\u3cem\u3e Ars, Virtus, Impetus\u3c/em\u3e: Gladiatorial Training and Roman Legionaries

In 105 BCE, the Roman consul Publius Rutilius Rufus employed gladiatorial training for his legionaries. This thesis examines the physiological and psychological consequences of this style of training on the human body in an effort to understand why these particular soldiers were so effective. I used experiential testing alongside primary and secondary source research to examine how this process better prepared Roman troops for engaging in actual combat

Die separation strength for deep reactive ion etched wafers.

In the electronic and microfabrication industry, die separation is one of the most critical steps in producing an undamaged, stand-alone micro-scale device. For silicon based devices, it is the predominant step governing resistance to die failure by mechanical fracture. Traditional separation methods include the use of dicing saws and/or backside grinding to dice-by-thinning. Excessive forces, vibrations, and surface contact involved with these methods can cause undesirable side-wall chipping and microcracking, which often translates to inoperable devices. Deep Reactive Ion Etching (DRIE) offers an alternative technique for die separation with less mechanical force. The DRIE process may be used to either introduce notches in one uniform step that allow for die separation via fracture in three-point bending, or to directly separate the dies by etching completely through the substrate. This work presents an analysis of the stress concentrations due to DRIE etched notches and the bending stress required to achieve die separation. The defect rate and die strength associated with DRIE-based die separated is compared with traditional saw methods for a variety of notch depths. Results indicate that the DRIE-based separation technique offers modest advantages over the traditional methods, but can also greatly reduce strength if the protective mask is over etched. It will also show that shallow trenches formed by a mechanical dicing saw resulted in stronger die than deeper trenches

Smoking and dose-dependent early effects of nicotine on bone mechanical properties and histology

The objective was to study the effects of nicotine and cigarette smoke on mechanical properties of cortical bone. Experiments were conducted for 5 weeks with New Zealand White Rabbits. The first experiment of 18 rabbits studied the effect of nicotine levels delivered via a nicotine patch (5.25, 10.5, 21 ng/ml), measured by different mechanical tests, porosity, and composition. There was no significant difference between the control and the treatment groups.;The second experiment of 22 rabbits studied the effects of nicotine delivered via a nicotine patch (10.5 ng/ml) and via a smoking chamber on fracture toughness and porosity. The rabbits exposed to the smoke for 5 weeks had significantly lower fracture toughness values when compared to the different groups (exposed to smoke for 4 weeks group, nicotine group, and the control group). This suggests that other agents besides nicotine are responsible for the weakening of bone clinically seen in smokers

THE EFFECT OF VARIOUS PATHOLOGIES ON BONE QUALITY

Bone’s ability to resist fracture is often ignored until a low-energy fracture occurs. Patients with Chronic Kidney Disease (CKD) or osteoporosis are at an increased risk of low-energy fracture. Generally, fracture risk is evaluated by using a bone mineral density (BMD) test. BMD values; however, do not fully predict bone’s ability to resist fracture. This suggests that other parameters may be involved. Bone quality is the term used to describe these parameters, which are categorized into three groups: structural, material, and microdamage. The aim of this dissertation research was to examine whether bone quality was altered in patients who: 1) had abnormal bone turnover (high or low) due to CKD, 2) suffered a low-energy fracture despite normal BMD, or 3) had osteoporosis and were treated with bisphosphonates. These studies used iliac crest bone specimens from Caucasian females aged 21 to 87 years. Bone’s material parameters were measured by Fourier transform infrared spectroscopy. The key finding from the turnover study was that high and low turnover was associated with altered bone quality. Specifically, bone with high turnover had a lower mineral-to-matrix ratio compared to normal and low turnover (p\u3c0.05), while low turnover had a lower cancellous bone volume and trabecular thickness compared to normal or high turnover (p\u3c0.05). The key finding from the fracture study was that patients with normal BMD and low-energy fractures had altered bone quality (greater collagen crosslinking ratio) compared to patients who had low-BMD with low-energy fractures and healthy subjects (controls) (p\u3c0.05). Lastly, the key findings from the bisphosphonate studies were that osteoporosis patients treated with these drugs had altered bone quality (specifically, greater (p\u3c0.05) mineral-to-matrix ratio) compared to untreated turnover-matched osteoporotic patients, and that were several positive linear correlations with the nanoindentation derived Young’s modulus and hardness of cortical and trabecular bone and the duration of bisphosphonate treatment (p\u3c0.05). The findings presented provide further evidence that bone quantity is not the sole factor in determining bone’s ability to resist fractures and that bone quality is an essential factor

Re-envisioning Housing in Over-the-Rhine, Cincinnati

A new era of urban revitalization has recently occurred in several major US cities, many of which must deal with outdated or dilapidated urban housing choices in inner city neighborhoods. Many of these broken neighborhoods require new housing alternatives. The proposition of this thesis is how can urban architecture alter the economic viability of a neighborhood. How can new housing typologies help to rehabilitate a blighted neighborhood? What social and neighborhood problems can architecture actually address? These questions seek to address the problems that encompass Over-the-Rhine

Bi-stable buckled energy harvesters actuated via torque arms.

Vibrational energy harvesters (VEH) are one way to generate electricity. Though the energy quantities are not enough to run desktop computers, they can power remote devices such as temperature, pressure, and accelerometer sensors or power biological implants. New versions of the Bluetooth protocol can even be used with VEH technology to send wireless data. An important aspect of VEH devices is the power output, operating frequency, and bandwidth. This dissertation investigates a novel method of actuating the primary buckled energy harvesting structure using torque arms as a force amplification mechanism. Buckled structures can exhibit snap-through and has the potential to broaden the operating frequency for the VEH. Macro and MEMS size prototypes are fabricated and evaluated via a custom made shaker table. The effect of compliance arms, which pin the center beam with piezoelectric strips, are also evaluated along with damping ratios. ANSYS models evaluating generated power are created for use in future optimization studies. Lastly, high energy orbitals (HEO) are observed in the devices. Results show that buckling lowers and broadens the output power of the new devices. Reverse sweeps drastically increase the operating frequency during snap-through. Rectangular compliance arms made of poly-lactic acid (PLA) generated the most power of all compliance arms tested. HEO performance can be induced by perturbing the system while maintaining the same input force which increases power output