Papers associated with head region (and th)

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	Temporal and spatial transcriptomic dynamics across brain development in Xenopus laevis tadpoles., Ta AC., G3 (Bethesda). January 4, 2022; 12 (1):
	Comparative analysis of monoaminergic cerebrospinal fluid-contacting cells in Osteichthyes (bony vertebrates)., Xavier AL., J Comp Neurol. June 15, 2017; 525 (9): 2265-2283.
	Gene expression analysis of developing cell groups in the pretectal region of Xenopus laevis., Morona R., J Comp Neurol. March 1, 2017; 525 (4): 715-752.
	Deep-brain photoreception links luminance detection to motor output in Xenopus frog tadpoles., Currie SP., Proc Natl Acad Sci U S A. May 24, 2016; 113 (21): 6053-8.
	ACT-PRESTO: Rapid and consistent tissue clearing and labeling method for 3-dimensional (3D) imaging., Lee E., Sci Rep. January 11, 2016; 6 18631.
	Spatiotemporal Development of the Orexinergic (Hypocretinergic) System in the Central Nervous System of Xenopus laevis., López JM., Brain Behav Evol. January 1, 2016; 88 (2): 127-146.
	Ascl1 phospho-status regulates neuronal differentiation in a Xenopus developmental model of neuroblastoma., Wylie LA., Dis Model Mech. May 1, 2015; 8 (5): 429-41.
	Dopamine: a parallel pathway for the modulation of spinal locomotor networks., Sharples SA., Front Neural Circuits. June 16, 2014; 8 55.
	Ascl1 as a novel player in the Ptf1a transcriptional network for GABAergic cell specification in the retina., Mazurier N., PLoS One. March 18, 2014; 9 (3): e92113.
	Wiring the retinal circuits activated by light during early development., Bertolesi GE., Neural Dev. February 13, 2014; 9 3.
	Angiogenesis in the intermediate lobe of the pituitary gland alters its structure and function., Tanaka S., Gen Comp Endocrinol. May 1, 2013; 185 10-8.
	Pax3 and Zic1 drive induction and differentiation of multipotent, migratory, and functional neural crest in Xenopus embryos., Milet C., Proc Natl Acad Sci U S A. April 2, 2013; 110 (14): 5528-33.
	Pattern of calbindin-D28k and calretinin immunoreactivity in the brain of Xenopus laevis during embryonic and larval development., Morona R., J Comp Neurol. January 1, 2013; 521 (1): 79-108.
	Contexts for dopamine specification by calcium spike activity in the CNS., Velázquez-Ulloa NA., J Neurosci. January 5, 2011; 31 (1): 78-88.
	Immunohistochemical localization of DARPP-32 in the brain and spinal cord of anuran amphibians and its relation with the catecholaminergic system., López JM., J Chem Neuroanat. December 1, 2010; 40 (4): 325-38.
	Sonic hedgehog expression during Xenopus laevis forebrain development., Domínguez L., Dev Biol. August 6, 2010; 1347 19-32.
	Identification of the gene encoding alkylglycerol monooxygenase defines a third class of tetrahydrobiopterin-dependent enzymes., Watschinger K., Proc Natl Acad Sci U S A. August 3, 2010; 107 (31): 13672-7.
	Generation of functional eyes from pluripotent cells., Viczian AS., PLoS Biol. August 1, 2009; 7 (8): e1000174.
	Spatio-temporal expression of Pax6 in Xenopus forebrain., Moreno N., Brain Res. November 6, 2008; 1239 92-9.
	Timing the generation of distinct retinal cells by homeobox proteins., Decembrini S., PLoS Biol. September 1, 2006; 4 (9): e272.
	Colocalization of nitric oxide synthase and monoamines in neurons of the amphibian brain., López JM., Brain Res Bull. September 15, 2005; 66 (4-6): 555-9.
	Localization of Mel1b melatonin receptor-like immunoreactivity in ocular tissues of Xenopus laevis., Wiechmann AF., Exp Eye Res. October 1, 2004; 79 (4): 585-94.
	Differential distribution of Mel(1a) and Mel(1c) melatonin receptors in Xenopus laevis retina., Wiechmann AF., Exp Eye Res. January 1, 2003; 76 (1): 99-106.
	Basal ganglia organization in amphibians: chemoarchitecture., Marín O., J Comp Neurol. March 16, 1998; 392 (3): 285-312.
	Brain-derived neurotrophic factor/neurotrophin-4 receptor TrkB is localized on ganglion cells and dopaminergic amacrine cells in the vertebrate retina., Cellerino A., J Comp Neurol. September 15, 1997; 386 (1): 149-60.
	Effects of localized application of retinoic acid on Xenopus laevis development., Drysdale TA., Dev Biol. April 1, 1994; 162 (2): 394-401.
	A nonrandom interneuronal pattern in the developing frog spinal cord., Heathcote RD., J Comp Neurol. February 15, 1993; 328 (3): 437-48.
	Distribution of tyrosine hydroxylase and dopamine immunoreactivities in the brain of the South African clawed frog Xenopus laevis., González A., Anat Embryol (Berl). February 1, 1993; 187 (2): 193-201.
	Does lineage determine the dopamine phenotype in the tadpole hypothalamus?: A quantitative analysis., Huang S., J Neurosci. April 1, 1992; 12 (4): 1351-62.
	Phosphorylation of human recombinant tyrosine hydroxylase isoforms 1 and 2: an additional phosphorylated residue in isoform 2, generated through alternative splicing., Le Bourdellès B., J Biol Chem. September 15, 1991; 266 (26): 17124-30.
	Development of the Xenopus laevis hatching gland and its relationship to surface ectoderm patterning., Drysdale TA., Development. February 1, 1991; 111 (2): 469-78.
	GABA and tyrosine hydroxylase immunocytochemistry reveal different patterns of colocalization in retinal neurons of various vertebrates., Wulle I., J Comp Neurol. June 1, 1990; 296 (1): 173-8.

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