EFFECTS OF THERMAL AND NON-THERMAL METHODS ON THE CHEMICAL COMPOSITION AND BACTERIAL INACTIVATION OF CAMEL MILK

Dhahir, Namariq

01 September 2021

Understanding the composition of camel milk coupled with studying the effects of thermal and non-thermal treatments on its components and bacterial inactivation were the general objectives of this dissertation. In the first study (Chapter 2), the gross composition of camel milk including milk protein, fat, casein, total solids, lactose, ash, and mineral content were analyzed. In addition, fatty acid profile, amino acid profile, protein fractions, and volatile compounds were evaluated as well. Our results revealed that camel milk has its unique nutrients profile. These findings make it easier for the researchers and consumers to understand some of the nutritional attributes of camel milk.The impact of non-thermal ultrasound treatment (900 W, 20 kHz, 100% power level) on some milk-borne microorganisms and the components of camel milk was studied in Chapter3. We reported that continuous ultrasound processing was efficient in inactivating Escherichia coli (E.coli) O157: H7 and Salmonella Typhimurium (S. Typhimurium) in camel milk without detrimental effects on milk fatty acids profile, lipid peroxides, and protein fractions except for some changes in milk volatile compounds (VC). In Chapter 4, another non-thermal technique, ultraviolet-C (UV-C) light, was applied to camel milk to study the effects of different UV-C light doses on the viability of E. coli O157:H7 and S. Typhimurium and the chemical changes to milk components. The main findings of this study were: (i) UV-C treatment at a dose of 12.45 mJ/cm2 resulted in only 3.9-log10 for both bacterial strains which did not meet the Food and Drug Administration (FDA) requirements for the 5-log pathogen reduction; (ii) the UV-C treatment at the above dose, had limited effects on camel milk components. Thermal pasteurization of milk was first introduced to prevent milk-borne infectious diseases, however, its effects on camel milk components and quality are still unknown. Therefore, in Chapter 5, we investigated the efficacy of three previously reported thermal methods: PAST-1 (65ºC/30 min), PAST-2 (72ºC/5 min), and PAST-3 (80ºC/5 min) on bacterial inactivation and some camel milk components such as the fatty acid profile, lipid peroxidation, VC, and milk protein fractions. Complete elimination (6 log10 CFU/ml reduction) of E. coli O157: H7 was achieved using all pasteurization methods, however, only 3.4 log10 CFU/ml reduction of the total viable counts was reported using PAST-1 and PAST-3 methods. We also reported that the PAST-1 and PAST-3 methods did not affect the chemical composition of camel milk. In conclusion, we assessed the main components of camel milk along with the amino fatty acid profile, acid profile, volatile compounds, and protein fractions. Thermal methods were more effective than the non-thermal methods in terms of microbial inactivation and most camel milk components were not significantly influenced by thermal and non-thermal methods.

Camel milk

E. coli O157:H7

milk components

Salmonella Typhimurium

ultrasound treatment

ultraviolet-C (UV-C) light

PER- AND POLYFLUOROALKYL SUBSTANCES (PFAS) DEGRADATION BY NANOSCALE ZERO-VALENT IRON UNDER LIGHT FOR WATER REUSE

Xia, Chunjie

01 May 2022

Wastewater reclamation and reuse have been increasingly practiced as sustainable strategies to meet water demands, particularly in regions threatened by water shortages. However, one of the biggest challenges for reusing wastewater effluents (WEs) as irrigation water is to remove emerging organic contaminants such as persistent and potentially bioaccumulated per- and polyfluoroalkyl substances (PFAS), whose presence may result in adverse impacts on crops, soils, aqueous ecosystems, and human health. Photocatalysis is an effective and promising technique to remediate PFAS in aqueous media. This dissertation aims to: i) Develop a novel, environmental-friendly, and low-cost treatment process for PFAS removal and degradation for water reuse; ii) Optimize the experimental conditions and investigate the removal mechanisms of PFAS with different structures in this novel process; iii) Scale up this treatment process and apply it to treatment of WEs in a point-of-use (POU) system. First, ultraviolet (UV) C /nanoscale zero-valent iron (nZVI, Fe0 nanoparticles (NPs)) system is used for the first time to induce PFAS photocatalytic removal from aqueous solution. Oxidative and/or reductive degradation of three representative PFAS - perfluorooctanoic acid (PFOA), perfluorononanoic acid (PFNA), and perfluorooctane sulfonate (PFOS) was achieved using Fe0 NPs under UVC light both with and without presence of oxygen. However, no PFAS removal was observed either under visible light and in the dark, and much lower PFAS degradation was achieved under UVA light. Higher degradation and defluorination efficiencies were obtained for longer chain PFNA compared to PFOA, and higher degradation and defluorination of PFAS were achieved without presence of O2 compared to with O2. The degradation of PFOA and PFOS followed first order reaction kinetics with the highest efficiencies achieved of 97.6, >99.9, and 98.5% without presence of O2 for PFOA, PFNA, and PFOS, respectively. The degradation efficiencies increased with the increase of nZVI concentrations in the range of 1-100 mg/L. The degradation efficiency of PFOA using bare Fe0 NPs was higher than that using 1% PVP-coated Fe0 NPs in the initial 6 h. Second, the removal mechanism of PFAS in UVC/Fe0 NPs system was obtained by testing the concentrations of iron ions (Fe2+/Fe3+), intermediate products, and reactive oxygen species (ROS, e.g., ·O2- and ·OH) generated, and conducting ROS quenching experiments. The proposed degradation pathway of PFCAs (PFNA and PFOA) was initiated from PFOA/PFNA oxidation by transferring an electron of the carboxylate terminal group of PFOA/PFNA to the Fe(III)-carboxylate complex, then followed by decarboxylation−hydroxylation−elimination−hydrolysis (DHEH) pathway and the accompanying CO2 and F− release. The generated shorter chain PFCAs also underwent degradation with time in the system. This proposed degradation pathway was confirmed by the formation of shorter chain PFCAs, e.g. PFHpA, PFHxA, PFPeA, and PFBA, F- ions, and rapid consumption of Fe3+. For PFOS, besides H/F exchange pathway and chain-shortening (DHEH pathway) to form short chain PFAS during PFCA degradation, desulfonation to form PFOA followed by PFOA degradation also happened. These pathways were suggested by the formation of intermediates — trace amount of shorter chain PFCAs, 6:2 FTS, PFHpS, and F- ions. ·O2- and ·OH were not involved in PFOA degradation in the UVC/Fe0 NPs system with presence of O2, while they may be involved in PFOS degradation, e.g., desulfonation to form PFOA, which were suggested by the results of quenching experiments. And introducing H2O2 into the UVC/Fe0 NPs system resulted in lower PFOA degradation efficiency and defluorination efficiency, which also indicated that ·OH may not be involved in PFOA degradation. Hydrated electrons e-aq that can be involved in desulfonation, defluorination, and C-C bond scission processes were likely quenched by the presence of oxygen to reduce the degradation and defluorination efficiencies; plus, presence of Fe0 NPs may promote the generation of hydrated electrons. Last, UVC/Fe0 NPs system was used to degrade PFAS from WEs in both bench scale and in a scale up POU system. The degradation efficiencies of PFAS in WEs from both wastewater treatment plants (WWTP) were lower than that in deionized water, likely reflecting the complex compositions in the environmental media. Optimal degradation efficiencies of 90±1%, 88±1%, and 46±2% were obtained for PFNA, PFOS, and PFOA, respectively, each starting from 0.5 µg/L using bare Fe0 at pH 3.0 after 2 h. PFAS removal and bacterial inactivation were achieved simultaneously in the POU system using Fe0 NPs without and with rGO support under UVC irradiation in WEs, although the PFAS levels were still above the regulation levels for discard. These pilot tests provided more data and experiences for the real applications of UVC/Fe0 NP system to PFAS contaminated wastewater or other water matrix treatment. Overall, this research demonstrated a cost-effective and environment-friendly method — UVC/Fe0 NPs method for PFAS (i.e., PFOA, PFNA, and PFOS) degradation from WEs for water reuse both with and without presence of oxygen. The possible degradation mechanisms of PFAS with different structures were obtained by testing the concentrations of iron ions, intermediate products, and reactive oxygen species (ROS) involved in the reactions. The developed technology can be potentially applied to treat other environmental media (e.g., groundwater, landfill leachate) that are contaminated by PFAS from previous anthropogenic activities.

Fe0 nanoparticles/nZVI

PFAS

Photodegradation

Ultraviolet C (UVC)

Wastewater effluent

Water reuse

Thermal treatments for short-term storage of potato (Solanum tuberosum L.)

Ranganna, Byrappa.

January 1996

No description available.

Potatoes -- Sprouting.

Ultraviolet radiation.

Potatoes -- Effect of temperature on.

A comparison of the physical radiation-induced bystander effect and peroxide-mediated oxidative stress in human and murine epithelial cells

Rusin, Andrej

January 2021

The effects of low doses of ionizing radiation on living things is a continually evolving area of research. Importantly, low dose effects were historically overlooked and not properly accounted for the assessment of risk to human health, as is the case with the contentious linear no-threshold model. These low dose effects are now known to be relevant to human health in both accidental and intentional exposures, including doses relevant to medical diagnostics and therapeutics. Furthermore, there is a relative dearth of information on low dose effects in non-human species, which necessitates further investigation and evaluation of radiosensitivity. Radiation-induced bystander effects occur in organisms due to the receipt of signals from directly irradiated cells, which act to communicate radiation damage to surrounding cells. Recent research has identified one type of bystander signal which is carried by photons of biological origin, however the effects produced in bystander cells receiving these photons has not been extensively investigated. It was suspected, based on previous research, that reactive oxygen species participate in the manifestation of this bystander effect. Three mammalian cell lines were assessed for their ability to produce bystander photons upon direct irradiation; subsequently, radiologically unexposed cells were exposed to the resulting photons and assayed for biological effects. The human cell lines used exhibited significant photon emissions and oxidative stress, clonogenic cell death, reduced cellular metabolism, and compromised mitochondrial oxidative phosphorylation following exposure to these photons. The use of a melanocyte cell line indicated that these effects are attenuated by melanin, and this is suspected to occur through photoabsorption or antioxidant mechanisms. Additionally, the same assays were conducted following cell exposure to hydrogen peroxide at low concentrations to assess responses to oxidative stress relevant to bystander responses, indicating less overall sensitivity in the examined melanocytes. These findings are significant because they contribute to our understanding of the mechanisms behind low dose biological effects, because they further challenge the linear no-threshold model and other models based on target theory, because they provide evidence for differential responses to the physical bystander signal in non-human species, and because secondary photon emissions are likely relevant to the medical radiation sciences. / Thesis / Master of Science (MSc) / Low doses of ionizing radiation interact with living things differently than high doses. Low dose effects are now known to be relevant to human health and protection of the environment. Radiation-induced bystander effects occur in cells due to the receipt of signals from irradiated cells which act to communicate radiation damage to surrounding cells. One type of bystander signal is carried by photons emitted from directly irradiated cells, however the effects produced in bystander cells receiving these photons has not been extensively investigated. This thesis investigates the cellular effects of these “biophotons”, including cell survival, oxidative stress, and metabolism.

Novel aromatic dendritic-co-poly(3-hexylthiophene) composites for photovoltaic cell application

Ramoroka, Morongwa Emmanuel

January 2021

Philosophiae Doctor - PhD / Fossil fuels are part of fuels that are formed from natural processes and they are called non-renewable sources of energy. These include natural gas, coal and oil. They have been used for decades to produce energy globally. However, there are some factors that related with the use of fossil fuels which results in an increase in the requirement of large amounts of energy. In addition, the use of fossil fuels as energy source has a negative impact on the environment and they cannot be reused. It is expected that at some point they will run out. Thus, a need for a renewable, clean and plentiful source of energy is urgent. Solar energy is one of the energy sources that may overcome fossil fuel drawbacks.

Dendrimers

Photoluminescence

Organic photovoltaic cells

Ultraviolet-visible spectroscopy

Cyclic voltammetry

Fossil fuels

Limited Effectiveness of Psoralen- and Ultraviolet-Inactivated Vaccinia Virus on Shiv Infection

Glenn, L. Lee

17 October 2013

Excerpt: The title and conclusions of the study recently published by Jones et al. (1) concluded that monkeys were protected from dying from a form of simian-human immunodeficiency virus (SHIV) by an psoralen- and ultraviolet-inactivated vaccinia virus in a multi-envelope DNA-VV-protein (DVP). However, the findings in the study are more equivocal than indicated by the title because the effectiveness of the modified vaccinia virus was not decisively demonstrated.

envelope cocktail

HIV-1 vaccine

Non-human primate

Pathogenic SHIV

Ultraviolet-inactivated vaccinia virus

College of Nursing

Nursing

A New Spectroscopic Method for the Non-Destructive Characterization of Weathering Damage in Plastics

George, Andrew Robert

20 November 2006

The weathering of plastics and composites is a problem because of the loss of both physical and mechanical properties that it causes in these materials. But this weathering effect has been difficult, and in some cases, impossible to characterize without the destruction of the plastic or composite part. Clearly a rapid, reliable, and non-destructive test for the extent of the weathering damage is critically needed. A recent problem that arose at Superyacht Solutions, a boat repair company in Australia, required a solution to just this problem. Such a test was developed for Superyacht Solutions, and is being applied across a wide range of plastic materials. The chemical foundation upon which this solution rests is also being confirmed. The Superyacht Solutions problem was that a boat was brought in for repair which was yellowing dramatically. Surface erosion was confirmed by scanning electron microscope (SEM) surface studies. A loss of mechanical properties was also suspected. A new spectroscopic method of analysis was developed that not only identified the problem as extensive oxidation, but was able to quantify the extent of damage that occurred through a non-destructive technique. This method has also been applied to other plastics with encouraging initial results. The method used and its theoretical basis are included in this thesis.

plastics

weathering

non-destructive

spectroscopy

EDS

ultraviolet

photooxidation

oxidation

Construction Engineering and Management

Assessing the viability of sol-gel nimgo films for solar blind detection

Scheurer, Amber

01 May 2011

Wide bandgap semiconductors have been broadly investigated for their potential to detect and emit high energy ultraviolet (UV) photons. Advancements in deep UV optoelectronic materials would enable the efficient and affordable realization of many medical, industrial and consumer UV optical devices. The traditional growth method, vacuum deposition, is an extremely complicated and expensive process. Sol-gel processing dramatically simplifies facility requirements and can be scaled to industrial size. The work presented here involves a novel study of the ternary wide bandgap material Ni1-xMgxO. Films were developed by sol-gel spin coating for investigation of material and electrical properties. This method produced films 200-600 nm thick with surface roughness below 4 nm RMS. Sintered films indicated an improvement from 60% to 90% transmission near the band edge. Additionally, compositional analysis was performed by X-ray Photoelectron Spectroscopy and film defects were characterized by photoluminescence using a continuous wave He-Cd UV laser, revealing the expected oxygen defect at 413nm. This film growth technique has produced thin polycrystalline films with low surface roughness and a high degree of crystalline orientation; crucial characteristics for semiconductor devices. These films have demonstrated the ability to be tuned over the full compositional range from the bandgap of NiO (3.6 eV) to that of MgO (7.8 eV). Optoelectronic devices produced by standard photolithographic techniques are discussed as well as the electrical transport properties of their metal contacts. Based on initial results, these films have demonstrated strong potential as solar blind detectors of UV radiation.

Electrical and Computer Engineering

The Impact Of Growth Conditions On Cubic Znmgo Ultraviolet Sensors

Boutwell, Ryan

01 January 2013

Cubic Zn1-xMgxO (c-Zn1-xMgxO) thin films have opened the deep ultraviolet (DUV) spectrum to exploration by oxide optoelectronic devices. These extraordinary films are readily wet-etch-able, have inversion symmetric lattices, and are made of common and safe constituents. They also host a number of new exciting experimental and theoretical challenges. Here, the relation between growth conditions of the c-Zn1-xMgxO film and performance of fabricated ultraviolet (UV) sensors is investigated. Plasma-Enhanced Molecular Beam Epitaxy was used to grow Zn1-xMgxO thin films and formation conditions were explored by varying the growth temperature, Mg source flux, oxygen flow rate, and radio-frequency (RF) power coupled into the plasma. Material review includes the effect of changing conditions on the film’s optical transmission, surface morphology, growth rate, crystalline phase, and stoichiometric composition. Oxygen plasma composition was investigated by spectroscopic analysis under varying oxygen flow rate and applied RF power and is correlated to device performance. Ni/Mg/Au interdigitated metalsemiconductor-metal detectors were formed to explore spectral responsivity and UV-Visible rejection ratio (RR). Zn1-xMgxO films ranged in Mg composition from x = 0.45 - 1.0. Generally, x increased with increasing substrate temperature and Mg source flux, and decreased with increasing oxygen flow rate and RF power. Increasing x was correlated with decreased peak responsivity intensity and increased RR. Device performance was improved by increasing the ratio of O to O+ atoms and minimizing O2 + in the plasma. Peak responsivity as high as 500 A/W was observed in visible-blind phase-segregated Zn1-xMgxO devices, while cubic iv phase solar-blind devices demonstrated peak responsivity as high as 12.6 mA/W, and RR of three orders of magnitude. Optimal conditions are predicted for the formation of DUV Zn1- xMgxO sensors

Oxide

semiconductor

thin films

optoelectronics

ultraviolet

sensor

detector

photonics

Electromagnetics and Photonics

Optics

Exposure to Ultraviolet Radiation Causes Proteomic Changes in Embryos of the Purple Sea Urchin, Strongylocentrotus purpuratus

Campanale, Joseph Paul

01 August 2009

The amount of solar ultraviolet radiation (UVR, 290-400 nm) reaching Earth’s surface is increasing due to ozone depletion and global climate change. Embryos of the purple sea urchin, Strongylocentrotus purpuratus, provide an ideal system for examining how UVR affects developing marine organisms and cells in general. To model the protein-mediated cell cycle response to UV-irradiation, six batches of S. purpuratus embryos were exposed to UVR, monitored for delays in the first mitotic division and examined for global proteomic changes. Embryos from each batch were exposed to or protected from artificial UVR for 25 or 60 min. Embryos treated with UVR for 60 min cleaved an average of 23.24 min (±1.92 s.e.m) later than the UV-protected embryos. Protein expression of UV-protected and UV-treated embryos was examined at 30 and 90 min post-fertilization using two dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis (2D SDS-PAGE) and mass spectrometry (MS). Proteins were isoelectrically focused (pH 4-7) and separated by molecular weight using SDS-PAGE. At least 1,306 protein spots were detected in all gels. A total of 171 protein spots (13% of the detected proteome) migrated differently in UV-treated embryos at 30 min post-fertilization and 187 spots (14%) at 90 min post-fertilization (2-way ANOVA, P= 0.03, n=6). Our results identify the differential migration of proteins from multiple cellular pathways and are the first to indicate that the mechanisms involved in the protein mediated UV-induced developmental delay are integrated among pathways for cellular stress, protein turnover and translation, signal transduction, general metabolism and involve the cytoskeleton.

ultraviolet radiation

sea urchin embryo

proteome response

Biology

Biotechnology

Developmental Biology