Occipitalization of the ventral part and vertebralization of the dorsal part of the atlas with insufficiency of the transverse ligament

1982 ◽  
Vol 24 (1) ◽  
pp. 45-47 ◽  
Author(s):  
A. Wackenheim
Keyword(s):  
Ventral Part ◽  
Dorsal Part ◽  
Transverse Ligament

Morphological and ontogenetic studies in Plams. IV. Ontogeny of the vasuclar pattern in four Genera

1966 ◽  
Vol 14 (3) ◽  
pp. 277 ◽  
Author(s):  
K Periasamy
Keyword(s):  
Temporal Sequence ◽  
Mature Leaf ◽  
Ventral Part ◽  
Dorsal Part ◽  
Basic Pattern ◽  
Line Parallel ◽  
Basal Half ◽  
Two Sides ◽  
Different Parts

The median dorsal strand is the first to differentiate in Cocos, Phoenix, and Caryota. It traverses the terminal abaxial ridge of the plications, to end at the apex of the non-plicate margin of the lamina wing. The series of strands that afterwards differentiate tangentially on either side of it form the first vasculature of the adaxial ridges of the plications, and are termed "primary strands". In Borassus, the median dorsal strand differentiates only after 5-10 pairs of primary strands are differentiated. In Cocos and Borassus, each primary strand traverses one adaxial ridge; hence the primary strands are more or less equal in number to the pinnae in Cocos and the segments in Borassus. In Phoenix, each primary strand executes an almost right-angled, adaxial curve at its tip and branches dichotomously into two to four branches, each traversing a line parallel to an adaxial ridge, in the "haut" formed by the fusion of the adaxial ridges with each other. Therefore the primary strands are characteristically fewer than the pinnae. In addition to the branches that vascularize the haut, the primary strands make connections later with some of the strands of the pinnae that differentiate in the lamina. When the haut is shed, those parts of the branches of the primary strands situated in the haut are lost, leaving the primary strands connected to the laminar strands alone. In Borassus, during dissection of the palmate lamina, those parts of the primary strands situated in the apical halves of the adaxial ridges are constricted, along with the surrounding ridge, and shed. In the basal half of the adaxial ridge, the primary strand makes connections with other neighbouring strands of the lamina. In Caryota, the primary strands are comparatively few, since the primary plications are few. The strands formed adaxial and abaxial to the tangential row of primary strands are irregularly disposed, and are termed the adaxiai and abaxial complexes respectively. These strands vascularize the rest of the lamina, and also the adaxial ridges. The strands of the adaxial complex of Cocos are inversely oriented. The primary strands extend to the thin ventral part of the sheathing base in Cocos, Borassus, and Caryota, but are confined to the thick dorsal part in Phoenix. The oblique courses of the strands on the two sides of the median ventral line of the sheath as mirror images of one another, and their spatial and temporal sequence of differentiation along two different transverse depths, account for their remarkable interlocking as "warps and wefts" along the median ventral line. The primary strands differentiate acropetally. The adaxial and the abaxial strands show acropetal, basipetal, or discontinuous differentiation in different parts of the leaf. Although the basic pattern of vasculature seen in the younger stages does not change, the vasculature of the mature leaf becomes very complex by the formation of numerous additional bundles and branches, and their anastomoses, especially in the sheath and rachis.

scholarly journals Regionalization in the compound eye of Talitrus saltator (Crustacea, Amphipoda)

2019 ◽  
Author(s):  
Alice Ciofini ◽  
Luca Mercatelli ◽  
Yumi Yamahama ◽  
Takahiko Hariyama ◽  
Alberto Ugolini
Keyword(s):  
Compound Eye ◽  
Wavelength Region ◽  
Ventral Part ◽  
Dorsal Part ◽  
Blue Filter ◽  
Talitrus Saltator ◽  
Summary Statement ◽  
Celestial Compass ◽  
Behavioural Experiments ◽  
Retinular Cells

AbstractThe crustacean Talitrus saltator is known to use many celestial cues during its orientation along the sea-land axis of sandy shores. In this paper, we investigated the existence of the eye regionalization by morphological, electrophysiological and behavioural experiments. Each ommatidium possesses five radially arranged retinular cells producing a square fused rhabdom by R1-R4 cells; the smaller R5 exist between R1 and R4. The size of R5 rhabdomere is largest in dorsal part and becomes gradually smaller in median and ventral part of the eye. Spectral-sensitivity measurements were recorded from either dorsal or ventral parts of the compound eye to clarify the chromatic difference. Results show that the dorsal part is green and UV-blue dichromatic, whereas the ventral part is UV (390 nm) with a substantial population of 450 nm receptors with the responses in the longer wavelength region. To evaluate the orienting behaviour of individuals, their eyes were black painted either in the dorsal or ventral part, under natural sky or a blue filter with or without the vision of the sun. Results show that animals painted on the dorsal part of their eyes tested under the screened sun were more dispersed and in certain cases their directions deflected than other groups of individuals. Furthermore, sandhoppers subjected to the obscuring of this area met in any case high difficulties in their directional choices. Therefore, our present work indicates the existence of a regionalization of the compound eye of T. saltator.Summary statementThis work provides evidences of the morphological and electrophysiological regionalization of the compound eye and the visual capabilities for behaviour involved in the recognition of the celestial compass orienting factors in crustaceans.

‘Nemacheilus’ argyrogaster, a new species of loach from southern Laos (Teleostei: Nemacheilidae)

Zootaxa ◽  
2021 ◽  
Vol 4933 (2) ◽  
pp. 277-288
Author(s):  
MAURICE KOTTELAT
Keyword(s):  
New Species ◽  
Southeast Asia ◽  
The Body ◽  
Colour Pattern ◽  
Flowing Water ◽  
Ventral Part ◽  
Dorsal Part ◽  
Posterior Edge ◽  
Lower Lip ◽  
A New Species

‘Nemacheilus’ argyrogaster, new species, is described from the Xe Kong, Mekong drainage, in Attapeu and Xe Kong provinces, southern Laos. It is distinguished from all other Nemacheilidae in Southeast Asia by its unique colour pattern made of a bold black midlateral stripe separating the yellowish brown dorsal part of the body from the silvery whitish ventral part and a middorsal row of 14–19 thin saddles. Besides, the male has a globulous suborbital flap with tubercles along its free, posterior edge, and the pectoral fin with thickened anterior ray and branched rays 1–4 and unculiferous pads behind them covered by small tubercles; lips thin, lower lip continuous with a narrow median notch. It was found in moderate to fast flowing water, over pebble to stone bottom. ‘Nemacheilus’ argyrogaster, was earlier misidentified as N. longistriatus; it is provisionally placed in the genus Nemacheilus. 

scholarly journals Feather loss in laying hens

2006 ◽  
Vol 60 (1-2) ◽  
pp. 107-114
Author(s):  
Slavca Hristov ◽  
Sreten Mitrovic ◽  
Mirjana Todorovic ◽  
Vladan Djermanovic ◽  
Ivica Cvetkovic
Keyword(s):  
Sequence Analysis ◽  
Laying Hens ◽  
The Other ◽  
Ventral Part ◽  
Dorsal Part ◽  
Detailed Consideration ◽  
Video Recordings ◽  
One Year ◽  
The One ◽  
Comparison Of The Results

The paper examined the incidence of different forms of feather loss and cannibalism in laying hens aged 74 weeks following moulting and in laying hens following exploitation for a period of one year. The forms of feather loss were considered in detail through a repeated examination of video recordings and they were sorted according to localization - to feather loss on the ventral part of the neck, on the dorsal part of the neck, and on the back between the wings. Feather loss on the ventral part of the neck was established in 47.9% hens, and in the dorsal part in 16.77% hens of the 167 laying hens aged 74 weeks following moulting. The group of 129 laying hens that were observed following one-year exploitation exhibited considerably more frequent feather loss, in 96.90% hens it was localized on the ventral part of the neck, in 60.47% hens on the dorsal part of the neck, and in 20.16% hens it was localized on the back between the wings. A comparison of the results of the incidence of co localized forms of feather loss in the one and the other group of laying hens using the t-test showed statistically very significant differences. A detailed consideration of the video recordings using the method of sequence analysis did not reveal any cannibalism in either group of laying hens.

Analysis of object motion in the ventral part of the medial superior temporal area of the macaque visual cortex

1993 ◽  
Vol 69 (1) ◽  
pp. 128-142 ◽  
Author(s):  
K. Tanaka ◽  
Y. Sugita ◽  
M. Moriya ◽  
H. Saito
Keyword(s):  
Visual Cortex ◽  
Receptive Fields ◽  
Object Motion ◽  
Ventral Part ◽  
Dorsal Part ◽  
Stationary Object ◽  
Temporal Area ◽  
Small Stimulus ◽  
Medial Superior Temporal ◽  
Stationary Background

1. The medial superior temporal area (MST) is an extrastriate area of the macaque visual cortex. Cells in MST have large receptive fields and respond to moving stimuli with directional selectivity. We previously suggested that the dorsal part of MST is mainly involved in analysis of field motion caused by movements of the animal itself, because most cells in the dorsal part preferentially responded to movements of a wide textured field rather than to movements of a small stimulus. To determine whether the remaining ventral part of MST differs in function from the dorsal part, we examined properties of cells in the ventral part in comparison with those of cells in the dorsal part, using anesthetized and paralyzed preparation. 2. Most cells in the ventral part preferably responded to movements of a small stimulus rather than to movements of a wide textured field. 3. Although the cells in the ventral part did not respond to movements of a textured field over a large window, many of them began to respond when a small stationary object was introduced in front of the moving field. The direction to which the cells responded in this stimulus configuration was opposite to the direction in which they responded to movements of an object on a stationary background. Activities of these cells thus represented the direction of relative movement of an object on a background, irrespective of whether the image of the object or the background moved on the retina. 4. We conclude that the ventral part of MST is distinctive from the dorsal part of MST and is mainly involved in the analysis of object movements in external space.

Controlled locomotion in the mesencephalic cat: distribution of facilitatory and inhibitory regions within pontine tegmentum

1978 ◽  
Vol 41 (6) ◽  
pp. 1580-1591 ◽  
Author(s):  
S. Mori ◽  
H. Nishimura ◽  
C. Kurakami ◽  
T. Yamamura ◽  
M. Aoki
Keyword(s):  
Stimulus Intensity ◽  
General Condition ◽  
Muscle Activity ◽  
Legged Locomotion ◽  
Facilitatory Effect ◽  
Ventral Part ◽  
Dorsal Part ◽  
Mesencephalic Locomotor Region ◽  
Inhibitory Region ◽  
Stimulation Of

1. The contribution of postural tonus to controlled locomotion elicited by the stimulation of mesencephalic locomotor region (MLR) was studied in the acute precolicular-postmammillary decerebrate (mesencephalic) cat. 2. A microelectrode was placed in the unilateral MLR and another was placed systematically at 1-mm increments throughout the pons (H--4 to H--1O) at level ranging from P2 to P11 dorsoventrally and mediolaterally from 0 to L or R6. Depending on the general condition of the animal, stimuli through this second electrode were delivered preceding, succeeding, or simultaneous with the MLR stimulation. 3. Stimulation of the ventral part of the caudal tegmental field (P3 to P9, H--6 to H--8) increased extensor tonus of the hindlimbs, as assessed by recording muscle activity. Concomitant stimulation of this region converted MLR-elicited hindlimb stepping to coordinated four-legged locomotion and also elicited locomotion even when stimulation of the MLR alone failed to elicit locomotion. Stimulation of this ventral tegmental region alone at a larger stimulus intensity elicited spastic locomotor movements associated with a substantial increase in extensor tonus. 4. Stimulation of the lateral tegmented field surrounding the pontine locomotor region (PLR) also facilitated MLR effects, but had a relatively weaker facilitatory effect on postural tonus then stimulation of the ventrocaudal tegmental field. PLR stimulation alone was also ineffective when postural tonus was not well maintained. 5 Stimulation of the dorsal part of caudal tegmental field (P3 to P9, H--4 to H--6) in its midline dramatically decreased extensor tonus of the hindlimbs. MLR-elicited controlled locomotion was completely suppressed during concomitant stimulation of this inhibitory region. 6. These results indicated clearly that the degree of existing postural tonus greatly affects MLR-elicited locomotor movements and that an increase in postural tonus and an activation of the spinal stepping generator are not separate phenomenia.

The Localization of Function in the Root of an insect Segmental Nerve

1963 ◽  
Vol 40 (3) ◽  
pp. 553-562
Author(s):  
ANN FIELDEN
Keyword(s):  
Nerve Root ◽  
Ganglion Cells ◽  
Ventral Part ◽  
Dorsal Part ◽  
Segmental Nerve ◽  
Functional Localization ◽  
Sensory Activity ◽  
Thin Walled ◽  
Ventral Roots

1. The roots of the segmental nerves in nymphs of Anax imperator originate from separate dorsal and ventral tracts in the ganglionic neuropile. 2. Axons forming the dorsal part of the nerve root can sometimes be traced to ganglion cells and tend to be large and thick-walled compared with the ventral axons which are smaller and thin-walled. 3. In the roots of the fifth nerves of the last ganglion the two parts can be separated by dissection. Recording from each part under various conditions of stimulation shows that sensory activity occurs predominantly in the ventral part of the nerve root whilst motor spikes are recorded almost entirely from the dorsal part. 4. It is concluded that there is a functional localization of motor and sensory fibres in the root of an insect nerve comparable to that in the dorsal and ventral roots of vertebrate nerves.

scholarly journals Far Lateral Approach for Resection of Transverse Ligament Cyst

2020 ◽  
Author(s):  
Lattimore Madison Michael ◽  
Vincent Nguyen ◽  
Jaafar Basma ◽  
William Mangham ◽  
Nickalus Khan ◽  
...  
Keyword(s):  
Spinal Cord ◽  
Mass Effect ◽  
Lateral Approach ◽  
Microsurgical Anatomy ◽  
Transverse Ligament ◽  
Far Lateral Approach ◽  
Adequate Understanding ◽  
Far Lateral ◽  
Microsurgical Resection ◽  
Dentate Ligament

Abstract Objectives This study was aimed to describe a far lateral approach for microsurgical resection of a transverse ligament cyst, with emphasis on the microsurgical anatomy and technique. Design A far lateral craniotomy is performed in the lateral decubitus position. After opening the dura laterally, dural sutures are placed for retraction. A stitch placed through the dentate ligament is advantageous to rotate the spinal cord to allow access to the ventral cyst. The cyst is marsupirlized and mass effect on the spinal cord is relieved. Photographs of the region are borrowed from Dr Rhoton's laboratory to illustrate the microsurgical anatomy. Participants The first author performed the surgery and edited the video. Chart review and literature review were performed by the other authors. Outcome Measures Outcome was assessed with postoperative neurological function. Results The patient was discharged home after an uneventful hospital course. At short-term follow-up, the patient had a significant improvement in postoperative strength. Conclusion The far lateral approach provides an adequate corridor to the ventrolateral brainstem in combination with utilization of the dentate ligament to reach ventral cysts compressing the spinal cord. An adequate understanding of the relevant microsurgical anatomy is a key to safe surgery in this region.The link to the video can be found at: https://youtu.be/5MGVPO2Q2pI.

Sign in / Sign up

Export Citation Format

Share Document