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Copy, alter and control : the déjà entendus of disc jockey cultureShiga, John Patrick January 2002 (has links)
Since the 1970s, the practice of deejaying has been integrated into music-making and musical performance in hip hop, dance music, and other cultures. Disc jockeys have also become recognized as producers and authors of sound recordings. I examine how changes in the technological, legal and commercial environment of disc jockeys in the 1990s are articulated in the styles and methods of deejaying. I argue that the conspicuous and covert styles of sampling articulate different forms of authorship, economic interests, and notions of originality. While the covert style has been crucial to the emergence of the DJ-as-author and deejaying as a legitimate art, the conspicuous style of copying on the edges of DJ culture troubles the tenuous links between the new DJ-stars and their works.
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Copy, alter and control : the déjà entendus of disc jockey cultureShiga, John Patrick January 2002 (has links)
No description available.
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The role of the geometry of the human lumbar facet joints in disc degenerationDuncan, Neil 04 1900 (has links)
No description available.
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Progressive Disc Herniation: An investigation of the mechanism using histochemical and microscopic techniquesTampier, Claudio January 2006 (has links)
Abstract Background: The process that involves the migration of the nucleus pulposus from the innermost annular layers and culminates with the final extrusion of the nucleus has been limited to a few studies. This investigation was directed towards a better understanding of the herniation process. The architecture of the annulus fibrosus and the mechanism of progressive disc herniation were analyzed, using a controlled porcine model. Microscopic and histochemical techniques were employed. <br /><br /> Methodology: Two studies were performed. In the first stage, the macroscopic and microscopic structures of twelve cervical intervertebral discs were compared with young human disc data from studies reported in the literature. Important structural features were studied such as annulus fibrosus thickness, number of lamellae, lamellae thickness, orientation of the lamellae fibers and blood supply. In the second study, sixteen fresh-frozen functional spine units were submitted to repetitive flexion?extension motions combined with a low compressive load in a servo-hydraulic dynamic testing system. Discograms, dissections and histochemical techniques were applied to characterize the cumulative damage. The experiment produced eight complete herniations, four partial herniations and four specimens without any microscopic detectable annular damage. <br /><br /> Results and Discussion: The structure of the cervical porcine disc resembles the lumbar human disc. Some differences are evident. The size of the annulus is smaller, the thickness of the lamellae is narrower and the number of layers is fewer in the pig. It is hypothesized that the flexion-extension motion combined with a low-level load produced an increased hydraulic pressure in the inner wall of the posterior annulus. This pressure and repetitive motion first produced a small cleft, spreading the collagen bundles inside the first layer. The nuclear material was "pumped" through the small cleft to the first layer filling the layer creating a fluid-filled pocket between the collagen fibers. Once the "pocket" acquired enough pressure a new cleft was produced in the weakest part of the layer allowing the nuclear material to create a new "pocket" in the second layer. This was the first stage of damage and disc herniation production. This mechanism was repeated until the nucleus traveled along the annulus reaching the posterior longitudinal ligament. At this point a complete extrusion herniation was produced. <br /><br /> Conclusion: The porcine model appears to be suitable as a model to understand the mechanism of disc herniation when the spine is subjected to flexion-extension motions combined with a low-level load. The first cumulative injury appears to be a cleft between the lamellae bundles produced by the nuclear hydraulic pressure. A cumulative load/cumulative injury model approach was used to create the damage that was quantified in the study.
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Progressive Disc Herniation: An investigation of the mechanism using histochemical and microscopic techniquesTampier, Claudio January 2006 (has links)
Abstract Background: The process that involves the migration of the nucleus pulposus from the innermost annular layers and culminates with the final extrusion of the nucleus has been limited to a few studies. This investigation was directed towards a better understanding of the herniation process. The architecture of the annulus fibrosus and the mechanism of progressive disc herniation were analyzed, using a controlled porcine model. Microscopic and histochemical techniques were employed. <br /><br /> Methodology: Two studies were performed. In the first stage, the macroscopic and microscopic structures of twelve cervical intervertebral discs were compared with young human disc data from studies reported in the literature. Important structural features were studied such as annulus fibrosus thickness, number of lamellae, lamellae thickness, orientation of the lamellae fibers and blood supply. In the second study, sixteen fresh-frozen functional spine units were submitted to repetitive flexion?extension motions combined with a low compressive load in a servo-hydraulic dynamic testing system. Discograms, dissections and histochemical techniques were applied to characterize the cumulative damage. The experiment produced eight complete herniations, four partial herniations and four specimens without any microscopic detectable annular damage. <br /><br /> Results and Discussion: The structure of the cervical porcine disc resembles the lumbar human disc. Some differences are evident. The size of the annulus is smaller, the thickness of the lamellae is narrower and the number of layers is fewer in the pig. It is hypothesized that the flexion-extension motion combined with a low-level load produced an increased hydraulic pressure in the inner wall of the posterior annulus. This pressure and repetitive motion first produced a small cleft, spreading the collagen bundles inside the first layer. The nuclear material was "pumped" through the small cleft to the first layer filling the layer creating a fluid-filled pocket between the collagen fibers. Once the "pocket" acquired enough pressure a new cleft was produced in the weakest part of the layer allowing the nuclear material to create a new "pocket" in the second layer. This was the first stage of damage and disc herniation production. This mechanism was repeated until the nucleus traveled along the annulus reaching the posterior longitudinal ligament. At this point a complete extrusion herniation was produced. <br /><br /> Conclusion: The porcine model appears to be suitable as a model to understand the mechanism of disc herniation when the spine is subjected to flexion-extension motions combined with a low-level load. The first cumulative injury appears to be a cleft between the lamellae bundles produced by the nuclear hydraulic pressure. A cumulative load/cumulative injury model approach was used to create the damage that was quantified in the study.
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Interspecies conservation of retinal guanosine 5' triphosphataseMcMurray, Melissa Meats January 2011 (has links)
Typescript (photocopy). / Digitized by Kansas Correctional Industries
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Isocirculational mechanics in stellar systemsCollett, James Leonard January 1995 (has links)
No description available.
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Cell metabolism and viability in the intervertebral discBibby, Susan R. S. January 2002 (has links)
No description available.
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A dynamic pre-clinical testing protocol for intervertebral disc replacement devicesHolsgrove, Timothy Patrick January 2012 (has links)
Back pain is a common complaint and the origin of this frequently attributed to degenerative disc disease. In the most severe cases, the integrity of the disc and surrounding tissue is lost to such an extent that surgical intervention is necessary. Fusion procedures are commonly used to treat severely degenerated discs. Yet this is known to alter the biomechanics of the operated level, and may create a progression of degenerative decline. Total disc replacement has emerged as a viable treatment but the complexity of the spine is reflected in the clinical results, which trail far behind the success of hip and knee arthroplasty. This may be due to a failure of total disc replacement procedures to restore the natural biomechanics of the spine. The present study has led to the development of a dynamic pre-clinical testing protocol to quantitatively assess the efficacy of disc replacement devices. A six-axis spine simulator was designed and built, and the stiffness matrix testing of porcine lumbar specimens was completed, both with and without an axial preload. Intact specimens were tested, and the testing repeated after a total disc replacement procedure with a DePuy In Motion artificial disc. This is the first study to complete dynamic six-axis spinal testing of this kind. The testing demonstrated the disc replacement device compared favourably with the intact porcine disc both in shear and axial stiffness. However, the low-friction, double ball and socket design of the In Motion device lacks stiffness in the three rotational axes, and it is unstable in lateral bending. Rotations are the primary movements in the spine, and it is crucial if the natural biomechanics are to be restored, that a disc replacement device should replicate the stiffnesses of these axes. The next generation of disc replacement devices feature elastomeric materials that may more closely replicate the natural intervertebral disc. From patents registered with DePuy, this may also be true of the next generation of In Motion disc. This research provides a means to complete standardised performance tests of new spinal devices and lays the foundations for future comparison studies. Additionally, the spine simulator and testing protocol would provide valuable data during the design stage of new total disc replacements, aiding the development of the next generation of artificial discs.
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IN VITRO AND IN VIVO BIOMECHANICAL INVESTIGATION OF THE CLINICAL PRACTICE OF DISC PROLAPSE PREVENTION AND REHABILITATIONScannell, Joan January 2007 (has links)
Underlying this thesis is the McKenzie school of thought, a physiotherapy approach that teaches clinicians to recommend particular exercises to their clients in an attempt to accelerate recovery/ prevent recurrence of disc prolapse. The recommendations are based on an untested clinical theory that movements opposite to those that cause disc prolapse can achieve reversal of disc prolapse. Little consideration has been given scientifically to the reversal of the failure process of the lumbar discs. Three in vitro and one in vivo study were designed to attain a greater understanding of both disc failure and the mechanics of its clinical treatment responses and thereby provide a foundation for evidence-based practice.
The first in vitro study in this thesis compared in vitro and in vivo herniated discs in an attempt to link the two and provide a more thorough understanding of the in vitro model proposed to test the mechanical theory underlying the McKenzie derangement approach. Ten C3/4 osteoligamentus porcine specimens were repeatedly flexed or flexed and side bent to result in posterior migration of the nucleus. Three of the 10 specimens had posterior migration of the nucleus. Statistically significant (p < 0.01) and clinically significant (>33%) disc height loss occurred in all 10 specimens. The results provide a sub-classification of in vitro herniated discs that is similar to the spectrum of herniated discs that occurs in vivo.
Continuing from the disc height loss sub-classification of post-herniated in vitro discs, the second in vitro study in this thesis pursues alternate methods of creating herniation with the goal of creating herniation without causing more than thirty three percent disc height loss of the specimens. Repeated flexion of porcine cervical specimens under a lower compression level (1kN) resulted in disc herniation but with loss of 50% of the pre-test disc height (p < 0.001). Re-hydrating specimens by injecting the disc after a period of failure testing with a barium sulphate nucleus mix (n = 5) or by placing the specimen in a saline bath for an extended period of time (n = 4) resulted in a significant increase of the disc height of the specimens. Further flexion testing of the specimens significantly reduced the disc height again. Intermittent saline injection of specimens (n = 3) during the failure procedure did not prevent or reduce the disc height loss that occurred in the absence of saline injections. Using higher compression levels (2 and 2.596kN, n = 4), failure testing under torque control (n = 3), non-physiologically starting the annular rupture (n = 5) and using hypolordotic thoracic porcine spines (n = 9) instead of porcine cervical spines were unsuccessful attempts at creating herniations. This study indicated that the in vitro model used in the first in vitro study displayed features from one end of the spectrum of damage seen clinically but was then the best-available. Combined these two studies provide a framework for interpretation of the results of the subsequent and third in vitro study in this thesis.
The focus of the third study is the mechanical investigation of the McKenzie clinical theory of the treatment response seen in vivo in prolapsed discs, which is that movements or positioning can alter the location of a displaced portion of nucleus in a prolapsed disc. This study is a proof of the principle on which this aspect of the McKenzie approach is based and provides, to the author’s knowledge, the first scientific evidence supporting the theory that repeating movements opposite to those that caused posterior migration of the nucleus can centralize the prolapsed material. The results indicate that the McKenzie approach works on some prolapsed discs and not on others. Consideration of the changes in disc height of the specimens during the testing procedures offers some understanding of the varied success of this approach and exposes a vast area of future research that will refine the clinical approach and mechanical understanding of this specific disc pathology.
The fourth study, an in vivo study, provides a first look at the kinematics and kinetics of the current in vivo application of this approach. Twenty asymptomatic subjects volunteered to participate in this study and performed frequently prescribed McKenzie exercises and a selection of activities of daily living during which a 3-SPACE Isotrak system measured their three dimensional lumbar kinemetics. One subject underwent a series of McKenzie exercises while electromyography and three-dimensional lumbar motion were measured. Mean peak extension of extension in standing and extension in lying exercises were within 3% (SD 22.33%) of each other. An additional 6.75% (SD 11.18%) of extension occurred when the extension in lying exercise was combined with a Grade 3 Maitland extension mobilization to L3, a passive physiotherapy technique that involves the therapist applying intermittent low amplitude oscillations to, in this case, the posterior aspect of the spinous process with the goal of subsequently increasing the range of active motion in the direction of the mobilization. The peak extension during the extension in lying exercise was increased after the mobilization relative to the pre-mobilization range. The mean peak right side bend in the right side glide exercise, normalized to the full right side bend range, was 61% (SD 17.4%). The L4-5 forces at the position of peak extension in extension in lying and extension in standing were 828.97N and 1368.86N respectively. The peak flexion ranges of the activities of daily living investigated match those previously used to create disc prolapse when applied at high repetitions and under moderate axial compression. The lumbar spine ranges achieved in commonly prescribed McKenzie rehabilitative and preventative exercises and those that occur in seemingly non-problematic activities of daily living were quantified. The results of this study will enhance clinical practice by providing quantitative evidence of the relative peak motion of the McKenzie exercises as well as highlighting seemingly benign activities of daily living that involve levels of flexion, side bend and rotation sufficient to cause disc damage and even prolapse.
The macroscopic goal of this thesis was to attain a greater understanding of the mechanics of both disc failure and its clinical treatment responses and thereby provide a foundation for evidence-based practice, a goal that was successfully achieved. This thesis ultimately challenged and increased our understanding of pathological discs while simultaneously adding information to assist clinical decision making. Several new contributions to the existing knowledge of lumbar spine biomechanics and clinical concepts of treating disc prolapse have been made.
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