The Use of Three-Dimensional Scanning and Surface Capture Methods in Recording Forensic Taphonomic Traces: Issues of Technology, Visualisation, and Validation

Three-dimensional (3D) space capture is now routinely applied in forensic practice. This has often taken the form of using pseudo-3D visualisations such as 360° photography (return to scene) or digital photogrammetry or true 3D space capture using laser scanning (to derive surfaces), or total station survey methods (to derive Cartesian coordinates). Often these are used to record topography and spatial distributions at crime scenes and may be used to provide a spatial archive of evidence found at a scene or as an aid in visualisation for courtroom purposes. However, there is a growing interest in the use of 3D data capture methods for recording and analysing taphonomic evidence, both for purposes of recording and data sharing, but also to facilitate formal taphonomic analyses which are often qualitative with regard to taphonomic trace criteria. However, as the application of 3D data in taphonomy is a relatively new phenomenon, there remains little consensus on what equipment and imaging modalities are either appropriate or indeed best, to use, and whether digital models of taphonomic traces are analytically valid or verifiable. This paper sets out to highlight and evaluate a number of technological approaches

Neuromuscular Factors Related to Hamstring Muscle Function, Performance and Injury

Hamstring function is influenced by a number of neural, architectural and morphological factors, and the adaptability of these characteristics has important implications for optimizing performance and reducing injury risk. High rates of maximal or near-maximal hamstring force development are required to generate peak horizontal velocities during running, and this is largely determined by the extent to which these muscles can be voluntarily activated. Greater eccentric hamstring strength also correlates with better acceleration capacity and likely improves the ability to decelerate the lower limb during the presumably injurious terminal swing phase of high-speed running. The intra- and intermuscular coordination of the hamstrings appears to influence both hamstring muscle fatiguability and the risk of muscle strain injury. Muscle volume and architectural features such as fascicle length and pennation angle also influence hamstring function, and these vary considerably between hamstring muscles, between individuals and with training status. The adaptability of these features has been explored to a significant extent in recent times, and careful exercise selection allows selective targeting of individual hamstring muscles or muscle segments and this appears to influence the pattern of chronic adaptations such as muscle hypertrophy. Short fascicles within the often-injured long head of biceps femoris may predispose athletes to strain injury but these appear to respond in a contraction-mode-specific manner; lengthening after eccentric training and shortening after concentric training of 4 or more weeks. Conventional training with eccentric and concentric phases in each repetition can also lengthen fascicles, possibly in an excursion (muscle length)-dependent manner. A large biceps femoris muscle to proximal aponeurosis width ratio has been proposed as a potential risk factor for hamstring strain injury, although this is only supported by biomechanical modelling at the time of writing. High levels of anterior pelvic tilt and lateral trunk flexion during sprint running may also predispose athletes to hamstring strain injury, although the quantity of evidence for this is small at the moment. At present, the optimal methods for altering coordination and running technique are not known

Optimising Hamstring Strength and Function for Performance After Hamstring Injury

Hamstring strain injury often results in neuromuscular performance deficits that persist beyond rehabilitation and the return to full training and competitive sport. It seems appropriate to address these deficits as a part of a sport-specific training program which primarily aims to enhance performance. Prolonged deficits in horizontal ground reaction forces in sprinting, repeat sprint performance, knee flexor eccentric strength and biceps femoris long head fascicle lengths have been observed in multiple studies of hamstring strain injury. Why such deficits persist beyond the return to sport is not known, although persistent neuromuscular inhibition of the injured muscles has been proposed. There is limited and mixed evidence for sprint running kinematic (technique) differences between previously injured and uninjured limbs or athletes, although more work in this area seems warranted. While there is some uncertainty about the optimal mix of methods for addressing the aforementioned deficits, sport-specific running programs in conjunction with continued monitoring of acceleration phase sprint performance and repeated sprint ability seem appropriate. Heavy strength training with at least some eccentrically biased exercises is also recommended to address deficits in eccentric strength and muscle fascicle lengths