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lowed by severe paralysis of the hand, but the use and power of the hand is gained in a few weeks; ablations, on the other hand, of even large portions of e posterior central gyrus do not give rise even to transient paralysis.
In some of the animals experimented on, the motor area was found to extend the deeper part of the posterior wall of the central sulcus of Rolando. Anteriorly extended into the pre-central sulci as well as into the occasional sulci which cross e anterior central gyrus; indeed the hidden part of the motor area fully equals in
0. External occipital protuberance (inion).
M. Mid-point between G and O.
T. Mid-point between M and O.
S. Mid-point between T and O.
FIG. 1067.-CRANIO-CEREBRAL TOPOGRAPHY.
Shows relations of the motor and sensory areas to the gyri, and to Chiene's lines.
Mid-point of AB.
is drawn parallel to AM.
VW. Guide to anterior limit of transverse sinus.
E. Zygomatic process of frontal.
P. Root of zygoma (pre-auricular point).
R. Mid-point of PS.
Site at which subarachnoid space may be opened.
extent that contributing to the free surface of the hemisphere. The motor areas extend a little in front of the superior and inferior pre-central sulci, which cannot therefore be regarded as physiological boundaries.
Reference to Fig. 1068 shows that, of the main areas, that for the lower extremity occupies the upper third of the motor region, that for the upper extremity the middle third, while the face occupies the inferior third. The relative topography of the chief subdivisions of these main areas is shown in Fig. 1069. It must be remembered, however, that there exists much overlapping of the adjacent areas.
The body of the lateral ventricle, which is equal in length to the posterior
tissue but includes many elastic and muscle fibres. From its deep surface, more especially at the hilum, strong trabeculæ pass into the organ to support the blood-vessels and nerves.
The arteries enter eres have a lymphoi he larger arteries res rends symmetricall Many of the white specks, but, b Twards their termi
thelial cells; 224s with the The pulp i Development 2t, in a 9-mm celomic epit
of the thickeR
a single layer. Th
the the intra-splen rentiate.
es between them
The pulp is a spongework of fine fibres covered, at places entirely concealed, by branched connective-tissue corpuscles, reticulum cells. Associated with these, occupying some of the
FIG. 1064.-SECTION THROUGH GLOMUS COCCYGEUM (highly magnified).
From J. W. Thomson Walker.
smaller spaces of the spongework, are cells like very large leucocytes, spleen phagocytes. These are amoeboid and often contain the debris of red blood corpuscles.
the pulp. The
rasformation is und
(ii) GLOMU The glomus call body, 2-2: aced immediate the coccyx, up dle sacral ar companied by xodies of similar Hation.
a fibrous capsu polyhedral cells considerable bl astomosing chan a vein.
Development the capillar the tip of the capillary wal stead of forming The position c et that its bloo ety-valve on t 4 as vet, been maphil cells
The arteries enter at the hilum, run in the trabeculæ, and branch freely. The smaller teries have a lymphoid sheath developed in their walls. This replaces the fibrous sheath which e larger arteries receive from the trabecula. Every here and there the lymphoid sheath pands symmetrically or asymmetrically to form a lymphatic nodule (nodulus lymphaticus nalis). Many of the nodules thus formed are quite small; others are visible to the naked eye white specks, but, however large or small they may be, each contains a network of capillaries. >wards their termination the arteries lose their sheaths and become reduced to simple tubes of dothelial cells; gaps appear in their walls and finally the cells forming them become connuous with the reticulum cells of the pulp. The veins begin in the same way as the arteries d. The pulp is, therefore, the modified capillary system of the spleen. Development. The spleen is mesodermal in origin. The first indication of its developent, in a 9-mm. embryo, is a thickening of the dorsal mesogastrium. In 10-12 mm. embryos le cœlomic epithelium over the splenic rudiment is several layers thick. Soon the deeper yers of the thickening are transformed into mesenchyme and the epithelium is reduced again a single layer. The first vascularisation of the spleen is effected by a capillary network. Out f this the intra-splenic arteries and veins ifferentiate. The undifferentiated capilaries between them form capillary tufts r spherules. These become transformed nto the pulp. The exact method of this ransformation is undetermined, but during ts progress great numbers of red blood ells are produced. The lymphatic nodules are developed in the later part of fœtal life, and with their contained lymphocytes differentiate from the tunica adventitia of the arteries.
Structure. The glomus is enclosed in a fibrous capsule and consists of round or polyhedral cells with large nuclei lining a considerable blood space, which is an anastomosing channel between an artery and a vein.
(ii.) GLOMUS COCCYGEUM.
The glomus coccygeum is a small body, 2-2.5 mm. in diameter, placed immediately anterior to the tip of the coccyx, upon a branch of the middle sacral artery. Usually it is Entrance of artery accompanied by a group of smaller bodies of similar structure and arterial relation.
into main glomus
FIG. 1065.-SCHEMA OF THE RELATION PRESENTED BY THE
Development.-The glomus develops from the capillary network of the region of the tip of the embryonic tail. At first the capillary walls differentiate as if to form an artery, then the cells of the middle coat, instead of forming muscle, assume an epithelioid character.
The position of the glomus coccygeum at the posterior end of the axis of the body, and the fact that its blood-spaces form a wide arterio-venous anastomosis, suggest that it is a sort of safety-valve on the peripheral circulation. No evidence that it produces an internal secretion has, as yet, been obtained, and in spite of frequent statements to the contrary it contains no chromaphil cells (Stoerk).
BY HAROLD J. STILES, F.R.C.S.
THE HEAD AND NECK.
Scalp. The first and third layers of the scalp, namely, the skin and the epicranius muscle, are firmly united by fibrous processes which pass from the one to the other through the second or subcutaneous fatty layer. Intervening between these three layers and the pericranium is a loose cellular layer which supports the small vessels passing between the scalp proper and pericranium. The thin pericranium, although regarded anatomically as periosteum, possesses very limited bone-forming properties; over the vertex it is readily separated from the skull-cap, except along the lines of the sutures, where it gives off intersutural processes to join the endosteal layer of the dura.
The free blood-supply of the scalp is for the purpose of nourishing its abundant hair follicles and glands. The main vessels lie in the dense subcutaneous tissue, and are superficial, therefore, to the epicranius (Fig. 1066). The arteries supplying the frontal region are derived from the internal carotid, while those for the remainder of the scalp spring from the external carotid. These two sets of vessels anastomose freely with one another, and freely also across the median plane; hence the failure of ligature of the external carotid to cure cirsoid aneurysm of the temporal artery.
Wounds of the scalp bleed freely, and the vessels are difficult to ligature on account of the adhesion of their walls to the dense subcutaneous tissue. In extensive flap wounds and in diffuse suppuration beneath the epicranius there is little danger of sloughing of the scalp. Abscesses and hæmorrhages superficial to the epicranius are usually limited on account of the density of the subcutaneous tissue. Hæmorrhage beneath the epicranius is seldom extensive on account of the small size of the vessels, but suppuration in this situation may rapidly undermine the whole muscle and its aponeurosis-the galea aponeurotica; incisions to evacuate the pus should be made early, and parallel to the main vessels of the scalp. Extravasation of blood beneath the pericranium leads to a hæmatoma which is limited by the sutures.
The veins of the scalp communicate with the intra-cranial venous sinuses(1) directly through their anastomoses with the large emissary veins, namely, the parietal, which opens into the superior sagittal sinus, and the mastoid and condyloid, which open into the transverse sinus; (2) through the anastomoses of the frontal and supra-orbital veins with the ophthalmic vein, which opens into the cavernous sinus; (3) through the veins of the diplöe, which connect the veins of the scalp and the pericranium on the one hand with those of the dura mater and the venous sinuses on the other; (4) through small veins which pass from the pericranium through the bones and the intersutural membranes to the dura. It is along these various channels that pyogenic infection may extend, from the scalp and pericranium, through the bone to the dura mater and venous sinuses, and from the latter to the cerebral veins, the pia-arachnoid, and the substance of the brain. More rarely the infection spreads from the cranial cavity along the emissary veins to the scalp.
The lymph vessels of the anterior part of the scalp join the external maxillary lymph vessels; those of the temporal and parietal regions open into the pre-auricular and parotid lymph glands, situated in front of and below the ear, and into the post-auricular or mastoid glands, situated upon the insertion of the sterno-mastoid muscle. The lymph vessels of the occipital region open into the occipital glands, which lie close to the occipital artery where it becomes superficial in the scalp.