1Tsuji S (1963) Das Action potential of the isolated bulbus cordis of the frog heart. natural sciences 50: 575.

2Tsuji S (1964) Intracellular pacemaker potentials of the bulbus cordis of the Frog's heart. natural sciences 51: 141.

3Couteaux R, Taxi J (1952) Histochemical research on distribution desactivités cholinestérasiques at the level of the myoneural synapse. Arch Anat Micr 41: 352-392.

4Benda P, Tsuji S, Daussant J, Changeux JP (1970) Localization of acetylcholinesterase by immunofluorescence in eel electroplax. Nature 225: 1149-1150.

5Bourgeois JP, Tsuji S, Boquet P, Pillot J, Ryter A and Changeux JP (1971) Localization of the cholinergic receptor protein by immunofluorescence in eel electroplax. FEBS Letters16: 92-94.

6Tsuji S, Rieger F, Peltre G, Massoulie J, Benda P (1972) Acetylcholinesterase of the Muscle, Spinal Cord and Gymnote Brain. Demonstration of "native" molecular species and histochemical localization. J Neurochem 19 : 989-997.

7Tauc L, Hoffmann A, Tsuji S, Hinzen DH, Faille L (1974) Transmission abolished on a cholinergic synapse after injection of acetylcholinesterase into the presynaptic neurone. Nature 250, 496-498.

8Cade-Treyer D, Tsuji S (1975) In vitro culture of the proximal tubule of the bovine nephron. Cell Tiss Res163: 15-28.

9Tsuji S (1981) Attempted direct visualization of negatively stained amplified immune complex of synaptic acetylcholinesterase using cryo ultramicrotomy sections. Histochemistry 72: 369-375.

10Anglade P, Tsuji S (1997) The hundredth anniversary of the "synapse": I. A short history of the milestones in synapse research. Zool Sci14: 533-537.

11Koelle GB, Friedenwald JS (1949) A histochemical method for localizing cholinesterase activity. Proc Soc Exp Biol Med 70: 617-622.

12Karnovsky MJ, Roots L (1964) A "direct-coloring" thiocholine method for cholinesterases. J Histochem Cytochem12: 219-221.

13McMahan UJ, Sanes, JR, Marshall LM (1978) Cholinesterase is associated with the basal lamina at the neuromuscular junction. Nature271: 172-174.

14Tsuji S (1974) On the chemical basis of thiocholine methods for demonstration of acetylcholinesterase activities. Histochemistry 42: 99-110.

15Tsuji S, Anglade P (1997) The hundredth anniversary of the « synapse »: II. Study of the cholinergic synapse. Zool Sci14: 539-548.

16Changeux J-P (1990) The TiPs Lecture. The nicotinic acetylcholine receptor: an allosteric protein prototye of ligand-gated ion channels. Trends Pharmacol Sci11:485-492.

17Tsuji S, Tooyama I, Kato T, Peltre G, Kimura H (2003) Binding avidity of immunoglobulin G for acetylcholine. Biomed Res 24: 217-221.

18Souchay P, Tsuji S (1970) Contribution to the study of the reaction of copper salts thiocholine used in the histochemical detection of cholinesterases. Ann Histochim15:263-271.

19Tsuji S, Larabi Y (1983) A modification of the thiocholine-ferricyanide method of Karnovsky and Roots for localization of acetylcholinesterase activity without interference by Koelle's copper thiocholine iodide precipitate. Histochemistry 78:317-323.

20Tago H, Kimura H, Maeda T (1986) Visualization of detailed acetylcholinesterase fiber and neuron staining in rat brain by a sensitive histochemical procedure. J Histochem Cytochem34: 1431-1438.

21Tsuji S (1998) Electron microscopic localization of acetylcholinesterase activity in the central nervous system: the chemical basis of catalytic activity of Hatchett's brown (cupric ferrocyanide)precipitate revealed by 3,3'-diaminobenzidine.Folia Histochem Cytobiol 36:67-70.

22Stoward PJ, Pearse AGE (1991) Histochemistry Theoretical and Applied, Vol 3, Enzyme histochemistry, 4th ed., Churchill and Livingstone, Edinburgh.

23Lehrer GM, Ornstein L (1959) A diazo coupling method for the electron microscopic localization of cholinesterase. J Bioph Biochem Cytol6: 399-406.

24Tsuji S, Tobin-Gros C (1980) A simple silver nitrate impregnation of nerve fibers with preservation of acetylcholinesterase activity at the motor end-plate. Experientia 36: 1317-1319.

25Anglade P, Michel C, Ozaki T, Tsuji S, Vignon X, et al. (1988) Simultaneous localization of acetylcholinesterase activity and met-enkephalin,, vasoactive intestinal peptide and substance P immuno reactivity in the rat my enteric plexus. Histochem J 20: 464-467.

26Balasubramanian AS, Bhanumathy CD (1993) Noncholinergic functions of Cholinesterases. FASEB J7: 1354-1358.

27Bigbee JW, Sharma KV, Gupta JJ, Dupree JL (1999) A morphogenic role for acetylcholinesterase in axonal outgrowth during neural development. Environ. Health Persp. Suppl.-1 107: 81-87.

28Zhang XJ, Yang L, Zhao Q, Caen JP, He HY, et al. (2002) Induction of acetylcholinesterase expression during apoptosis in various cell types. Cell death diff9: 790-800.

29Anglade P, Grassi J, Motelica-Heino I, Hashikawa T, Tsuji S (1999) Ultrastructural evidence for dendritic release of acetylcholinesterase in the rat substantia nigra. Folia Histochem Cytobiol37: 243-247.

30Ishii K, Hayashida T, Hashikawa T, Tsuji S (2004) Dendritic spinules in rat nigral neurons revealed by acetylcholinesterase immunocytochemistry and serial sections of the dendritic spine heads. Folia Histochem Cytobiol 42: 77-81.

31Castro A, Martinez A (2006) Targeting beta-amyloid pathogenesis through acetylcholinesterase inhibitors. Curr Pharma Des12: 4377-4387.

32Lane RM, Kivipelto M, Greig NH (2004) Acetylcholinesterase and its inhibition in Alzheimer disease. Clin Neuro Pharmacol 27: 141-149.

33Silman I, Sussman JL (2005) Acetylcholinesterase: "classical" and "non-classical" functions and pharmacology. Curr Opin Pharmacol 5: 293-302

34Tsuji S, Nakatomi R, Tsuchiya H, Hirai K, Katayama Y, et al. (2002) Perineuronal surface acetylcholinesterase activity of a fine neural network stained histochemically and observed with backscattered electron imaging and X-ray mapping methods. Brain Res Protocols9: 16-22.

35Tsuji S, Alameddine HS (1981) Silicotungstic acid for cytochemical localization of water-soluble substance(s) of the cholinergic motor nerve terminal. Histochemistry73: 33-37.

36Tsuji S, Alameddine HS, Nakanishi S, Ohoka T (1983) Molybdic and Tungstic heteropolyanions for "ionic fixation" of acetylcholine in cholinergic nerve terminals. Histochemistry77: 51-56.

37Tsuji S, Motelica-Heino I (1993) Further studies on electron microscopic localization of acetylcholine-like cations in frog neuromuscular junctions. Acta Histochem Cytochem26: 577-582.

38Couteaux R, Pécot-Dechavassine M (1970) Synaptic vesicles and pouches level of "active areas" of the neuromuscular junction. C R Acad Sci Paris271 (Series D): 2346-2349.

39Couteaux R, Pécot-Dechavassine M (1974) Specialized areas presynaptic membranes. C R Acad Sci Paris278 (Series D) : 291-293.

40Tsuji S (1985) Ultracytochemical localization of acetylcholine-like cations in excited motor end-plates by means of ionic fixation. Histochemistry 83: 213-219.

41Ohoka T, Tsuji S (1988) The specificity of ionic fixation with silicotungstic acid for cytochemical localization and identification of acetylcholine in synaptic vesicles. Biomed Res 9: 335-341.

42Anglade P, Tsuji S, Javoy-Agid F, Agid Y, Hirsch EC (1995) Plasticity of nerve afferents to nigrostriatal neurons in Parkinson's disease. Ann Neurol 37: 265-272.

43Tsuji S, Motelica-Heino I, Brisorgueil M-J, Anglade P and Araneda S (1992) A Combined method of immunocytochemistry of choline-acetyltransferase detection and of autoradiography of [3H] choline after retrograde axonal transport. Proc Japan Acad 68: 145-149.

44Tsuji S, Motelica-Heino I, Anglade P (1997) The capture of [3H] choline by fibrocytes of frog motor endplate region. Proc Japan Acad 73: 158-160.

45Hirai K, Katayama Y, Peltre G, Tsuji S (2008) Ultrastructural visualization of the transmembranous and cytomatrix-related part of nicotinic acetylcholine receptor of frog motor endplate by means of an immunochemical avidity of IgG for d-tubocurarine. Folia Histochem Cytobiol 46: 111-116.

46Tsuji S (1993) Obituary – Professor Syomatu Yokoyama. Founder of modern electrophysiology of the enteric nervous system. Acta Med Biol 41: 167-169.

47Tsuji S, Yokoyama S (1982) Peristaltic reflex in the small intestine deprived of the mucosa. Jpn J Smooth Muscle Res18: 218-220.

48Tsuji S, Anglade P, Ozaki S, Sazi T, Yokoyama S (1992) Peristaltic movement evoked in an intestinal tube devoid of mucosa and submucosa. Jpn J Physiol 42: 363-375.

49Fujita T, Kobayashi S (1979) Current views on the para neurone concept. Trends Neurosci 2: 27-30.

50Fujita T, Kanno T, Yanaihara N, Miyoshi A (1983) Brain-gut axis. Biomed Res Found Tokyo.

51Mentre P (1996) The water in the cell. A heterogeneous and dynamic interface of macromolecules. Masson, Paris. (Translated in Japanese under the title « Saibo no naka no mizu » by Tsuji S, Nakanishi S, Ochiai M, Ohoka T (2006),University of Tokyo Press).

52Tanaka E, Ishii K, Akagi T, Hirai K, Motelica-Heino I, et al.(2004) A new cytochemical method for ultrastructural localization of Co2+ in rat hippocampal CA1 pyramidal neurons in vitro. J Neuro sci Method135:1-8.

53Hirai K, Tanaka E, Motelica-Heino I, Katayama Y, Higashi H et al. (2006) A new cytochemical method for in situ detection of cholinergic synaptic transmission by staining of Cu2+ incorporated in frog neuromuscular junction during nerve stimulation. Biomed Res 27: 125-130.

54Anglade P, Larabi-Godinot Y, Tsuji S (2014) Electron transfers and holographic molecules: why neuroscientists should take quantum phenomena into consideration. NeuroQuantology 12: 237-246.

55Anglade P, Larabi-Godinot Y (2015) Do receptor proteins store holographic data in the brain? NeuroQuantology 13: 104- 107.

56Anglade P, Larabi-Godinot Y (2018) Holographic processes involved in rhodopsin-mediated phototaxis? Neuroquantology 16: 172-174.

57Tsuji S (2006) René Couteaux (1909-1999) and the morphological identification of synapes. Bio Cell 98: 503-509.

58Tsuji S (2007) Morphological identification of the synapse in light microscopy and ultrastructural observation of presynaptic active zone by René Couteaux. In Symposium on the French neuroanatomy: from Louis Ranvier to René Couteaux, REHSEIS, Paris.