Matching Items (17)
Filtering by
- Creators: Barrett, The Honors College
Description
Every minute and a half, an American is sexually assaulted (Department of Justice, 2017). After an instance of sexual assault, some victims are given the choice of having a sexual assault evidence kit (SAK) collected. These kits are designed to collect DNA evidence that will, in the best case scenario, result in the identification of the perpetrator. If the perpetrator cannot be located, the DNA profile can still be submitted to the FBI’s CODIS databank, which houses hundreds of thousands of DNA profiles from criminal cases, and may still lead to apprehension of the rapist. Unfortunately, some SAKs experience long delays, decades even, before being tested. To date, there are hundreds of thousands of untested SAKs that remain in police custody awaiting to be submitted for forensic profiling across the country. Here, we completed a holistic investigation of sexual assault response and SAK processing in Arizona. It is important to notice that the focus of our study not only includes SAK processing and the backlog but sexual assault prevention and improving victim reporting in an effort to understand the SAK “pipeline,” from assault to prosecution.
We identified problems in three major categories that negatively impact the SAK pipeline: historical inertia, legislative and institutional limitations, and community awareness. We found that a large number of SAKs in Arizona have remained untested due insufficient funding and staffing for public crime labs making it difficult for state labs to alleviate the SAK backlog while simultaneously responding to incoming cases (“Why the Backlog Exists,” n.d.). However, surveys of ASU undergraduate students revealed a significant interest in campus assault and the SAK backlog. Based on our findings, we suggest harnessing the interest of undergraduate students and recruiting them to specialized SAK-oriented forensic technician and sexual assault nurse examiner (SANE) training at ASU with the goal of creating a workforce that will alleviate the absence of trained professionals within the country. We also explore the possibility of the creation of a private crime laboratory at ASU devoted the processing of SAKs in Arizona as a measure of alleviating the demand on local public laboratories and providing a more economic alternative to commercial laboratories. The creation of an SAK laboratory at ASU would provide undergraduates the opportunity to learn more about real forensic analysis on campus, provide a pipeline for students to become technicians themselves, and help reduce and prevent a future SAK backlog in Arizona.
We identified problems in three major categories that negatively impact the SAK pipeline: historical inertia, legislative and institutional limitations, and community awareness. We found that a large number of SAKs in Arizona have remained untested due insufficient funding and staffing for public crime labs making it difficult for state labs to alleviate the SAK backlog while simultaneously responding to incoming cases (“Why the Backlog Exists,” n.d.). However, surveys of ASU undergraduate students revealed a significant interest in campus assault and the SAK backlog. Based on our findings, we suggest harnessing the interest of undergraduate students and recruiting them to specialized SAK-oriented forensic technician and sexual assault nurse examiner (SANE) training at ASU with the goal of creating a workforce that will alleviate the absence of trained professionals within the country. We also explore the possibility of the creation of a private crime laboratory at ASU devoted the processing of SAKs in Arizona as a measure of alleviating the demand on local public laboratories and providing a more economic alternative to commercial laboratories. The creation of an SAK laboratory at ASU would provide undergraduates the opportunity to learn more about real forensic analysis on campus, provide a pipeline for students to become technicians themselves, and help reduce and prevent a future SAK backlog in Arizona.
ContributorsStewart, Jamie (Co-author) / Brokaw, Danielle (Co-author) / Stone, Megan (Co-author) / Kanthaswamy, Sreetharan (Thesis director) / Oldt, Robert (Committee member) / School of Human Evolution & Social Change (Contributor) / Barrett, The Honors College (Contributor)
Created2019-05
Description
The effects that forensic-themed programs such as CSI: Crime Scene Investigation has on the public's understanding and expectations of the criminal justice system has been a main focus of study in recent years. This phenomenon was coined by the media and termed the "CSI Effect." This study aimed to research the correlations between age, gender, and program-watching habits on potential juries' evidence expectations in court. To do so, 70 people were surveyed and asked a series of demographic questions, as well as questions about how often they watch forensic-themed shows and their experience with the criminal justice system. They were given a mock crime scene scenario and asked about their scientific and non-scientific evidence expectations in this particular case. The most notable results showed that a longer exposure time to forensic-themed programs correlated to high evidence expectations. However, how often viewers watch forensic-themed programs did not seem to affect their evidence expectations. It was concluded that the higher evidence expectations by modern jurors may be due to a combination of the "CSI Effect" and the newly hypothesized "Tech Effect," instead of just being the consequence of the watching too much forensic-themed television.
ContributorsJones, Kristin Taylor (Author) / Kobojek, Kimberly (Thesis director) / Lafond, Sue (Committee member) / Barrett, The Honors College (Contributor) / School of Mathematical and Natural Sciences (Contributor)
Created2014-05
Description
Abstract Molecular Engineering of Novel Polymeric Agents for Targeted Cancer Gene Therapy Dana Matthews Cancer gene cell therapy is a strategy that involves the administration of genes for correcting the effect of mutated cancer cells in order to induce tumor cell death. In particular, genes that encode for pro-apoptotic proteins can result in death of tumor cells. Prostate cancer is a very common cancer among males in America, and as highly destructive chemotherapy and radiation are generally the only treatments available once the cancer has metastasized, there is a need for the development of treatments that can specifically target and kill prostate cancer cells, while demonstrating low toxicity to other tissue. This experiment will attempt to create such a treatment through gene therapy techniques. The parallel synthesis and DNA binding affinity assay utilized in these experiments have produced a polymer that surpasses pEI-25, a gene delivery polymer standard, in both transfection efficacy and low cytotoxicity and trafficking of polyplexes in the cell, and finding methods to increase the transfection efficacy and specificity of polyplexes for PC3-PSMA cells.
ContributorsMatthews, Dana (Author) / Rege, Kaushal (Thesis director) / Linton, Rebecca (Committee member) / Huang, Huang-Chial (Committee member) / Barrett, The Honors College (Contributor)
Created2008-12
Description
Photophysical Studies of the DNA Microenvironment and Small Molecule-DNA Interactions
The photophysical properties of ethidium in a variety of organic solvents, as well as several dsDNAs, were measured. We report that the fluorescence quantum yield of intercalated ethidium is .30(.03), which falls between previous stated measurements of .14 and .60. We believe this to be the most accurately measured fluorescence quantum yield to date, as verified by Strickler-Berg analyses, which exhibit excellent agreement with experimental fluorescence lifetimes. A marked hypochromism upon binding to DNA is noted due to interactions of the dye’s and nucleobases’ respective π-stacks. This more than counteracts the expected increase in transition dipole due to increased conjugation caused by twisting of the phenyl moiety upon intercalation.
The reduced volume cylinder model was tested by the quenching of the fluorescence of an intercalator (ethidium bromide) by a groove binder (methyl viologen). We report that the model is not accurate over a relevant range of DNA concentrations.
The photophysical properties of ethidium in a variety of organic solvents, as well as several dsDNAs, were measured. We report that the fluorescence quantum yield of intercalated ethidium is .30(.03), which falls between previous stated measurements of .14 and .60. We believe this to be the most accurately measured fluorescence quantum yield to date, as verified by Strickler-Berg analyses, which exhibit excellent agreement with experimental fluorescence lifetimes. A marked hypochromism upon binding to DNA is noted due to interactions of the dye’s and nucleobases’ respective π-stacks. This more than counteracts the expected increase in transition dipole due to increased conjugation caused by twisting of the phenyl moiety upon intercalation.
The reduced volume cylinder model was tested by the quenching of the fluorescence of an intercalator (ethidium bromide) by a groove binder (methyl viologen). We report that the model is not accurate over a relevant range of DNA concentrations.
ContributorsEngelhart, Aaron (Author) / Gould, Ian (Thesis director) / Francisco, Wilson (Committee member) / Bednar, Valerie (Committee member) / Barrett, The Honors College (Contributor)
Created2005-05
Description
Using DNA nanotechnology a library of structures of various geometries have been built; these structures are modified chemically and/or enzymatically at nanometer precisions. With DNA being chemically very stable, these structures can be functionalized through an abundance of well-established protocols. Additionally, they can be used for various biological and medicinal purposes, such as drug delivery. For in vivo applications, the DNA nanostructures must have a long circulation life in the bloodstream; otherwise, they could be easily excreted shortly after entry. One way of making these nanostructures long lasting in the blood is to cover them with the biocompatible polymer, polyethylene glycol (PEG). Adding DNA to PEG before forming structures has been found to interfere in the hybridization of the DNA in the structure, resulting in formation of deformed structures. In this study we have developed a new methodology based on "click chemistry" (CC) to modify the surface of DNA nanostructures with PEG after they are formed. These structures can then be used for in vivo studies and potential applications in the future.
ContributorsSmith, Eric Lynn (Author) / Yan, Hao (Thesis director) / Liu, Yan (Committee member) / Barrett, The Honors College (Contributor) / Department of Chemistry and Biochemistry (Contributor)
Created2015-05
Description
While DNA and protein nanotechnologies are promising avenues for nanotechnology on their own, merging the two could create more diverse and functional structures. In order to create hybrid structures, the protein will have to undergo site-specific modification, such as the incorporation of an unnatural amino, p-azidophenylalanine (AzF), via Shultz amber codon suppression method, which can then participate in click chemistry with modified DNA. These newly synthesized structures will then be able to self-assemble into higher order structures. Thus far, a surface exposed residue on the aldolase protein has been mutated into an amber stop codon. The next steps are to express the protein with the unnatural amino acid, allow it to participate in click chemistry, and visualize the hybrid structure. If the structure is correct, it will be able to self-assemble.
ContributorsAziz, Ann-Marie (Author) / Stephanopoulos, Nicholas (Thesis director) / Mills, Jeremy (Committee member) / School of Social Transformation (Contributor) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2017-05
Description
There are unrealistic expectations of the forensic science discipline by the public today. More specifically about the types of evidence that can be recovered from a fired cartridge casing. The common misconception with the evidence that can be recovered from a cartridge casing is that all three types of evidence: DNA, latent prints, and firearms can be recovered from the same cartridge casing. However, just because some analyses are possible does not mean that they are practical. The definition of possibility is that an event can happen. However, the definition of practicality is not only that it can happen, but that the event should occur to optimize the efficiency of a given task. Through literature review of previous studies as well as experimental data, each discipline (DNA, latent prints, and firearms and toolmark analysis) were evaluated. For the experimental trials, three total experiments were carried out. Experiment one focused on the possibility aspect, so in experiment one the best conditions were simulated to receive a positive result. Experiment two focused on creating conditions that would occur at a crime scene, and experiment three refined those variables to serve as middle ground. After evaluation, each discipline was classified as possible and/or practical. These results were then used to determine practical sequential processing for a fired cartridge casing. After both experimentation and review, it was determined that the best possible sequential processing path for a cartridge casing collected at the crime scene to get the quickest information back is as follows: Firearms, DNA, Latent Prints.
ContributorsKephart, Amanda K. (Author) / Armendariz Guajardo, Jose (Thesis director) / Kobojek, Kimberly (Committee member) / Rex, Scott (Committee member) / School of Mathematical and Natural Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
The two chapters of this thesis focus on different aspects of DNA and the properties of nucleic acids as the whole. Chapter 1 focuses on the structure of DNA and its relationship to enzymatic efficiency. Chapter 2 centers itself on threose nucleic acid and optimization of a step in the path to its synthesis. While Chapter 1 discusses DNA and Uracil-DNA Glycosylase with regards to the base excision repair pathway, Chapter 2 focuses on chemical synthesis of an intermediate in the pathway to the synthesis of TNA, an analogous structure with a different saccharide in the sugar-phosphate backbone.
Chapter 1 covers the research under Dr. Levitus. Four oligonucleotides were reacted for zero, five, and thirty minutes with uracil-DNA glycosylase and subsequent addition of piperidine. These oligonucleotides were chosen based on their torsional rigidities as predicted by past research and predictions. The objective was to better understand the relationship between the sequence of DNA surrounding the incorrect base and the enzyme’s ability to remove said base in order to prepare the DNA for the next step of the base excision repair pathway. The first pair of oligonucleotides showed no statistically significant difference in enzymatic efficiency with p values of 0.24 and 0.42, while the second pair had a p value of 0.01 at the five-minute reaction. The second pair is currently being researched at different reaction times to determine at what point the enzyme seems to equilibrate and react semi-equally with all sequences of DNA.
Chapter 2 covers the research conducted under Dr. Chaput. Along the TNA synthesis pathway, the nitrogenous base must be added to the threofuranose sugar. The objective was to optimize the original protocol of Vorbrüggen glycosylation and determine if there were better conditions for the synthesis of the preferred regioisomer. This research showed that toluene and ortho-xylene were more preferable as solvents than the original anhydrous acetonitrile, as the amount of preferred isomer product far outweighed the amount of side product formed, as well as improving total yield overall. The anhydrous acetonitrile reaction had a final yield of 60.61% while the ortho-xylene system had a final yield of 94.66%, an increase of approximately 32%. The crude ratio of preferred isomer to side product was also improved, as it went from 18% undesired in anhydrous acetonitrile to 4% undesired in ortho-xylene, both values normalized to the preferred regioisomer.
Chapter 1 covers the research under Dr. Levitus. Four oligonucleotides were reacted for zero, five, and thirty minutes with uracil-DNA glycosylase and subsequent addition of piperidine. These oligonucleotides were chosen based on their torsional rigidities as predicted by past research and predictions. The objective was to better understand the relationship between the sequence of DNA surrounding the incorrect base and the enzyme’s ability to remove said base in order to prepare the DNA for the next step of the base excision repair pathway. The first pair of oligonucleotides showed no statistically significant difference in enzymatic efficiency with p values of 0.24 and 0.42, while the second pair had a p value of 0.01 at the five-minute reaction. The second pair is currently being researched at different reaction times to determine at what point the enzyme seems to equilibrate and react semi-equally with all sequences of DNA.
Chapter 2 covers the research conducted under Dr. Chaput. Along the TNA synthesis pathway, the nitrogenous base must be added to the threofuranose sugar. The objective was to optimize the original protocol of Vorbrüggen glycosylation and determine if there were better conditions for the synthesis of the preferred regioisomer. This research showed that toluene and ortho-xylene were more preferable as solvents than the original anhydrous acetonitrile, as the amount of preferred isomer product far outweighed the amount of side product formed, as well as improving total yield overall. The anhydrous acetonitrile reaction had a final yield of 60.61% while the ortho-xylene system had a final yield of 94.66%, an increase of approximately 32%. The crude ratio of preferred isomer to side product was also improved, as it went from 18% undesired in anhydrous acetonitrile to 4% undesired in ortho-xylene, both values normalized to the preferred regioisomer.
ContributorsTamirisa, Ritika Sai (Author) / Levitus, Marcia (Thesis director) / Stephanopoulos, Nicholas (Committee member) / Windman, Todd (Committee member) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2016-05
Description
Extrachromosomal circular DNA (eccDNA) has been identified in a broad range of eukaryotes and have been shown to carry genes and regulatory sequences. Additionally, they can amplify within a cell by autonomous replication or reintegration into the genome, effectively influencing copy number in cells. This has significant implications for cancer, where oncogenes are frequently amplified on eccDNA. However, little is known about the exact molecular mechanisms governing eccDNA functionality. To this end, we constructed a fluorescent reporter at an eccDNA-prone locus of the yeast genome, CUP1. It is our hope that this reporter will contribute to a better understanding of eccDNA formation and amplification within a cell.
ContributorsKeal, Tula Ann (Author) / Wang, Xiao (Thesis director) / Tian, Xiaojun (Committee member) / School of Life Sciences (Contributor, Contributor) / Barrett, The Honors College (Contributor)
Created2021-05
Description
Bermuda Land Snails make up a genus called Poecilozonites that is endemic to Bermuda and is extensively present in its fossil record. These snails were also integral to the creation of the theory of punctuated equilibrium. The DNA of mollusks is difficult to sequence because of a class of proteins called mucopolysaccharides that are present in high concentrations in mollusk tissue, and are not removed with standard DNA extraction methods. They inhibit Polymerase Chain Reactions (PCRs) and interfere with Next Generation Sequencing methods. This paper will discuss the DNA extraction methods that were designed to remove the inhibitory proteins that were tested on another gastropod species (Pomacea canaliculata). These were chosen because they are invasive and while they are not pulmonates, they are similar enough to Bermuda Land Snails to reliably test extraction methods. The methods that were tested included two commercially available kits: the Qiagen Blood and Tissue Kit and the Omega Biotek Mollusc Extraction Kit, and one Hexadecyltrimethylammonium Bromide (CTAB) Extraction method that was modified for use on mollusk tissue. The Blood and Tissue kit produced some DNA, the mollusk kit produced almost none, and the CTAB Extraction Method produced the highest concentrations on average, and may prove to be the most viable option for future extractions. PCRs attempted with the extracted DNA have all failed, though it is likely due to an issue with reagents. Further spectrographic analysis of the DNA from the test extractions has shown that they were successful at removing mucopolysaccharides. When the protocol is optimized, it will be used to extract DNA from the tissue from six individuals from each of the two extant species of Bermuda Land Snails. This DNA will be used in several experiments involving Next Generation Sequencing, with the goal of assembling a variety of genome data. These data will then be used to a construct reference genome for Bermuda Land Snails. The genomes generated by this project will be used in population genetic analyses between individuals of the same species, and between individuals of different species. These analyses will then be used to aid in conservation efforts for the species.
ContributorsClark, Patrick Louis (Author) / Stone, Anne (Thesis director) / Winingear, Stevie (Committee member) / School of Life Sciences (Contributor, Contributor) / School of Human Evolution & Social Change (Contributor) / Barrett, The Honors College (Contributor)
Created2021-05