The Human Central Nervous System: A Synopsis and AtlasThe present edition of The Human Central Nervous System differs considerably from its predecessors. In previous editions, the text was essentially confined to a section dealing with the various functional systems of the brain. This section, which has been rewritten and updated, is now preceded by 15 newly written chapters, which introduce the pictorial material of the gross anatomy, the blood vessels and meninges and the microstructure of its various parts and deal with the development, topography and functional anatomy of the spinal cord, the brain stem and the cerebellum, the diencephalon and the telencephalon. Great pains have been taken to cover the most recent concepts and data. As suggested by the front cover, there is a focus on the evolutionary development of the human brain. Throughout the text numerous correlations with neuropathology and clinical n- rology have been made. After much thought, we decided to replace the full Latin terminology, cherished in all previous editions, with English and Anglicized Latin terms. It has been an emotional farewell from beautiful terms such as decussatio hipposideriformis W- nekinkii and pontes grisei caudatolenticulares. Not only the text, but also the p- torial material has been extended and brought into harmony with the present state of knowledge. More than 230 new illustrations have been added and many others have been revised. The number of macroscopical sections through the brain has been extended considerably. Together, these illustrations now comprise a complete and convenient atlas for interpreting neuroimaging studies. |
From inside the book
Results 1-5 of 73
Page 7
... rostrally and caudally [137]. The temporary openings at either end of the closing neural tube are known as the rostral and caudal neuropores (Fig. 2.1D). The rostral neuropore closes &30 days after fertilization; the caudal neuropore ...
... rostrally and caudally [137]. The temporary openings at either end of the closing neural tube are known as the rostral and caudal neuropores (Fig. 2.1D). The rostral neuropore closes &30 days after fertilization; the caudal neuropore ...
Page 9
... rostral part of the neural plate becomes wider than the caudal part. The former gives rise to the brain whereas the spinal cord develops from the latter. 2. Prior to closure of the anterior neuropore, the rostral part of the primordial ...
... rostral part of the neural plate becomes wider than the caudal part. The former gives rise to the brain whereas the spinal cord develops from the latter. 2. Prior to closure of the anterior neuropore, the rostral part of the primordial ...
Page 11
... rostral neuropore 11 neuromeres were counted. These observations have been largely confirmed by O'Rahilly and Müller [143]. In the folds of the completely open neural groove of a 26-day embryo they distinguished six primary neuromeres ...
... rostral neuropore 11 neuromeres were counted. These observations have been largely confirmed by O'Rahilly and Müller [143]. In the folds of the completely open neural groove of a 26-day embryo they distinguished six primary neuromeres ...
Page 18
... rostral part of the rhombic lip. The rhombic lip is a thickened germinal zone in the rhombencephalic alar plate, situated directly adjacent to the attachment of the roof of the fourth ventricle (Fig. 2.9). From the rostral segment of ...
... rostral part of the rhombic lip. The rhombic lip is a thickened germinal zone in the rhombencephalic alar plate, situated directly adjacent to the attachment of the roof of the fourth ventricle (Fig. 2.9). From the rostral segment of ...
Page 25
... Rostral hypothalamic area rm Magnocellular red nucleus rp Parvocellular red nucleus RP Roof plate sc Superior colliculus sch Suprachiasmatic nucleus sep Septum sm Stria medullaris sn Substantia nigra sol Solitary nucleus spc Spinal cord ...
... Rostral hypothalamic area rm Magnocellular red nucleus rp Parvocellular red nucleus RP Roof plate sc Superior colliculus sch Suprachiasmatic nucleus sep Septum sm Stria medullaris sn Substantia nigra sol Solitary nucleus spc Spinal cord ...
Contents
2 | |
67 | |
4 | 95 |
Brain Slices 137 | 136 |
Neocortex 491 | 174 |
Structure of Spinal Cord and Brain Parts | 175 |
Introduction and Epithalamus 247 | 246 |
Hypothalamus | 289 |
Basal Ganglia | 427 |
Functional Systems | 680 |
Vestibular System | 715 |
Auditory System | 733 |
Visual System | 751 |
Cerebellum | 807 |
Motor Systems | 841 |
Reticular Formation and the Monoaminergic | 888 |
Introduction and Olfactory System | 337 |
Hippocampus and Related Structures | 361 |
Amygdala and Claustrum | 401 |
Greater Limbic System | 917 |
Subject Index | 947 |
Other editions - View all
The Human Central Nervous System: A Synopsis and Atlas R. Nieuwenhuys,Jan Voogd,C. van Huijzen No preview available - 2012 |
The Human Central Nervous System: A Synopsis and Atlas Rudolf Nieuwenhuys,Jan Voogd,Christiaan van Huijzen No preview available - 2016 |
The Human Central Nervous System: A Synopsis and Atlas Rudolf Nieuwenhuys,Jan Voogd,Christiaan van Huijzen No preview available - 2007 |
Common terms and phrases
activity afferents amygdala amygdaloid anterior artery ascending association axons basal behaviour body Brain Res brain stem branches bundle caudal cells centres cerebellar cerebral cortex cingulate circuit collaterals column commissure Comp Neurol complex connections contains cortex cortical dendrites descending direct dorsal efferent elements entorhinal evidence extends fibres field forebrain formation frontal functional grey gyrus hemisphere hippocampal horn human hypothalamic inferior input internal interneurons involved known lamina lateral layer limbic lobe located macaque medial midbrain monkey motor neocortex nerve neurons Neurosci nucleus olfactory organization origin parietal pass pathways peduncle posterior prefrontal primary primate principal processing projections pyramidal cells receives region reticular rhesus monkey rostral sensory shown specific spinal cord stria striatum structures substantia sulcus superior surface synaptic tegmental temporal terminate thalamic thalamic nucleus tion tract types various vein ventral ventricle visual zone
Popular passages
Page 657 - Posterior parietal cortex in rhesus monkey: II. Evidence for segregated corticocortical networks linking sensory and limbic areas with the frontal lobe.
Page 275 - Retrograde axonal transport and the demonstration of non-specific projections to the cerebral cortex and striatum from thalamic intralaminar nuclei in the rat, cat and monkey. J. comp. Neurol.
Page 660 - Foote, SL, Aston-Jones, G, and Bloom. FE, 1980, Impulse activity of locus coeruleus neurons in awake rats and monkeys is a function of sensory stimulation and arousal, Proc.
Page 751 - WB (1978) The olivocochlear bundle: its origins and terminations in the cat. In: Naunton RF, Fernandez C (eds) Evoked electrical activity in the auditory nervous system. Academic Press, New York, pp 43-63 110.
Page 328 - Sexually dimorphic regions in the medial preoptic area and the bed nucleus of the stria terminalis of the guinea pig brain: A description and an investigation of their relationship to gonadal steroids in adulthood - Hines M., Davis FC, Coquelin A.
Page 665 - Burton H (1976) Areal differences in the laminar distribution of thalamic afferents in cortical fields of the insular, parietal and temporal regions of primates.
Page 278 - C (1992) Efferent connections of the centromedian and parafascicular thalamic nuclei in the squirrel monkey: a PHA-L study of subcortical projections. J Comp Neurol 315:137-159 125.
Page 332 - E. (2000): A mutation in a case of early onset narcolepsy and a generalized absence of hypocretin peptides in human narcoleptic brains. Nat. Med.
Page 426 - Bunney BS (1989) Topographical organization of the efferent projections of the medial prefrontal cortex in the rat: an anterograde tract-tracing study with Phaseolus vulgaris leucoagglutinin. J Comp Neurol 290:213-242.
Page 751 - Warr, WB (1975). Olivocochlear and vestibular efferent neurons of the feline brain stem: Their location, morphology, and number determined by retrograde axonal transport and acetylcholinesterase histochemistry. J. Comp. Neurol.