Your search keyword '"Ronayne, S"' showing total 11 results

1. 295 Don’t forget about memory: prevalence of cognitive impairment in older adults attending the integrated day hospital

Author

Ronayne, S, primary, Alexander, M, additional, and O'Malley, T, additional

Published

2023

2. Visual evoked potentials determine chronic signal quality in a stent-electrode endovascular neural interface

Author

Gerboni, G, primary, John, S E, additional, Rind, G S, additional, Ronayne, S M, additional, May, C N, additional, Oxley, T J, additional, Grayden, D B, additional, Opie, N L, additional, and Wong, Y T, additional

Published

2018

3. Cortical Brain Stimulation with Endovascular Electrodes

Author

Gerboni, G., primary, John, S. E., additional, Ronayne, S. M., additional, Rind, G. S., additional, May, C. N., additional, Oxley, T. J., additional, Grayden, D. B., additional, Opie, N. L., additional, and Wong, Y. T., additional

Published

2018

4. Development and Implementation of a Corriedale Ovine Brain Atlas for Use in Atlas-Based Segmentation

Author

Hu, D, Liyanage, KA, Steward, C, Moffat, BA, Opie, NL, Rind, GS, John, SE, Ronayne, S, May, CN, O'Brien, TJ, Milne, ME, Oxley, TJ, Hu, D, Liyanage, KA, Steward, C, Moffat, BA, Opie, NL, Rind, GS, John, SE, Ronayne, S, May, CN, O'Brien, TJ, Milne, ME, and Oxley, TJ

Abstract

Segmentation is the process of partitioning an image into subdivisions and can be applied to medical images to isolate anatomical or pathological areas for further analysis. This process can be done manually or automated by the use of image processing computer packages. Atlas-based segmentation automates this process by the use of a pre-labelled template and a registration algorithm. We developed an ovine brain atlas that can be used as a model for neurological conditions such as Parkinson's disease and focal epilepsy. 17 female Corriedale ovine brains were imaged in-vivo in a 1.5T (low-resolution) MRI scanner. 13 of the low-resolution images were combined using a template construction algorithm to form a low-resolution template. The template was labelled to form an atlas and tested by comparing manual with atlas-based segmentations against the remaining four low-resolution images. The comparisons were in the form of similarity metrics used in previous segmentation research. Dice Similarity Coefficients were utilised to determine the degree of overlap between eight independent, manual and atlas-based segmentations, with values ranging from 0 (no overlap) to 1 (complete overlap). For 7 of these 8 segmented areas, we achieved a Dice Similarity Coefficient of 0.5-0.8. The amygdala was difficult to segment due to its variable location and similar intensity to surrounding tissues resulting in Dice Coefficients of 0.0-0.2. We developed a low resolution ovine brain atlas with eight clinically relevant areas labelled. This brain atlas performed comparably to prior human atlases described in the literature and to intra-observer error providing an atlas that can be used to guide further research using ovine brains as a model and is hosted online for public access.

Published

2016

5. Editorial

Author

Ronayne S

Subjects

Nursing, General Medicine, Nurse patient, Psychology, General Nursing, Hospital care

Published

2001

6. Nurse-patient partnerships in hospital care.

Author

Ronayne S

Published

2001

7. 3D-Printed PEEK/Silicon Nitride Scaffolds with a Triply Periodic Minimal Surface Structure for Spinal Fusion Implants.

Author

Du X, Ronayne S, Lee SS, Hendry J, Hoxworth D, Bock R, and Ferguson SJ

Subjects

Materials Testing, Polyethylene Glycols chemistry, Ketones chemistry, Printing, Three-Dimensional, Osteogenesis, Spinal Fusion

Abstract

The issue of spine-related disorders is a global healthcare concern that requires effective solutions to restore normal spine functioning. Spinal fusion implants have become a standard approach for this purpose, making it crucial to develop biomaterials and structures that possess high osteogenic capacities and exhibit mechanical properties and dynamic responses similar to those of the host bone. This study focused on the fabrication of 3D-printed polyether ether ketone/silicon nitride (PEEK/SiN) scaffolds with a triply periodic minimal surface (TPMS) structure, which offers several advantages, such as a large surface area and uniform stress distribution under load. The mechanical properties and dynamic response of PEEK/SiN scaffolds with varying porosities were evaluated through mechanical testing and finite element analysis. The scaffold with 30% porosity exhibited a compressive strength (34.56 ± 1.91 MPa) and elastic modulus (734 ± 64 MPa) similar to those of trabecular bone. In addition, the scaffold demonstrated favorable damping properties. The biological data revealed that incorporating silicon nitride into the PEEK scaffold stimulated osteogenic differentiation. In light of these findings, it can be inferred that PEEK/SiN TPMS scaffolds exhibit significant potential for use in bone tissue engineering and represent a promising option as candidates for spinal fusion implants.

Published

2023

8. Cortical Brain Stimulation with Endovascular Electrodes.

Author

Gerboni G, John SE, Ronayne SM, Rind GS, May CN, Oxley TJ, Grayden DB, Opie NL, and Wong YT

Subjects

Electric Stimulation, Electrodes, Photic Stimulation, Stereotaxic Techniques, Brain

Abstract

Electrical stimulation of neural tissue and recording of neural activity are the bases of emerging prostheses and treatments for spinal cord injury, stroke, sensory deficits, and drug-resistant neurological disorders. Safety and efficacy are key aspects for the clinical acceptance of therapeutic neural stimulators. The cortical vasculature has been shown to be a safe site for implantation of electrodes for chronically recording neural activity, requiring no craniotomy to access high-bandwidth, intracranial EEG. This work presents the first characterization of endovascular cortical stimulation measured using cortical subdural surface recordings. Visual stimulation was used to verify electrode viability and cortical activation was compared with electrically evoked activity. Due to direct activation of the neural tissue, the latency of responses to electrical stimulation was shorter than for that of visual stimulation. We also found that the center of neural activation was different for visual and electrical stimulation indicating an ability of the stentrode to provide localized activation of neural tissue.

Published

2018

9. An ovine model of cerebral catheter venography for implantation of an endovascular neural interface.

Author

Oxley TJ, Opie NL, Rind GS, Liyanage K, John SE, Ronayne S, McDonald AJ, Dornom A, Lovell TJH, Mitchell PJ, Bennett I, Bauquier S, Warne LN, Steward C, Grayden DB, Desmond P, Davis SM, O'Brien TJ, and May CN

Subjects

Animals, Cranial Sinuses diagnostic imaging, Craniotomy methods, Electrodes, Implanted, Female, Magnetic Resonance Imaging, Male, Models, Biological, Motor Cortex diagnostic imaging, Motor Cortex surgery, Stents, Brain-Computer Interfaces, Catheterization methods, Cerebral Veins diagnostic imaging, Cerebral Veins surgery, Endovascular Procedures methods, Neural Prostheses, Phlebography methods, Prosthesis Implantation methods, Sheep

Abstract

OBJECTIVE Neural interface technology may enable the development of novel therapies to treat neurological conditions, including motor prostheses for spinal cord injury. Intracranial neural interfaces currently require a craniotomy to achieve implantation and may result in chronic tissue inflammation. Novel approaches are required that achieve less invasive implantation methods while maintaining high spatial resolution. An endovascular stent electrode array avoids direct brain trauma and is able to record electrocorticography in local cortical tissue from within the venous vasculature. The motor area in sheep runs in a parasagittal plane immediately adjacent to the superior sagittal sinus (SSS). The authors aimed to develop a sheep model of cerebral venography that would enable validation of an endovascular neural interface. METHODS Cerebral catheter venography was performed in 39 consecutive sheep. Contrast-enhanced MRI of the brain was performed on 13 animals. Multiple telescoping coaxial catheter systems were assessed to determine the largest wide-bore delivery catheter that could be delivered into the anterior SSS. Measurements of SSS diameter and distance from the motor area were taken. The location of the motor area was determined in relation to lateral and superior projections of digital subtraction venography images and confirmed on MRI. RESULTS The venous pathway from the common jugular vein (7.4 mm) to the anterior SSS (1.2 mm) was technically challenging to selectively catheterize. The SSS coursed immediately adjacent to the motor cortex (< 1 mm) for a length of 40 mm, or the anterior half of the SSS. Attempted access with 5-Fr and 6-Fr delivery catheters was associated with longer procedure times and higher complication rates. A 4-Fr catheter (internal lumen diameter 1.1 mm) was successful in accessing the SSS in 100% of cases with no associated complications. Complications included procedure-related venous dissection in two major areas: the torcular herophili, and the anterior formation of the SSS. The bifurcation of the cruciate sulcal veins with the SSS was a reliable predictor of the commencement of the motor area. CONCLUSIONS The ovine model for cerebral catheter venography has generalizability to the human cerebral venous system in relation to motor cortex location. This novel model may facilitate the development of the novel field of endovascular neural interfaces that may include preclinical investigations for cortical recording applications such as paralysis and epilepsy, as well as other potential applications in neuromodulation.

Published

2018

10. The ovine motor cortex: A review of functional mapping and cytoarchitecture.

Author

John SE, Lovell TJH, Opie NL, Wilson S, Scordas TC, Wong YT, Rind GS, Ronayne S, Bauquier SH, May CN, Grayden DB, O'Brien TJ, and Oxley TJ

Subjects

Animals, Brain Mapping, Motor Cortex diagnostic imaging, Neurons cytology, Neurons physiology, Motor Cortex anatomy & histology, Motor Cortex physiology, Sheep anatomy & histology, Sheep physiology

Abstract

In recent years, sheep (Ovis aries) have emerged as a useful animal model for neurological research due to their relatively large brain and blood vessel size, their cortical architecture, and their docile temperament. However, the functional anatomy of sheep brain is not as well studied as that of non-human primates, rodents, and felines. For example, while the location of the sheep motor cortex has been known for many years, there have been few studies of the somatotopy of the motor cortex and there were a range of discrepancies across them. The motivation for this review is to provide a definitive resource for studies of the sheep motor cortex. This work critically reviews the literature examining the organization of the motor cortex in sheep, utilizing studies that have applied direct electrical stimulation and histological methods A clearer understanding of the sheep brain will facilitate and progress the use of this species as a scientific animal model for neurological research., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

11. Development and Implementation of a Corriedale Ovine Brain Atlas for Use in Atlas-Based Segmentation.

Author

Liyanage KA, Steward C, Moffat BA, Opie NL, Rind GS, John SE, Ronayne S, May CN, O'Brien TJ, Milne ME, and Oxley TJ

Subjects

Algorithms, Anatomy, Cross-Sectional methods, Anatomy, Veterinary, Animals, Brain diagnostic imaging, Image Interpretation, Computer-Assisted, Image Processing, Computer-Assisted, Magnetic Resonance Imaging methods, Anatomy, Artistic methods, Atlases as Topic, Brain anatomy & histology, Brain Mapping methods, Brain Mapping veterinary, Sheep anatomy & histology

Abstract

Segmentation is the process of partitioning an image into subdivisions and can be applied to medical images to isolate anatomical or pathological areas for further analysis. This process can be done manually or automated by the use of image processing computer packages. Atlas-based segmentation automates this process by the use of a pre-labelled template and a registration algorithm. We developed an ovine brain atlas that can be used as a model for neurological conditions such as Parkinson's disease and focal epilepsy. 17 female Corriedale ovine brains were imaged in-vivo in a 1.5T (low-resolution) MRI scanner. 13 of the low-resolution images were combined using a template construction algorithm to form a low-resolution template. The template was labelled to form an atlas and tested by comparing manual with atlas-based segmentations against the remaining four low-resolution images. The comparisons were in the form of similarity metrics used in previous segmentation research. Dice Similarity Coefficients were utilised to determine the degree of overlap between eight independent, manual and atlas-based segmentations, with values ranging from 0 (no overlap) to 1 (complete overlap). For 7 of these 8 segmented areas, we achieved a Dice Similarity Coefficient of 0.5-0.8. The amygdala was difficult to segment due to its variable location and similar intensity to surrounding tissues resulting in Dice Coefficients of 0.0-0.2. We developed a low resolution ovine brain atlas with eight clinically relevant areas labelled. This brain atlas performed comparably to prior human atlases described in the literature and to intra-observer error providing an atlas that can be used to guide further research using ovine brains as a model and is hosted online for public access.

Published

2016