The evolution of man : a popular exposition of the principal points of human ontogeny & phylogeny /

Bound in green publisher's cloth with gilt-stamped spine, blind-stamped boards, and yellow coated endpapers.

A textbook of anatomy for nurses,

Mode of access: Internet.

A laboratory manual in anatomy and physiology,

Mode of access: Internet.

Text-book of anatomy and physiology for nurses,

Mode of access: Internet.

Anatomy : a manual for students and practitioners /

Includes index.

Anatomy and physiology; a text-book for nurses,

Mode of access: Internet.

Landmarks and surface markings of the human body ... with thirty-one illustrations.

Some of the plates accompanied by leaves with descriptive letterpress.

The anatomy of the peritonaeum /

Outlines of the embryological development of the abdominal viscera.

General anatomy, applied to physiology and medicine;

Mode of access: Internet.

Special anatomy and histology.

First edition, 1826; first five editions issued under title: A treatise on special and general anatomy.

A text-book of pathological anatomy and pathogenesis /

"Press of Stettiner, Lambert & Co., 129 & 131 Crosby St., New York."; vol. 2, pt. 2.

Text-book of anatomy and physiology for nurses,

Mode of access: Internet.

A text-book of clinical anatomy for students and practitioners,

Mode of access: Internet.

Human brain regions required for the dividing and switching of attention between two features of a single object

This combined PET and ERP study was designed to identify the brain regions activated in switching and divided attention between different features of a single object using matched sensory stimuli and motor response. The ERP data have previously been reported in this journal [64]. We now present the corresponding PET data. We identified partially overlapping neural networks with paradigms requiring the switching or dividing of attention between the elements of complex visual stimuli. Regions of activation were found in the prefrontal and temporal cortices and cerebellum. Each task resulted in different prefrontal cortical regions of activation lending support to the functional subspecialisation of the prefrontal and temporal cortices being based on the cognitive operations required rather than the stimuli themselves. (C) 2003 Elsevier Science B.V. All rights reserved.

Imaging, anatomical, and molecular analysis of callosal formation in the developing human fetal brain

A complex set of axonal guidance mechanisms are utilized by axons to locate and innervate their targets. In the developing mouse forebrain, we previously described several midline glial populations as well as various guidance molecules that regulate the formation of the corpus callosum. Since agenesis of the corpus callosum is associated with over 50 different human congenital syndromes, we wanted to investigate whether these same mechanisms also operate during human callosal development. Here we analyze midline glial and commissural development in human fetal brains ranging from 13 to 20 weeks of gestation using both diffusion tensor magnetic resonance imaging and immunohistochemistry. Through our combined radiological and histological studies, we demonstrate the morphological development of multiple forebrain commissures/decussations, including the corpus callosum, anterior commissure, hippocampal commissure, and the optic chiasm. Histological analyses demonstrated that all the midline glial populations previously described in mouse, as well as structures analogous to the subcallosal sling and cingulate pioneering axons, that mediate callosal axon guidance in mouse, are also present during human brain development. Finally, by Northern blot analysis, we have identified that molecules involved in mouse callosal development, including Slit, Robo, Netrin1, DCC, Nfia, Emx1, and GAP-43, are all expressed in human fetal brain. These data suggest that similar mechanisms and molecules required for midline commissure formation operate during both mouse and human brain development. Thus, the mouse is an excellent model system for studying normal and pathological commissural formation in human brain development. (c) 2006 Wiley-Liss, Inc.