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	The ultrastructure of gliosomes in the brains of amphibia., Srebro Z., J Cell Biol. August 1, 1965; 26 (2): 313-22.
	The distribution of non-synaptic intercellular junctions during neurone differentiation in the developing spinal cord of the clawed toad., Hayes BP., J Embryol Exp Morphol. April 1, 1975; 33 (2): 403-17.
	The central pathways of optic fibres in Xenopus tadpoles., Steedman JG., J Embryol Exp Morphol. April 1, 1979; 50 199-215.
	The relationship between retinal and tectal growth in larval Xenopus: implications for the development of the retino-tectal projection., Gaze RM., J Embryol Exp Morphol. October 1, 1979; 53 103-43.
	An autoradiographic study of the retinal projection in Xenopus laevis with comparisons to Rana., Levine RL., J Comp Neurol. January 1, 1980; 189 (1): 1-29.
	Pineal complex of the clawed toad, Xenopus laevis Daud.: structure and function., Korf HW., Cell Tissue Res. January 1, 1981; 216 (1): 113-30.
	The central projections of lateral line and cutaneous sensory fibres (VII and X) in Xenopus laevis., Lowe DA., Proc R Soc Lond B Biol Sci. October 22, 1982; 216 (1204): 279-97.
	The relation between soma position and fibre trajectory of neurons in the mesencephalic trigeminal nucleus of Xenopus laevis., Lowe DA., Proc R Soc Lond B Biol Sci. June 22, 1984; 221 (1225): 437-54.
	Projection patterns of lateral-line afferents in anurans: a comparative HRP study., Fritzsch B., J Comp Neurol. November 1, 1984; 229 (3): 451-69.
	Factors guiding regenerating retinotectal fibres in the frog Xenopus laevis., Fawcett JW., J Embryol Exp Morphol. December 1, 1985; 90 233-50.
	Map formation in the developing Xenopus retinotectal system: an examination of ganglion cell terminal arborizations., Sakaguchi DS., J Neurosci. December 1, 1985; 5 (12): 3228-45.
	Visual deprivation and the maturation of the retinotectal projection in Xenopus laevis., Keating MJ., J Embryol Exp Morphol. February 1, 1986; 91 101-15.
	Mauthner neurons survive metamorphosis in anurans: a comparative HRP study on the cytoarchitecture of Mauthner neurons in amphibians., Will U., J Comp Neurol. February 1, 1986; 244 (1): 111-20.
	Double labeling of neural circuits using horseradish peroxidase and cobalt., Ebbesson SO., J Neurosci Methods. May 1, 1987; 20 (1): 1-5.
	Immunocytochemical analysis of proenkephalin-derived peptides in the amphibian hypothalamus and optic tectum., Merchenthaler I., Dev Biol. July 28, 1987; 416 (2): 219-27.
	Light microscopy of GTP-binding protein (Go) immunoreactivity within the retina of different vertebrates., Terashima T., Dev Biol. December 15, 1987; 436 (2): 384-9.
	The ultrastructural organization of the isthmic nucleus in Xenopus., McCart R., Anat Embryol (Berl). January 1, 1988; 177 (4): 325-30.
	An aberrant retinal pathway and visual centers in Xenopus tadpoles share a common cell surface molecule, A5 antigen., Fujisawa H., Dev Biol. October 1, 1989; 135 (2): 231-40.
	The development of the Xenopus retinofugal pathway: optic fibers join a pre-existing tract., Easter SS., Development. November 1, 1989; 107 (3): 553-73.
	Dorsomedial telencephalon of lungfishes: a pallial or subpallial structure? Criteria based on histology, connectivity, and histochemistry., von Bartheld CS., J Comp Neurol. April 1, 1990; 294 (1): 14-29.
	Organization of hindbrain segments in the zebrafish embryo., Trevarrow B., Neuron. May 1, 1990; 4 (5): 669-79.
	Development of the amphibian oculomotor complex: evidences for migration of oculomotor motoneurons across the midline., Naujoks-Manteuffel C., Anat Embryol (Berl). January 1, 1991; 183 (6): 545-52.
	Distribution of galanin-like immunoreactivity in the brain of Rana esculenta and Xenopus laevis., Lázár GY., J Comp Neurol. August 1, 1991; 310 (1): 45-67.
	Optic synapses are found in diencephalic neuropils before development of the tectum in Xenopus., Gaze RM., Anat Embryol (Berl). January 1, 1993; 187 (1): 27-35.
	Expression of thrombospondin in the adult nervous system., Hoffman JR., J Comp Neurol. February 1, 1994; 340 (1): 126-39.
	Spinothalamic projections in amphibians as revealed with anterograde tracing techniques., Muñoz A., Neurosci Lett. April 25, 1994; 171 (1-2): 81-4.
	The contralaterally projecting neurons of the isthmic nucleus in five anuran species: a retrograde tracing study with HRP and cobalt., Tóth P., J Comp Neurol. August 8, 1994; 346 (2): 306-20.
	Differential perturbations in the morphogenesis of anterior structures induced by overexpression of truncated XB- and N-cadherins in Xenopus embryos., Dufour S., J Cell Biol. October 1, 1994; 127 (2): 521-35.
	Immunochemical localization of calcium/calmodulin-dependent protein kinase I., Picciotto MR., Synapse. May 1, 1995; 20 (1): 75-84.
	The cellular patterns of BDNF and trkB expression suggest multiple roles for BDNF during Xenopus visual system development., Cohen-Cory S., Dev Biol. October 10, 1996; 179 (1): 102-15.
	Essential role of heparan sulfates in axon navigation and targeting in the developing visual system., Walz A., Development. June 1, 1997; 124 (12): 2421-30.
	Basal ganglia organization in amphibians: chemoarchitecture., Marín O., J Comp Neurol. March 16, 1998; 392 (3): 285-312.
	Distribution of synaptic vesicle proteins within single retinotectal axons of Xenopus tadpoles., Pinches EM., J Neurobiol. June 15, 1998; 35 (4): 426-34.
	Nitric oxide in the retinotectal system: a signal but not a retrograde messenger during map refinement and segregation., Rentería RC., J Neurosci. August 15, 1999; 19 (16): 7066-76.
	Patterns of calretinin, calbindin, and tyrosine-hydroxylase expression are consistent with the prosomeric map of the frog diencephalon., Milán FJ., J Comp Neurol. March 27, 2000; 419 (1): 96-121.
	Neuronal nicotinic acetylcholine receptors from Drosophila: two different types of alpha subunits coassemble within the same receptor complex., Schulz R., J Neurochem. June 1, 2000; 74 (6): 2537-46.
	Nitric oxide modulates retinal ganglion cell axon arbor remodeling in vivo., Cogen J., J Neurobiol. November 5, 2000; 45 (2): 120-33.
	Developmental regulation of CPG15 expression in Xenopus., Nedivi E., J Comp Neurol. July 9, 2001; 435 (4): 464-73.
	Nitric oxide is an essential negative regulator of cell proliferation in Xenopus brain., Peunova N., J Neurosci. November 15, 2001; 21 (22): 8809-18.
	GABA and development of the Xenopus optic projection., Ferguson SC., J Neurobiol. June 15, 2002; 51 (4): 272-84.
	Metalloproteases and guidance of retinal axons in the developing visual system., Webber CA., J Neurosci. September 15, 2002; 22 (18): 8091-100.
	Expression of voltage-dependent potassium channels in the developing visual system of Xenopus laevis., Pollock NS., J Comp Neurol. October 28, 2002; 452 (4): 381-91.
	Chondroitin sulfate disrupts axon pathfinding in the optic tract and alters growth cone dynamics., Walz A., J Neurobiol. November 15, 2002; 53 (3): 330-42.
	Tyrosine hydroxylase-immunoreactive interneurons in the olfactory bulb of the frogs Rana pipiens and Xenopus laevis., Boyd JD., J Comp Neurol. December 2, 2002; 454 (1): 42-57.
	Normal chiasmatic routing of uncrossed projections from the ventrotemporal retina in albino Xenopus frogs., Grant S., J Comp Neurol. April 14, 2003; 458 (4): 425-39.
	N- and C-terminal domains of beta-catenin, respectively, are required to initiate and shape axon arbors of retinal ganglion cells in vivo., Elul TM., J Neurosci. July 23, 2003; 23 (16): 6567-75.
	Organization of glomeruli in the main olfactory bulb of Xenopus laevis tadpoles., Nezlin LP., J Comp Neurol. September 22, 2003; 464 (3): 257-68.
	Human neuronal stargazin-like proteins, gamma2, gamma3 and gamma4; an investigation of their specific localization in human brain and their influence on CaV2.1 voltage-dependent calcium channels expressed in Xenopus oocytes., Moss FJ., BMC Neurosci. September 23, 2003; 4 23.
	Water transport in the brain: role of cotransporters., MacAulay N., Neuroscience. January 1, 2004; 129 (4): 1031-44.
	Connexin 43 expression in glial cells of developing rhombomeres of Xenopus laevis., Katbamna B., Int J Dev Neurosci. February 1, 2004; 22 (1): 47-55.

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