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(2023)ThesisSensory signals informing about frictional properties of a surface are used both for perception to experience material properties and for motor control to be able to handle objects using adequate manipulative forces. There are fundamental differences between these two purposes and scenarios, how sensory information typically is obtained. This thesis aims to explore the mechanisms involved in the perception of frictional properties of the touched surfaces under conditions relevant for object manipulation. Firstly, I show that in the passive touch condition, when the surface is brought in contact with immobilised finger, humans are unable to use existing friction-related mechanical cues and perceptually associate them with frictional properties. However, a submillimeter range lateral movement significantly improved the subject's ability to evaluate the frictional properties of two otherwise identical surfaces. It is demonstrated that partial slips within the contact area and fingertip tissue deformation create very potent sensory stimuli, enabling tactile afferents to signal friction-dependent mechanical effects translating into slipperiness (friction) perception. Further, I demonstrate that natural movement kinematics facilitate the development of such small skin displacements within the contact area and may play a central role in enabling the perception of surface slipperiness and adjusting grip force to friction when manipulating objects. This demonstrates intimate interdependence between the motor and sensory systems. This work significantly extends our understanding of fundamental tactile sensory processes involved in friction signaling in the context of motor control and dexterous object manipulation tasks. This knowledge and discovered friction sensing principles may assist in designing haptic rendering devices and artificial tactile sensors as well as associated control algorithms to be used in robotic grippers and hand prostheses.
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(2022)ThesisCardiovascular disease (CVD) is the leading cause of global mortality. Two forms of CVD are acute coronary syndromes (ACS) and heart failure (HF). Patients with either are prone to repeat hospitalisations, which are detrimental to both patients and the healthcare system. Traditional care models are suboptimal in preventing readmissions. Mobile health interventions (MHIs) are attractive due to the computing power and convenience of the smartphone. Firstly, the literature regarding MHIs in CVD is systematically reviewed and meta-analysed. MHIs improved medication adherence in ACS patients and hospitalisation rates in HF patients. The review noted limitations of published trials and identified features of successful MHIs, which were incorporated into the design of a novel smartphone app-based model of care (TeleClinical Care, TCC). TCC allows home measurement of blood pressure, heart rate and weight by patients. The readings are automatically transmitted to a central server, where clinicians can identify abnormalities and intervene accordingly. A pilot RCT comparing TCC and usual care (UC) to UC alone was performed (n=164). Patients using TCC had fewer readmissions at 6 months (41 vs. 21, hazard ratio 0.51, P= 0.015), and were more likely to be adherent with medications (75% vs. 50%, P= 0.001) and complete cardiac rehabilitation (39% vs. 18%, odds ratio 2.9, P= 0.02) compared to patients in the control arm. A process evaluation of the RCT was subsequently undertaken, which identified several contributory factors to TCC’s success, such as a helpful orientation protocol for team members, and high background rates of HF outreach service and cardiologist follow-up in both trial arms. Via a series of interviews, methods to improve the future delivery of TCC were identified, particularly relating to its integration into mainstream healthcare. Patterns of smartphone ownership among cardiac inpatients were also examined. Age, sex, diagnosis, and private health insurance subscription influenced smartphone ownership. These data will help identify patients who may be excluded from MHIs. The thesis contains a cost-effectiveness model of TCC if applied widely. When enrolment exceeds 237 patients, TCC will reduce healthcare costs relative to UC, resultant to readmission prevention. Enrolment of 500 patients is projected to save $100,000 annually. In conclusion, TCC is demonstrated as a feasible, beneficial, safe, and cost-effective intervention for patients with CVD.
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(2023)ThesisDepression is among the most prevalent mental disorders in middle-aged and older adults, with a global prevalence of up to 11%. Effective preventive measures for depression are often costly and labour-intensive and therefore require risk screenings to be practical. Recent studies suggested that clinically measured walking speed is a risk factor for depression, while little is known about whether other aspects of mobility are also predictive. To explore the temporal association between mobility, in particular daily-life mobility, and incident depression in older adults, one systematic review, one study on method development and validation, and three large-scale cohort studies were conducted. Significant findings include: • The Timed Up and Go Test, which incorporates multiple aspects of mobility (i.e., gait initiation, turning, and sit-to-stand time), is more predictive of depressive trajectories than the Six-Metre Walk Test and Five Times Sit to Stand Test. • Duration of the longest daily walking bout, measured with a waist-worn sensor, independently and significantly predicts incident depression over two years. • Daily-life walking speed, quality, quantity, and distribution can be reliably and validly measured with a wrist-worn sensor. • Daily-life gait quality and quantity, measured with a wrist-worn sensor, independently and significantly predict incident depression over nine years of follow-up. These findings add to the understanding of the association between human locomotion and depression. Gait quality and daily-life gait performances are independent and potentially modifiable predictors of depression. These measures, therefore, may have value for upcoming screening program development. Future research should investigate whether interventions addressing daily-life gait can play a role in preventing depression in middle-aged and older adults.
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(2023)ThesisLittle is known about human muscle growth in children with and without cerebral palsy (CP). The MUGgLE study aims to investigate growth-related changes in the three-dimensional (3D) architecture of lower leg muscles (muscle volume, physiological cross-sectional area (PCSA), fascicle length, and pennation angle) in 320 infants and children with and without CP aged < 3 months and 5 to 15 years. Infants have one leg scan (anatomical magnetic resonance imaging (MRI) and diffusion tensor imaging (DTI) images), while children have three scans over three years. The MUGgLE study is ongoing. This thesis presents data derived from the first scan conducted on each of 208 typically developing (TD) infants and children. Chapter 2 provides muscle volumes of ten muscle groups in infants, and the architecture and moment arms of the medial (MG) and lateral gastrocnemius (LG) muscles. By comparing these data to data obtained from adults, it was shown that MG muscle fascicles grow primarily in cross-section rather than in length from birth to adulthood. Chapter 3 determines if lower leg muscles grow synchronously from birth to 15 years. The data show that muscle volumes, normalised to total lower leg volume, vary with age, indicating asynchronous growth. The soleus and MG muscles grow disproportionately faster. Chapter 4 determines muscle-, age-, and sex-conditional distributions of MG and tibialis anterior (TA) muscle architecture from birth to 15 years. Up to age 15 years, both muscles grow nonlinearly in volume, PCSA, and fascicle length, while the pennation angles remain nearly constant. The MG and TA muscle fascicles grow primarily transversely rather than longitudinally over this period. Chapter 5 explores the development and evaluation of a portable dynamometer used to estimate the passive length-tension curves of the gastrocnemius muscles in children. The evaluation shows that the dynamometer requires further methodological refinements to be reliable enough for clinical and research use. This thesis contributes to the fields of biomechanics, muscle physiology, and human anatomy, providing the largest high-resolution 3D dataset of muscle architecture in children to date. Biomechanists can use the data to build more effective structure-function models of children’s muscles, clinicians can use the data to investigate disordered muscle growth in children and inform early interventions and treatments, and academics can use the data to teach muscle and bone anatomy.
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(2024)ThesisBackground: Radiology education in undergraduate medicine varies greatly in terms of teaching time, topics, methods of delivery and teaching staff. Medical curricula are crowded, and there are contrasting opinions regarding the most appropriate radiology topics, delivery methods and degree of integration to maximise effectiveness. Hypothesis: Radiology is suited to eLearning, especially as digitisation of diagnostic imaging is widespread. eLearning designed utilising principles of evidence-based instructional design might be effective and efficient for learning radiology, compared with traditional teaching methods. Methods: Interactive eLearning modules in radiology were developed and their effectiveness for learning was compared with widely used peer-reviewed non-interactive web-based resources in volunteer senior medical students and junior doctors. Effectiveness was evaluated quantitatively by knowledge assessments and qualitatively by surveys of participants’ perceptions of the resources. A systematic review was performed comparing elements of radiology education programs, in particular the role of eLearning. Results: Interactive eLearning in radiology was at least as effective as non-interactive web based peer reviewed resources in knowledge assessments for senior medical students and junior doctors. High heterogeneity between studies mitigated against firm conclusions in a systematic review and meta-analysis of radiology education. However, thematic analysis suggests that eLearning is equivalent to traditional pedagogies for learning radiology. Educational interventions are highly contextual and tailored for specific cohorts, accounting for high heterogeneity. Strategies to better standardise radiology curricula, assessment and the quality of educational research are required to reduce heterogeneity in radiology education research. Conclusion: Mixed data exists on the effectiveness of radiology teaching. Nevertheless, radiology eLearning resources utilising evidence-based instructional design principles are at least equivalent to traditional pedagogies and might be synergistic with in-person learning activities. Factors likely contributing to successful radiology education interventions include clear learning outcomes, active participation by students in learning and provision of immediate feedback. Strategies to reduce heterogeneity in radiology education research could enable educators to assess and utilise best evidence in their practice.
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(2024)ThesisGene electrotransfer is a technique whereby an electric field is applied to a target tissue to permeabilise the cells, allowing for plasmid DNA/RNA to be taken up and expressed, for a range of therapeutic applications. The BaDGE®project group at UNSW has begun developing new hardware and strategies to improve on current methods for electrotransfer, with an aim to target anatomical regions previously inaccessible with current techniques. One such application is the globus pallidus region of the brain, for treating Parkinson’s disease with plasmids encoding neuromodulating molecules. This thesis details the design, development, characterisation, and in vivo validation of a new device and protocols for improved electrotransfer. This device which could be operated untethered, consisted of integrated fluid and electric pulse delivery via the use of concentric needles, and was shown to have reliable electrical discharge, low fluid dead space, and low bilayer voltage losses. Several methods to enhance the operation of the device were tested and validated both in vitro and in vivo, including the use of quasimonopolar current steering to shape the local electric fields, and the use of sucrose solution for suspending the DNA in order to modify local resistivity and increase field strengths. Finally, a computational model was constructed to demonstrate the operation of this device in an accurately modelled human brain, incorporating findings from earlier experimental results. These experiments and models predicted that the hardware designed in this thesis could be used to achieve substantial transfection in the globus pallidus, especially with the enhancements developed, such that gene electrotransfer could be used as an alternative to current strategies for treating Parkinson’s disease.