS PubMed Google Scholar
10. Borg, S., Kvande, H., Rydberg, U., Terenius, L., and Wahlstrom, A., Endorphin levels in human cerebrospinal fluid during alcohol intoxication and withdrawal. Psychopharmacology_78_ (1982) 101–103.
    Article CAS PubMed Google Scholar
11. Brien, J. F., Andrews, P. J., Loomis, C. W., and Page, J. A., Gasliquid chromatographic determination of salsolinol in the striatum of rat brain during the calcium carbimide-ethanol interaction. Can. J. Physiol. Pharmac.61 (1983) 632–640.
    Article CAS Google Scholar
12. Britton, D. R., Rivier, C., Shier, T., Bloom, F., and Valet, W., In vivo and in vitro effects of tetrahydroisoquinolines and other alkaloids on rat pituitary function. Biochem. Pharmac.31 (1982) 1205–1211.
    Article CAS Google Scholar
13. Brown, Z. W., Amit, A., and Smith, B., Examination of the role of tetrahydroisquinoline alkaloids in the mediation of ethanol consumption in rats. Adv. expl. Med. Biol.126 (1980) 103–120.
    Article CAS Google Scholar
14. Buckholtz, N. S., Neurobiology of tetrahydro-β-carbolines. Life Sci.27 (1980) 893–903.
    Article CAS PubMed Google Scholar
15. Cardinale, G. J., Donnerer, J., Finck, A. D., Kantrowitz, J. D., Oka, K., and Spector, S., Morphine and codeine are endogenous components of human cerebrospinal fluid. Life Sci.40 (1987) 301–306.
    Article CAS PubMed Google Scholar
16. Cascio, C. S., and Kellar, K. J., Tetrahydro-β-carbolines: Affinities for tryptamine and serotonergic binding sites. Neuropharmacology_12_ (1982) 1219–1221.
    Article Google Scholar
17. Cashaw, J. L., Geraghty, C. A., McLaughlin, B. R., and Davis, V. E., A method for determination of subpicomole concentrations of tetrahydropapaveroline in rat brain by high-performance liquid chromatography with electrochemical detection. Analyt. Biochem.162 (1987) 274–282.
    Article CAS PubMed Google Scholar
18. Cashaw, J. L., Geraghty, C. A., McLaughlin, B. R., and Davis, V. E., Effect of acute ethanol administration on brain levels of tetrahydropapaveroline in L-dopa-treated rats. J. Neurosci. Res.18 (1987) 497–503.
    Article CAS PubMed Google Scholar
19. Clow, A., Stolerman, I. P., Murray, R. M., and Sandler, M., Ethanol preference in rats: Increased consumption after intraventricular administration of tetrahydropapaveroline. Neuropharmacology_22_ (1983) 563–565.
    Article CAS PubMed Google Scholar
20. Chow, A., Topham, A., Saunders, J. B., Murray, R., Sandler, M., The role of salsolinol in alcohol intake and withdrawal, in: Aldehyde Adducts in Alcoholism, pp. 101–113. Ed. M. A. Collins. Alan Liss, New York 1985.
    Google Scholar
21. Cohen, G., The synaptic properties of some tetrahydroisoquinoline alkaloids. Alc. clin. expl. Res.2 (1978) 121–125.
    Article CAS Google Scholar
22. Cohen, G., and Collins, M., Alkaloids from catecholamines in adrenal tissue: Possible role of alcoholism. Science_167_ (1970) 1749–1751.
    Article CAS PubMed Google Scholar
23. Collins, D. M., and Myers, R. D., Buspirone attenuates volitional alcohol intake in the chronically drinking monkey. Alcohol_4_ (1987) 49–56.
    Article CAS PubMed Google Scholar
24. Collins, M. A., A possible neurochemical mechanism for brain and nerve damage associated with chronic alcoholism. Trends pharmac. Sci.3 (1982) 373–375.
    Article CAS Google Scholar
25. Collins, M. A., ed., Aldehyde Adducts in Alcoholism. Alan Liss, New York 1985.
    Google Scholar
26. Collins, M. A., and Kahn, A. J., Attraction to ethanol solutions in mice: induction by a tetrahydroisoquinoline derivative of L-Dopa. Subs. Alc. Actions/Misuse_3_ (1982) 299–302.
    CAS Google Scholar
27. Collins, M. A., Hannigan, J. J., Origitano, T., Moura, D., and Osswald, W., On the occurrence, assay and metabolism of simple tetrahydroisoquinolines in mamalian tissues, in: Beta-Carbolines and Tetrahydroisoquinolines, pp. 155–166. Eds F. Bloom, J. Barchas, M. Sandler and E. Usdin. Alan Liss, New York 1982.
    Google Scholar
28. Collins, M. A., Nijm, W. P., Borge, G. F., Teas, G., and Goldfarb, C., Dopamine-related tetrahydroisoquinolines: significant urinary excretion by alcoholics after alcohol consumption. Science_206_ (1979) 1184–1186.
    Article CAS PubMed Google Scholar
29. Critcher, E. C., and Myers, R. D., Evidence for the hippocampus as a site of action for tetrahydropapaveroline (THP)-or cyanamide-induced alcohol drinking. Alcohol_1_ (1984) 167.
    Article Google Scholar
30. Critcher, E. C., and Myers, R. D., Cyanamide given ICV or systemically to the rat alters subsequent alcohol drinking. Alcohol_4_ (1987) 347–353.
    Article CAS PubMed Google Scholar
31. Critcher, E. C., Lin, C. I., Patel, J., and Myers, R. D., Attenuation of alcohol drinking in tetrahydroisoquinoline-treated rats by morphine and naltrexone. Pharmac. Biochem. Behav.18 (1983) 225–229.
    Article CAS Google Scholar
32. Dar, M. S., and Wooles, W. R., The effect of acute ethanol on dopamine metabolism and other neurotransmitters in the hypothalamus and corpus striatum of mice. J. neural Transm.60 (1984) 283–294.
    Article CAS Google Scholar
33. Davis, V. E., and Walsh, M. J., Alcohol, amines and alkaloids: a possible biochemical basis for alcohol addiction. Science_167_ (1970) 1005–1007.
    Article CAS PubMed Google Scholar
34. Duncan, C., and Deitrich, R. A., A critical evaluation of tetrahydroisoquinoline induced ethanol preference in rats. Pharmac. Biochem. Behav.13 (1980) 265–281.
    Article CAS Google Scholar
35. Fertel, R. H., Greenwald, J. E., Schwarz, R., Wong, L., and Bianchine, J., Opiate receptor binding and analgesic effects of the tetrahydroisoquinolines salsolinol and tetrahydropapaveroline. Res. Commun. chem. Path. Pharmac.27 (1980) 3–16.
    CAS Google Scholar
36. Geller, I., and Purdy, R., Alteration of ethanol preference in rats; effect of β-carbolines, pp. 295–302, in: Alcohol Intoxication and Withdrawall II. Ed. M. M. Gross. Plenum Press, New York 1975.
    Chapter Google Scholar
37. Genazzani, A. R., Nappi, G., Facchinetti, F., Mazzella, G. L., Parini, D., Sinforiani, E., Petraglia, F., and Savoldi, F., Central deficiency of β-endorphin in alcohol addicts. J. clin. Endocr. Metab.55 (1982) 583–586.
    Article CAS PubMed Google Scholar
38. Gianoulakis, C., and Gupta, A., Inbred strains of mice with variable sensitivity to ethanol exhibit differences in the content and processing of β-endorphin. Life Sci.39 (1986) 2315–2325.
    Article CAS PubMed Google Scholar
39. Hamilton, M. G., Blum, K., and Hirst, M., Identification of an isoquinoline alkaloid after chronic exposure to ethanol. Alc. clin. expl. Res.2 (1978) 133–137.
    Article CAS Google Scholar
40. Hannigan, J. J., and Collins, M. A., Tetrahydroisoquinolines and the serotonergic system. Drug Alc. Depend.4 (1979) 235–237.
    Article CAS Google Scholar
41. Hellevuo, K., and Korpi, E. R., Failure of Ro-15-4513 to antagonize ethanol in rat lines selected for differential sensitivity to ethanol and in Wistar rats. Pharmac. Biochem. Behav.30 (1988) 183–188.
    Article CAS Google Scholar
42. Hirst, M., Evans, D. R., and Gowdey, C. W., Salsolinol in urine of social drinkers. Prog. clin. biol. Res.90 (1985) 85–100.
    Google Scholar
43. Hirst, M., Evans, D. R., and Gowdey, C. W., Salsolinol in urine following chocolate consumption by social drinkers. Alc. Drug Res.7 (1987) 493–501.
    CAS Google Scholar
44. Hirst, M., Evans, D. R., Gowdey, C. W., and Adams, A., The influences of ethanol and other factors on the excretion of urinary salsolinol in social drinkers. Pharmac. Biochem. Behav.22 (1985) 993–1000.
    Article CAS Google Scholar
45. Hirst, M., Adams, M. A., Okamoto, S., Gowdey, C. W., Evans, D. R., and LeBarr, J. M., Tetrahydroisoquinolines after ethanol consumption, in: β-Carbolines and Tetrahydroisoquinolines, pp. 81–96. Eds F. Bloom, J. Barchas, M. Sandler and E. Usdin. Alan Liss, New York 1982.
    Google Scholar
46. Ho, A. K. S., and Rossi, N., Suppression of ethanol consumption by MET-enkephalin in rats. J. Pharm. Pharmac.34 (1982) 118–119.
    Article CAS Google Scholar
47. Hoffman, I. S., and Cubeddu, L. X., Presynaptic effects of tetrahydropapaveroline on striatal dopaminergic neurons. J. Pharnac. expl. Ther.220 (1982) 16–22.
    CAS Google Scholar
48. Huttunen, P., and Myers, R. D., Tetrahydro-β-carboline micro-injected into the hippocampus induces an anxiety-like state in the rat. Pharmac. Biochem. Behav.24 (1986) 1733–1738.
    Article CAS Google Scholar
49. Huttunen, P., and Myers, R. D., Anatomical localization in hippocampus of tetrahydro-β-carboline-induced alcohol drinking in the rat. Alcohol_4_ (1987) 181–187.
    Article CAS PubMed Google Scholar
50. Imperato, A., and Di Chiara, G., Preferential stimulation of dopamine release in the nucleus accumbens of freely moving rats by ethanol. J. Pharmac. expl. Ther.239 (1986) 219–228.
    CAS Google Scholar
51. Kiianmaa, K., Andersson, K., and Fuxe, K., On the role of ascending dopamine systems in the control of voluntary ethanol intake and ethanol intoxication. Pharmac. Biochem. Behav.10 (1979) 605–608.
    Article Google Scholar
52. Koda, L. Y., Koob, G. F., Shier, W. T., and Bloom, F. E., Tetrahydropapaveroline induces small granular vesicles in brain dopamine fibres. Nature_276_ (1978) 281–283.
    Article CAS PubMed Google Scholar
53. Korpi, E. R., Sinclair, G. F., and Malminen, O., Dopamine D2 receptor binding in striatal membranes of rat lines selected for differences in alcohol-related behaviours. Pharmac. Toxic.61 (1987) 94–97.
    Article CAS Google Scholar
54. Levy, A. D., and Ellison, G., Amphetamine-induced enhancement of ethanol consumption: Role of central catecholamines. Psychopharmacology_86_ (1985) 233–236.
    Article CAS PubMed Google Scholar
55. Liljequist, S., Changes in the sensitivity of dopamine receptors in the nucleus accumbens and in the striatum induced by chronic ethanol administration. Acta pharmac. tox.43 (1978) 19–28.
    Article CAS Google Scholar
56. Lister, R. G., and Nutt, D. J., Is Ro-15-4513 a specific alcohol antagonist? Trends Neurosci.10 (1987) 223–225.
    Article CAS Google Scholar
57. Lucchi, L., Rius, R. A., Uzumaki, H., Govoni, S., and Trabucchi, M., Chronic ethanol changes opiate receptor function in rat striatum. Brain Res.293 (1984) 368–371.
    Article CAS PubMed Google Scholar
58. Makowski, E., and Ordonez, L. A., Behavioral alterations induced by formaldehyde-derived tetrahydroisoquinolines. Pharmac. Biochem. Behav.14 (1981) 639–643.
    Article CAS Google Scholar
59. Matsubara, K., Akane, A., Maseda, C., Takahashi, S., and Fukui, Y., Salsolinol in the urine of nonalcoholic individuals after long-term moderate drinking. Alc. Drug Res.6 (1986) 281–288.
    CAS Google Scholar
60. Matsubara, K., Fukushima, S., and Fukui, Y., A systematic regional study of brain salsolinol levels during and immediately following chronic ethanol ingestion in rats. Brain Res.413 (1987) 336–343.
    Article CAS PubMed Google Scholar
61. Melchior, C., and Collins, M. A., The route and significance of endogenous synthesis of alkaloids in animals, in: CRC Critical Reviews in Toxicology, pp. 313–356. CRC Press, Boca Rotan, Fl. 1982.
    Google Scholar
62. Melchior, C. L., Mueller, A., and Deitrich, R. A., Half-lives of salsolinol and tetrahydropapaveroline hydrobromide following intracerebroventricular injection. Biochem. Pharmac.29 (1980) 657–658.
    Article Google Scholar
63. Melchior, C. L., and Myers, R. D., Genetic differences in ethanol drinking of the rat following injection of 6-OHDA, 5,6-DHT or 5,8-DHT into the cerebral ventricles. Pharmac. Biochem. Behav.5 (1976) 63–72.
    Article CAS Google Scholar
64. Melchior, C. L., and Myers, R. D., Preference for alcohol evoked by tetrahydropapaveroline (THP) chronically infused in the cerebral ventricle of the rat. Pharmac. Biochem. Behav.7 (1977) 19–35.
    Article CAS Google Scholar
65. Melchior, C. L., and Myers, R. D., Alcohol drinking induced in the rat after chronic injections of tetrahydropapaveroline (THP), salsolinol or noreleagnine in the brain, in: Alcohol and Aldehyde Metabolizing Systems, vol. III, pp. 545–554. Eds R. G. Thurman, J. R. Williamson, B. Chanee,and R. H. Drott. Academic Press, New York 1977.
    Chapter Google Scholar
66. Melchior, C. L., Simpson, C. W., and Myers, R. D., Dopamine release within forebrain sites perfused with tetrahydroisoquinolines or tryptoline in the rat. Brain Res. Bull.3 (1978) 631–634.
    Article CAS PubMed Google Scholar
67. Meller, E., Friedman, E., Schweitzer, J. W., and Friedhoff, A. J., Tetrahydro-β-carbolines: Specific inhibitors of Type A monoamine oxidase in rat brain. J. Neurochem.28 (1977) 995–1000.
    Article CAS PubMed Google Scholar
68. Messiha, F. S., Larson, J. W., and Geller, I., Voluntary ethanol drinking by the rat: Effects of 2-aminoethylisothiouronium salt, a modifier of NAD: NADH and noreleagnine, a β-carboline derivative. Pharmacology_15_ (1977) 400–406.
    Article CAS PubMed Google Scholar
69. Minano, F. J., and Myers, R. D., Inhibition of dopa-decarboxylase in brain by Ro4-4602 on voluntary intake of alcohol induced by cyanamide. Psychopharmacology, (1989) in press.
70. Murphy, J. M., McBride, W. J., Gatto, G. J., Lumeng, L., and Li, T.-K., Effects of acute ethanol administration on monamine and metabolite content in forebrain regions of ethanol-tolerant and-non-tolerant alcohol-preferring (P) rats. Pharmac. Biochem. Behav.29 (1988) 169–174.
    Article CAS Google Scholar
71. Myers, R. D., Psychopharmacology of alcohol. A. Rev. Pharmac. Toxic.18 (1978) 125–144.
    Article CAS Google Scholar
72. Myers, R. D., Pharmacological effects of amine-aldehyde condensation products, in: Alcohol Tolerance and Dependence, pp. 339–370. Eds H. Rigter and J. Crabbe. Elsevier, The Netherlands 1980.
    Google Scholar
73. Myers, R. D., Multiple metabolite theory, alcohol drinking and the alcogene, in: Aldehyde Adducts in Alcoholism, pp. 201–220. Ed. M. A. Collins. Alan Liss, New York 1985.
    Google Scholar
74. Myers, R. D., Alkaloid metabolites and addictive drinking of alcohol. NIAAA Research Monograph 17, pp. 268–284. Eds N. C. Chang and H. M. Chao. 1985.
75. Myers, R. D., and Critcher, E. C., Naloxone alters alcohol drinking induced in the rat by tetrahydropapaveroline (THP) infused ICV. Pharmac. Biochem. Behav.16 (1982) 827–836.
    Article CAS Google Scholar
76. Myers, R. D., and Melchior, C. L., Alcohol drining in the rat after destruction of serotonergic and catecholaminergic neurons in the brain. Res. Commun. chem. Path. Pharm.10 (1975) 363–378.
    CAS PubMed Google Scholar
77. Myers, R. D., and Melchior, C. L., Alcohol drinking: Abnormal intake caused by tetrahydropapaveroline in brain. Science_196_ (1977) 554–556.
    Article CAS PubMed Google Scholar
78. Myers, R. D., and Melchior, C. L., Differential actions on voluntary alcohol intake of tetrahydroisoquinolines or a β-carboline infused chronically in the ventricle of the rat. Pharmac. Biochem. Behav.7 (1977) 381–392.
    Article CAS Google Scholar
79. Myers, R. D., and Oblinger, M., Alcohol drinking in the rat induced by acute intracerebral infusion of two tetrahydroisoquinolines and a β-carboline. Drug Alc. Depend.2 (1977) 469–483.
    Article CAS Google Scholar
80. Myers, R. D., and Privette, T. H., A neuroanatomical substrate for alcohol drinking: Identification of tetrahydropapaveroline (THP)-reactive sites in the rat brain. Brain Res. Bull.22 (1989) in press.
81. Myers, R. D., and Ruwe, W. D., Is alcohol-induced poikilothermia mediated by 5-HT and catecholamine receptors or by ionic set-point mechanism in the brain? Pharmac. Biochem. Behav.16 (1982) 321–327.
    Article CAS Google Scholar
82. Myers, R. D., Borg, S., and Mossberg, R., Antagonism by naltrexone of voluntary alcohol selection in the chronically drinking macaque monkey. Alcohol_3_ (1986) 383–388.
    Article CAS PubMed Google Scholar
83. Myers, R. D., Garrison, J. L., and Critcher, E. C., Degradation characteristics of two tetrahydroisoquinolines at room and body temperature: HPLC determination with electrochemical detection. J. liquid Chromat.6 (1983) 343–352.
    Article CAS Google Scholar
84. Myers, R. D., McCaleb, M. L., and Ruwe, W. D., Alcohol drinking induced in the monkey by tetrahydropapaveroline (THP) infused into the cerebral ventricle. Pharmac. Biochem. Behav.16 (1982) 995–1000.
    Article CAS Google Scholar
85. Myers, R. D., Melchior, C., and Swartzwelder, H. S., Amine-aldehyde metabolites and alcoholism: Fact, myth or uncertainy. Subs. Alc. Actions/Misuse_1_ (1980) 223–238.
    CAS Google Scholar
86. Myers, R. D., Swartzwelder, H. S., and Holahan, W., Effect of hippocampal lesions produced by intracerebroventricular kainic acid on alcohol drinking in the rat. Brain Res. Bull.10 (1983) 333–338.
    Article CAS PubMed Google Scholar
87. Myers, W. D., Ng, K. T., Marzuki, S., Myers, R. D., and Singer, G., Alteration of alcohol drinking in the rat by peripherally self-administered acetaldehyde. Alcohol_1_ (1984) 229–236.
    Article CAS PubMed Google Scholar
88. Myers, W. D., Ng, K. T., Singer, G., Smythe, G. A., and Duncan, M. W., Dopamine and salsolinol levels in rat hypothalami and striatum after schedule-induced self-injection (SISI) of ethanol and acetaldehyde. Brain Res.358 (1985) 122–128.
    Article CAS PubMed Google Scholar
89. Myers, W. D., Mackenzie, L., Ng, K. T., Singer, G., Smythe, G. A., and Duncan, M. W., Salsolinol and dopamine in rat medial basal hypothalamus after chronic ethanol exposure. Life Sci.36 (1985) 309–314.
    Article CAS PubMed Google Scholar
90. Nesterick, C. A., and Rahwan, R. G., Detection of endogenous salsolinol in neonatal rat tissue by a radioenzymatic-thin layer chromatographic assay. J. Chromat.164 (1979) 205–216.
    Article CAS Google Scholar
91. Nimit, Y., Schulze, I., Cashaw, J. L., Ruchirawat, S., and Davis, V. E., Interaction of catecholamine-derived alkaloids with central neurotransmitter receptors. J. Neurosci. Res.10 (1983) 175–189.
    Article CAS PubMed Google Scholar
92. Nimitkitpaisan, Y., and Skolnick, P., Catecholamine receptors and cyclic AMP formation in the central nervous system: effects of tetrahydroisoquinoline derivatives. Life Sci.23 (1978) 373–382.
    Article Google Scholar
93. O'Neill, P. J., and Rahwan, R. G., Absence of formation of brain salsolinol in ethanol-dependent mice. J. Pharmac. expl. Ther.200 (1977) 306–313.
    CAS Google Scholar
94. Origitano, T. C., and Collins, M. A., Confirmation of an unexpected brain O-methylation pattern for the dopamine-derived tetrahydroisoquinoline, salsolinol. Life Sci.26 (1980) 2061–2065.
    Article CAS PubMed Google Scholar
95. Perry, T. L., Jones, K., and Hansen, S., Tetrahydroisoquinoline lacks dopaminergic nigrostriatal neurotoxicity in mice. Neurosci. Lett.85 (1988) 101–104.
    Article CAS PubMed Google Scholar
96. Pfeffer, A. O., and Samson, H. H., Haloperidol and apomorphine effects on ethanol reinforcement in free feeding rats. Pharmac. Biochem. Behav.29 (1988) 343–350.
    Article CAS Google Scholar
97. Peura, P., Mackenzie, P., Koivusaari, U., and Lang, M., Increased fluidity of a model membrane caused by tetrahydro-β-carbolines. Molec. Pharmac.22 (1982) 721–724.
    CAS Google Scholar
98. Peura, P., Airaksinen, M., Tuomisto, L., Saano, V., and Eriksson, C. J. P., L-methyl-tetrahydro-_B_-carboline in human blood after alcohol intake. Proc. Finn. Symp. Biol. Med. Eff. Alc. (1981) 1135.
99. Privette, T. H., and Myers, R. D., Alcohol drinking: Role of neurotransmitter metabolites. Proc. natl Conf. Alc. Res. Raleigh, NC, 1987.
100. Privette, T. H., Hornsby, R. L., and Myers, R. D., Buspirone alters alcohol drinking in rats by tetrahydropapaveroline injected into brain monoamine pathways. Alcohol_5_ (1988) 147–152.
     Article CAS PubMed Google Scholar
101. Purvis, P. L., Hirst, M., and Baskerville, J. C., Voluntary ethanol consumption in the rat following peripheral administrations of 3-carboxysalsolinol. Subs. Alc. Actions/Misuse_1_ (1980) 439–445.
     CAS Google Scholar
102. Rezvani, A. H., Mack, C. M., Crovi, S. I., and Myers, R. D., Central Ca++-channel blockade reverses ethanol-induced poikilothermia in the rat. Alcohol_3_ (1986) 273–279.
     Article CAS PubMed Google Scholar
103. Richardson, J. S., and Novakovski, D. M., Brain monoamines and free choice ethanol consumption in rats. Drug Alc. Depend.3 (1978) 253–264.
     Article CAS Google Scholar
104. Rommelspacher, H., Buchau, C., and Weiss, J., Harman induces preference for ethanol in rats: Is the effect specific for ethanol. Pharmac. Biochem. Behav.26 (1987) 749–755.
     Article CAS Google Scholar
105. Rommelspacher, H., and Schmidt, L., Increased formation of β-carbolines in alcoholic patients following ingestion of ethanol. Pharmacopsychiatry_18_ (1985) 153–154.
     Article Google Scholar
106. Rommelspacher, H., and Subramanian, N., Tetrahydronorharmane modulates the depolarisation-induced efflux of 5-hydroxytryptamine and dopamine and is released by high potassium concentration from rat brain slices. Eur. J. Pharmac.56 (1979) 81–86.
     Article CAS Google Scholar
107. Rommelspacher, H., Damm, H., Strauss, S., and Schmidt, G., Ethanol induces an increase of harmane in the brain and urine of rats. Naunyn-Schmiedebergs Arch. Pharmak.327 (1984) 107–113.
     Article CAS Google Scholar
108. Russell, V. A., Lamm, M. C. L., and Taljaard, J. J. F., Effect of ethanol on [3H]dopamine release in rat nucleus accumbens and striatal slices. Neurochem. Res.13 (1988) 487–492.
     Article CAS PubMed Google Scholar
109. Samson, H. H., Tolliver, G. D., Pfeffer, A. O., Sadeghi, K. G., and Mills, F. G., Oral ethanol reiforcement in the rat: Effect of the partial inverse benzodiazepine agonist Ro15-4513. Pharmac. Biochem. Behav.27 (1987) 517–519.
     Article CAS Google Scholar
110. Sandi, C., Borrell, J., and Guzaz, C., Naloxone decreases ethanol consumption within a free choice paradigm in rats. Pharmac. Biochem. Behav.29 (1988) 39–43.
     Article CAS Google Scholar
111. Sandler, M., Carter, S. B., Hunter, K. R., and Stern, G. M., Tetrahydroisoquinoline alkaloids: in vivo metabolites of L-dopa in man. Nature_241_ (1973) 439–443.
     Article CAS PubMed Google Scholar
112. Sandler, M., Glover, V., Armando, I., and Clow, A., Pictet-spengler condensation products, stress and alcoholism: some clinical overtones. Prog. clin. biol. Res.90 (1982) 215–226.
     CAS PubMed Google Scholar
113. Sasaoka, T., Kaneda, N., Niwa, T., Hashizume, Y., and Nagatsu, T., Analysis of salsolinol in human brain using high-performance liquid chromatography with electrochemical detection. J. Chromat.428 (1988) 152–155.
     Article CAS Google Scholar
114. Schechter, M. D., Ability of 3-carboxysalsolinol to produce ethanol-like discrimination in rats. Psychopharmacology_68_ (1980) 277–281.
     Article CAS PubMed Google Scholar
115. Signs, S. A., and Schechter, M. D., The role of dopamine and serotonin receptors in the mediation of the ethanol interoceptive cue. Pharmac. Biochem. Behav.30 (1988) 55–64.
     Article CAS Google Scholar
116. Sinclair, J. D., and Myers, R. D., Cerebroventricular tetrahydropapaveroline infusions and ethanol consumption in the rat. Subs. Alc. Actions/Misuse_3_ (1982) 5–24.
     CAS Google Scholar
117. Sjöquist, B., Borg, S., and Kvande, H., Catecholamine derived compounds in urine and cerebrospinal fluid from alcoholics during and after long-standing intoxication. Subs. Alc. Actions/Misuse_2_ (1981) 63–72.
     Google Scholar
118. Sjöquist, B., Borg, S., and Kvande, H., Salsolinol and methylated salsolinol in urine and cerebrospinal fluid in healthy volunteers. Subs. Alc. Actions/Misuse_2_ (1981) 73–77.
     Google Scholar
119. Sjöquist, B., Johnson, H. A., and Borg, S., The influence of acute ethanol on the catecholamine system in man as reflected in cerebrospinal fluid and urine. A new condensation product, 1-carboxysalsolinol. Drug Alc. Depend.16 (1985) 241–249.
     Article Google Scholar
120. Sjöquist, B., Liljequist, S., and Engel, J., Increased salsolinol levels in rat striatum and limbic forebrain following chronic ethanol treatment. J. Neurochem.39 (1982) 259–262.
     Article PubMed Google Scholar
121. Sjöquist, B., Perdahl, E., and Winblad, B., The effect of alcoholism on salsolinol and biogenic amines in human brain. Drug. Alc. Depend.12 (1983) 15–23.
     Article Google Scholar
122. Sjöquist, B., Eriksson, A., and Winblad, B., Salsolinol and catecholamines in human brain and their relation to alcoholism, in: β-Carbolines and Tetrahydroisoquinolines, pp. 57–67. Eds F. Bloom, J. Barchas, M. Sandler and E. Usdin. Alan Liss, New York 1982.
     Google Scholar
123. Suzdak, P. D., Paul, S. M., and Crawley, J. N., Effects of Ro15-4513 and other benzodiazepine receptor inverse agonists on alcohol-induced intoxication in the rat. J. Pharmac. expl Ther.245 (1988) 880–886.
     CAS Google Scholar
124. Topel, H., Biochemical basis of alcoholism: Statements and hypotheses of present research. Alcohol_2_ (1985) 711–788.
     Article CAS PubMed Google Scholar
125. Tuomisto, L., Airaksinen, M. M., Peura, P., and Eriksson, C. J. P., Alcohol drinking in the rat: increases following intracerebroventricular treatment with tetrahydro-β-carbolines. Pharmac. Biochem. Behav.17 (1982) 831–836.
     Article CAS Google Scholar
126. Weiner, H., Simpson, C. W., Thurman, J. A., and Myers, R. D., Disulfiram alters dopamine metabolism at sites in rat's forebrain as detected by push-pull perfusions. Brain Res. Bull.3 (1978) 541–548.
     Article CAS PubMed Google Scholar

Download references