Investigating and Modeling the Mechanical Contributions to Traumatic Brain Injury in Contact Sports and Chronic Neural Implant Performance

Roy J Lycke (6622721)

10 June 2019

Mechanical trauma to the brain, both big and small, and the method to protect the brain in its presence is a crucial field of research given the large population exposed to neuronal trauma daily and the benefit available through better understanding and injury prevention. A population of particular interest and risk are youth athletes in contact sports due to large accelerations they expose themselves to and their developing brains. To better monitor the risk these athletes are exposed to, their accumulation of head acceleration events (HAEs), a measure correlated with harmful neurological changes, was tracked over sport seasons. It was observed that few significant differences in HAEs accumulated existed between players of ages from middle school to high school, but there did exist a difference between sports with girls' soccer players accumulating fewer HAEs than football players. This highlights to risk youth athletes are exposed to and the importance of improved technique and individual player size. To better monitor HAEs for each individual, a novel head segmentation program was developed that extracts player specific geometries from a single T1 MRI scan that can improve the accuracy of HAE monitoring. Acceleration measures processed with individualized head model versus those using a standardized head model typically displayed higher accelerations, highlighting the need for individualized measure for accurate monitoring of HAEs and risk of neurological changes. In addition to the large accelerations present in contact sports, the small but constant strains produced by neural implants embedded in the brain is also an important field of neuro-mechanical research as the physical properties of neural implants have been found to contribute to the chronic immune response, a major factor preventing the widespread implementation of neural implants. To reduce the severity of the immune response and provide improved chronic functionality, researchers have varied neural implant design and materials, finding general trends but not precise relationships between the design factors and how they contribute the mechanical strain in the brain. Performing a large series of mechanical simulations and Cotter's sensitivity analyses, the relationships between neural design factors and the stain they produce in the brain was examined. It was found that the direction which neural implants are loaded contributes the most to the strain produced in the brain followed by the degree of bonding between the brain and the electrode. Directly related to the design of electrodes themselves, it was found that in most cases reducing the cross-sectional area of the probe resulted in a larger decrease of mechanical strain compared to softening the implant. Finally, a study was performed quantifying the resting micromotion of the brain utilizing a novel method of soft tissue micromotion measurement via microCT, applicable within the skull and the throughout the rest of the body.

Biomechanical Engineering

TBI

Football

Neuroscience

Brain Machine Interface

Neural Implant

Head Segmentation

Micromotion

FEM

Simulation

Neural Implant Design

Head Acceleration

Modeling

Die Embryologie des Pfeilschwanzkrebses Limulus polyphemus (Xiphosura, Chelicerata) und anderer Arthropoden unter besonderer Berücksichtigung der Neurogenese

Mittmann, Beate

02 March 2005

Die vorliegende Arbeit beinhaltet verschiedene Aspekte der Embryogenese des Pfeilschwanzkrebses Limulus polyphemus (Chelicerata, Xiphosura), darunter die frühe Neurogenese, die Axogenese, eine Analyse der "Kopf"segmentierung bei Cheliceraten und anderen Arthropoden, sowie das Expressionsmuster des Homöoboxgens Distal-less insbesondere in neuronalen Zusammenhängen. Darüber hinaus wurde eine neue Embryonalstadieneinteilung geleistet. Markierungen mit Phalloidin sowie weiterer neurospezifischer Marker ergaben, daß die frühe Neurogenese bei Limulus polyphemus durch die Immigration von Zellclustern erfolgt. Die Zellen nehmen eine flaschenförmige Gestalt annehmen, bevor sie sich aus dem ventralen Neuroektoderm lösen. Die Anzahl der Zellen pro Zellcluster steigt mit fortschreitender Entwicklung. Die Zellcluster konzentrieren sich in in Zentrum jedes Hemisegmentes, und in ihrem dorsalen Bereich beginnt die rasch voranschreitende Axogenese. Die Untersuchung der "Kopf"segmentierung mittels alpha-Tubulin-Markierungen bei Limulus polyphemus, Triops cancriformis (Crustacea) und Lepisma saccharina (Hexapoda) ergab sowohl bei der Entwicklung des circumoesophagealen Neuropilringes und der Innervierung der dazugehörigen Anhangspaare als auch hinsichtlich des Verlaufs des Stomatogastrischen Nervensystems beachtliche Übereinstimmungen, die entgegen der klassischen Auffassung den Schluß zulassen, daß das Deutocerebrum der Cheliceraten keineswegs reduziert wurde oder mit dem Tritocerebrum verschmolzen ist, sondern die Chelicere innerviert. Somit wäre das Chelicerenneuromer homolog zum Deutocerebrum der Crustacea und Hexapoda (1. Antenne). Der Vergleich des Expressionsmuster des Homöoboxgens Distal-less bei Limulus und Lepisma saccharina ergab neben den typischen Expressionen in auswachsenden Extremitäten- und andern Anhangsknospen bei beiden Vertretern Expressionen in neuronalen Zusammenhängen (im Lobus opticus, Ganglien bei Limulus oder in das ZNS umgebende Zellen bei Lepisma), an den verschiedensten Positionen späterer Sinnesorgane wie Mechano- oder Chemorezeptoren. Doppelmarkierungen mit Synorf-1 deuten darauf hin, daß es sich bei den Dll-positiven Zellen zum größten Anteil um Glia-Zellen handelt. / The following study contains different aspects of the embryology of the horseshoe crab Limulus polyphemus (Chelicerata, Xiphosura) with the main focus on early neurogenesis, axogenesis and the "head"segmentation in chelicerates and other arthropods. The expression pattern of the homeobox gene Distal-less was examined with main focus on neuronal correlations. In addition, a new staging was provided. Phalloidin stainings and other markers showed that the early neurogenesis in Limulus polyphemus happens via immigration of cell clusters. Cellclusters in the prosoma contain cells that become bottle shaped before they immigrate from the ventral neuroectoderm. The number of these cells increases during further development, and the cells concentrate in the middle of each hemisegment. Axogenesis starts at the dorsal edge of these concentrated cellclusters and progresses quite fast building the typical ladder like CNS of arthropods. The investigation of the "head"segmentation using alpha-tubulin stainings in Limulus polyphemus, Triops cancriformis (Crustacea), and Lepisma saccharina (Hexapoda) showed remarkable similarities in the development of the circumesophageal neuropil ring, the related appendages, and the course of the stomatogastric nerves. These results lead to the thesis that the deutocerebrum of chelicerates is neither completely reduced nor totally merged into the tritocerebrum but innervates the chelicerae which contradicts the classical view. According to these results the neuromer of the chelicerae would be homologous to the deutocerebrum of Crustaceans and Hexapods (first antennae). The expression pattern of the homeobox gene Distal-less was examined and compared in Limulus polyphemus and Lepisma saccharina. Beside the typical expression pattern in the developing appendages a participation of the gene in development of the nervous system was observed. Dll positve cells were found in or at least in direct contact with the CNS (optical lobe, ganglia in Limulus or surrounding the entire CNS including the brain of Lepisma), at different positions of later mechano- and chemoreceptors (lateral spines, bristles, flabellum, Johnstons organ etc.). Double stainings using Dll and Synorf-1 showed that at least most of these Dll-postive cells are most likely glia cells.

Schlagworte

Limulus

Neurogenese

Immigration

Kopfsegmentierung

Glia

Deutocerebrum

Distal-less

Phalloidin

alpha-Tubulin

Arthropoden

1

Keywords

Limulus

neurogenesis

immigration

head segmentation

glia

deutocerebrum

Distal-less

phalloidin

alpha-tubulin

arthropods

1

570 Biowissenschaften, Biologie

32 Biologie

ddc:570