Electrochemical synthesis of electroactive polymers for drugrelease for bio scaffolds.

Almquist, Robert

January 2010

Stem cell based therapy has the potential to treat several severe diseases; Parkinson’s disease is one well- known example. Transplantation of stem cell derived cells into animal models is unfortunately often associated with tumour formation or- uncontrolled growth of the transplanted cells. One strategy to suppress this tumour formation might be to induce differentiation of these cells, which in turn would prevent them from dividing.   Neuroblastoma tumors are known to demonstrate the complete transition from an undifferentiated state to a completely harmful, differentiated appearance and derived cells can be used as a model for cell differentiation and tumor suppression.   In this Master Thesis’s the conducting polymers PEDOT and PPy, that upon formation can be doped with biologically active compounds which in- turn can be released in a controlled manner through electrical stimulation, were formed together with various drugs (e.g. Methotrexate and Mycophenolic Acid), here shown to have effect on Neuroblastoma cells. Neuroblastoma- derived cell line SH- SY5Y was used as a model system for neuronal differentiation and tumour inhibition. Release profiles of neuroblastoma active drugs following electrical stimulation were evaluated and the effects from electrochemical processes on simultaneously growing SH- SY5Y cells were investigated.   The methods to deposit and release the drugs were based on electropolymerization and electrochemically controlled release, respectively. Controlled release of various drugs and compounds was monitored using Vis- and UV- spectroscopy and on some occasions using HPLC.   The electrochemically controlled release of a biologically inactive compound that can be used as a negative control for electrochemical release in future experiments was shown and that resulting electrochemical processes have negative effects on neuroblastoma cell growth.

Medical Devices

Conducting Polymers

Other bioengineering

Potential Applications of Silk Fibroin as a Biomaterial

Bailey, Kevin

07 June 2013

Fibroin is a biopolymer obtained from the cocoons of the Bombyx mori silkworm that offers many unique advantages. In this thesis work, fibroin was processed into a regenerated film and examined for potential biomaterial applications. The adsorption of bovine serum albumin onto the fibroin film was investigated to examine the biocompatibility of the film, and it was found that BSA adsorption capacity increased with an increase in BSA concentration. At 10 mg/mL of BSA, the BSA sorption reached 0.045 mg/cm2. This level of BSA is indicative of good blood compatibility and biocompatibility of the fibroin. The gas permeabilities of oxygen, nitrogen, and carbon dioxide were tested for potential applications in contact lenses and wound dressings. Over a pressure range of 70 – 350 psig, the permeability of oxygen and nitrogen was 5 Barrer, while that of carbon dioxide ranged from 26 to 37 Barrer. The oxygen transmissibility of the fibroin films prepared in this study was on the low end required for use in daily wear contact lenses, but sufficient to aid the healing process for use in wound dressings. The permeability and diffusivity of four model drugs in the fibroin film was investigated for potential applications in controlled drug release. The permeability at higher source concentrations leveled out to 0.8 – 4.3 x 10-7 cm2/s depending on the drug tested. The diffusion coefficient determined from sorption experiments was approximately 1.8 x 10-9 cm2/s, while the diffusion coefficients from desorption experiments were determined to be 0.8 – 2.7 x 10-9 cm2/s. The magnitude of the drug permeability and diffusivity are consistent with many other controlled release materials, and the fibroin film showed good potential for use in controlled release.

Silk

Fibroin

Biomaterial

permeability

biocompatibility

controlled release

Chemical Engineering

Analysis and entrapment of select antioxidants from chokecherry and Saskatoon berry fruits

Konecsni, Kelly Alyson

03 June 2011

The major objectives of this research were to produce a phenolic rich isolate from two locally grown Saskatchewan fruits, chokecherries and saskatoons, develop an encapsulation system for the phenolic isolate, and test this system for the delivery of the phenolic isolate in an animal (rat) model. Natural phenolic compounds present in plants such as fruits have antioxidant and free radical scavenging activities, which have been proposed to have health benefits. The extraction of these compounds from plants is commonly performed using methanol despite being toxic to both humans and animals. As such, ethanol was investigated for its ability to extract phenolics from plants as a food safe alternative to methanol. Phenolic extraction from chokecherries with ethanol:formic acid:water (EFW) resulted in higher concentrations (9.83 mg gallic acid equivalents (GAE)/g fresh weight) than with methanol:formic acid:water (MFW) (7.97 mg GAE/g fresh weight). Results from saskatoons showed similar phenolic levels of 4.26 and 4.21 mg GAE/g fresh weight with MFW and ethanol (EFW), respectively. These results showed that EFW was a suitable substitute for MFW in phenolic compound isolation from chokecherries and saskatoons, and could be used to produce extracts that were safe for use in foods and feeds. High performance liquid chromatography with photodiode array detection (HPLC-PDA) was used to determine the phenolic compound composition of the raw fruits and their phenolic rich isolates. Chlorogenic acid was identified in both chokecherry and saskatoon samples, and rutin was also shown to be present in saskatoons. These identifications were based on the relative retention time and ultra violet-visual spectra comparisons to standards. Solid phase extraction (SPE) using Amberlite XAD-16 was employed to produce phenolic isolates from chokecherries and saskatoons. HPLC-PDA results determined that there was a ~2.7x and ~1.6x increase in peak area for chokecherries and saskatoons, respectively when SPE was employed. The antioxidant activity of the extracts and isolates was determined using in vitro radical scavenging tests including 2,2-diphenyl-1-picrylhydrazyl (DPPH) and 2,2´-azinobis-3-ethylbenzthiazoline-sulphonic acid (ABTS). The EFW chokecherry extract and isolate had the highest overall free radical scavenging activity. Crude fruit extracts exhibited lower free radical scavenging values compared to the isolate samples in both of the assays performed. The fruit phenolic isolates were encapsulated in chitosan (CH) sodium tripolyphosphate (TPP) nanoparticles at a ratio of 4.0:1.0 (CH:TPP). HPLC-PDA was used to determine the entrapment efficiency of phenolic isolates to be 15.9 ± 2.7% and 23.0 ± 7.1% for chokecherries and saskatoons, respectively. Characteristics such as the size, surface potential and phenolic release were determined for the two fruit isolate containing nanoparticles. The size of the nanoparticles were 527.90 ± 74.57 nm and 443.03 ± 15.79 nm for chokecherries and saskatoons, respectively. Both of the nanoparticle systems had positive surface charges at 52.70 ± 2.93 mV and 54.43 ± 1.27 mV for chokecherries and saskatoons, respectively. The release properties of the CH:TPP nanoparticles containing fruit phenolics were examined in enzymatic simulated intestinal fluid and resulted in ~23% and ~28% release of chokecherry and saskatoon phenolics, respectively. Saskatoon phenolic isolates and isolates encapsulated in CH:TPP were gavage fed to rats (six animals in each of the two groups) at a dosage rate of 276.36 ± 9.74 mg/kg body weight. The saskatoon isolate contained 12.44 ± 0.44 mg/kg body weight anthocyanins (~3.30 mg anthocyanin per rat). These animals were sacrificed after 1 h and all stomach tissue samples in each of the treatment groups contained detectable levels of anthocyanins. In the small intestine tissues all six of the saskatoon isolate and three of the encapsulated isolate groups had detectable amounts of anthocyanins, while in the large intestine tissue, only one sample from the isolate group showed detectable amounts of anthocyanins. Although other tissues were tested (brain, heart, kidney and liver), anthocyanins were not detected. Therefore anthocyanins were detected in the gastrointestinal tract of both of the treatment groups. The research performed therefore illustrated that phenolic compounds can be extracted from fruit sources using EFW and can be successfully encapsulated in chitosan tripolyphosphate capsules allowing for targeted delivery in an animal model.

animal model

release studies

antioxidants

phenolic compounds

anthocyanins

encapsulation

chitosan

Microsphere Kinetics in Chronic Total Occlusions

Fraser, Ashley

31 December 2010

Chronic total occlusions are a common problem in patients with coronary artery disease. The primary barrier to successful percutaneous coronary intervention is inability to cross the lesion with a guidewire. We seek to characterize polymer microspheres as a controlled delivery mechanism for collagenase and VEGF, novel intralesional therapies being investigated to alter CTO structural properties. Release profiles for protein-loaded PLGA [poly(lactic-co-glycolic acid)] microspheres showed sustained BSA and VEGF release over eight and 48 hours respectively. Polymer degradation products had no impact on endothelial cell growth and protein bioactivity was maintained post-release. In vivo localization of microsphere-released collagenase was not possible due to low concentrations remaining at the site. Histology confirmed microspheres remained in the collagen-dense, proximal 15 mm of the lesion, likely altering the structural integrity of the plaque.

Chronic Total Occlusion

Polymer microsphere

Controlled Release

0541

Lanthanide-encoded Poly(styrene-co-methacrylic Acid) Microspheres: Synthesis and Characterization

Liang, Yi

27 July 2012

Lanthanide-encoded polystyrene-co-methacrylic acid (P(S-MAA)) microspheres with narrow size distributions were synthesized by two-stage dispersion polymerization. I examined how the amounts of methacrylic acid (MAA) and lanthanide (Ln) salts affect the composition of the particles formed in the reaction. Also, I performed a systematic study of Ln ion release into different aqueous solutions. In normal buffers, these particles were stable against ion leakage, even upon prolonged storage and stirring. When strong chelating agent ethylenediaminetetraacetic acid (EDTA) and diethylenetriaminepentaacetic acid (DTPA) were present in buffer, the loss of Ln ions increased to 15 % after 8 weeks. A preliminary kinetic study of Ln ion incorporation was performed to help understand the particle formation mechanism.

polystyrene

dispersion polymerization

lanthanide

mass cytometry

microspheres

ion release

0495

Microsphere Kinetics in Chronic Total Occlusions

Fraser, Ashley

31 December 2010

Chronic total occlusions are a common problem in patients with coronary artery disease. The primary barrier to successful percutaneous coronary intervention is inability to cross the lesion with a guidewire. We seek to characterize polymer microspheres as a controlled delivery mechanism for collagenase and VEGF, novel intralesional therapies being investigated to alter CTO structural properties. Release profiles for protein-loaded PLGA [poly(lactic-co-glycolic acid)] microspheres showed sustained BSA and VEGF release over eight and 48 hours respectively. Polymer degradation products had no impact on endothelial cell growth and protein bioactivity was maintained post-release. In vivo localization of microsphere-released collagenase was not possible due to low concentrations remaining at the site. Histology confirmed microspheres remained in the collagen-dense, proximal 15 mm of the lesion, likely altering the structural integrity of the plaque.

Chronic Total Occlusion

Polymer microsphere

Controlled Release

0541

Lanthanide-encoded Poly(styrene-co-methacrylic Acid) Microspheres: Synthesis and Characterization

Liang, Yi

27 July 2012

Lanthanide-encoded polystyrene-co-methacrylic acid (P(S-MAA)) microspheres with narrow size distributions were synthesized by two-stage dispersion polymerization. I examined how the amounts of methacrylic acid (MAA) and lanthanide (Ln) salts affect the composition of the particles formed in the reaction. Also, I performed a systematic study of Ln ion release into different aqueous solutions. In normal buffers, these particles were stable against ion leakage, even upon prolonged storage and stirring. When strong chelating agent ethylenediaminetetraacetic acid (EDTA) and diethylenetriaminepentaacetic acid (DTPA) were present in buffer, the loss of Ln ions increased to 15 % after 8 weeks. A preliminary kinetic study of Ln ion incorporation was performed to help understand the particle formation mechanism.

polystyrene

dispersion polymerization

lanthanide

mass cytometry

microspheres

ion release

0495

Evaluation of metals release from oil sands coke : an ecotoxicological assessment of risk and hazard to aquatic invertebrates

PUTTASWAMY, NAVEEN V

26 August 2011

The oil sands operations in northeast Alberta, Canada, employ unconventional processes to produce synthetic crude oil (SCO). Because the extracted bitumen, ¡®the form of oil in oil sands¡¯, is highly viscous, it requires thermal upgrading to produce SCO. Coking technology is used to convert heavy bitumen fractions to lighter volatile fractions. During this process, an enormous volume of solid coke is produced and the metal impurities (e.g. Al, Fe, Mn, Ni, Ti and V) present in bitumen fractions end-up in the coke particles. As coke demands significant space for storage, oil sands companies are exploring options for placing coke into reclamation landscapes for long term storage and recovery. However, coke holds appreciable amounts of potentially leachable metals that may impede the performance of reclamation landscapes. Although two previous coke leaching studies had showed that coke released metals into water at concentrations exceeding the Canadian guidelines for the protection of aquatic life, the ecotoxicological hazard and risk of these metals were not well characterized. Therefore, the overall goal of this research was to characterize the fate and toxicity of metals associated with coke. In this research, the toxicity of coke leachates collected from oil sands field sites and those artificially generated in the laboratory were evaluated using a standard three-brood Ceriodaphnia dubia tests. Coke leachates (CLs) collected over a period of 20 months from two field lysimeters were found to be acutely toxic to C. dubia. Vanadium concentrations were significantly higher (p¡Ü0.05) than concentrations of all other metals in CLs from both lysimeters, and also in leachates from a laboratory batch renewal leaching study. Furthermore, toxic unit (TU) calculations suggested that Ni and V were likely the cause of CL toxicity, but this was not explicitly proven. Therefore, a chronic toxicity identification and evaluation (TIE) approach was adopted to identify and confirm the cause(s) of CL toxicity. Coke was subjected to a 15 day batch leaching process in the laboratory at pH 5.5 and 9.5 in order to characterize the effect of pH on metals release from coke, and to generate CLs for use in TIE tests. The 7-day LC50 estimates for C. dubia survival were 6.3% and 28.7% (v/v) for CLs generated at pH 5.5 and 9.5, respectively. The dissolved concentrations of Mn, Ni and Zn were high (p¡Ü0.05) in pH 5.5 CL, whereas Al, Mo and V were high (p¡Ü0.05) in pH 9.5 CL. Evidence gathered from a series of chronic TIE tests revealed that Ni and V were the cause of toxicity in pH 5.5 CL, whereas V was the primary cause of toxicity in pH 9.5 CL. Further, the influence of bicarbonate, chloride and sulfate ions on metals release, speciation and Ni and V toxicity was investigated. The type and amount of metals released from coke was significantly influenced by the ion type elevated in the leaching solution. Specifically, sulfate influenced mobilization of Ni, Fe, Mn and Zn from coke, whereas bicarbonate enhanced Al, Mo and V releases from coke. With respect to toxicity, increasing bicarbonate decreased the 7-day Ni2+ IC50 from 6.3 to 2.3 ¦Ìg Ni2+/L suggesting enhanced Ni toxicity at high pH or alkalinity. Conversely, sulfate showed a protective effect against V toxicity to C. dubia. The research presented in this thesis suggests that coke will not be inert when stored in reclamation landscapes and that metals, particularly Ni and V, could reach ecotoxicologically relevant levels in surface waters or substrate porewaters, under favourable leaching conditions. Operationally, efforts should focus on remediation and monitoring of metals released from coke, particularly Ni and V, in impacted wetlands, especially before discharging water into natural wetlands and/or local streams and rivers.

oil sands

coke

vanadium

toxicity

nickel

speciation

metals release

Development and evaluation of an oral controlled release and a transdermal delivery system, for melatonin in human subjects

Lee, Beom-jin

08 December 1992

Graduation date: 1993

Transdermal medication

Drugs -- Controlled release

Evaluation of metals release from oil sands coke : an ecotoxicological assessment of risk and hazard to aquatic invertebrates

PUTTASWAMY, NAVEEN V

26 August 2011

The oil sands operations in northeast Alberta, Canada, employ unconventional processes to produce synthetic crude oil (SCO). Because the extracted bitumen, ¡®the form of oil in oil sands¡¯, is highly viscous, it requires thermal upgrading to produce SCO. Coking technology is used to convert heavy bitumen fractions to lighter volatile fractions. During this process, an enormous volume of solid coke is produced and the metal impurities (e.g. Al, Fe, Mn, Ni, Ti and V) present in bitumen fractions end-up in the coke particles. As coke demands significant space for storage, oil sands companies are exploring options for placing coke into reclamation landscapes for long term storage and recovery. However, coke holds appreciable amounts of potentially leachable metals that may impede the performance of reclamation landscapes. Although two previous coke leaching studies had showed that coke released metals into water at concentrations exceeding the Canadian guidelines for the protection of aquatic life, the ecotoxicological hazard and risk of these metals were not well characterized. Therefore, the overall goal of this research was to characterize the fate and toxicity of metals associated with coke. In this research, the toxicity of coke leachates collected from oil sands field sites and those artificially generated in the laboratory were evaluated using a standard three-brood Ceriodaphnia dubia tests. Coke leachates (CLs) collected over a period of 20 months from two field lysimeters were found to be acutely toxic to C. dubia. Vanadium concentrations were significantly higher (p¡Ü0.05) than concentrations of all other metals in CLs from both lysimeters, and also in leachates from a laboratory batch renewal leaching study. Furthermore, toxic unit (TU) calculations suggested that Ni and V were likely the cause of CL toxicity, but this was not explicitly proven. Therefore, a chronic toxicity identification and evaluation (TIE) approach was adopted to identify and confirm the cause(s) of CL toxicity. Coke was subjected to a 15 day batch leaching process in the laboratory at pH 5.5 and 9.5 in order to characterize the effect of pH on metals release from coke, and to generate CLs for use in TIE tests. The 7-day LC50 estimates for C. dubia survival were 6.3% and 28.7% (v/v) for CLs generated at pH 5.5 and 9.5, respectively. The dissolved concentrations of Mn, Ni and Zn were high (p¡Ü0.05) in pH 5.5 CL, whereas Al, Mo and V were high (p¡Ü0.05) in pH 9.5 CL. Evidence gathered from a series of chronic TIE tests revealed that Ni and V were the cause of toxicity in pH 5.5 CL, whereas V was the primary cause of toxicity in pH 9.5 CL. Further, the influence of bicarbonate, chloride and sulfate ions on metals release, speciation and Ni and V toxicity was investigated. The type and amount of metals released from coke was significantly influenced by the ion type elevated in the leaching solution. Specifically, sulfate influenced mobilization of Ni, Fe, Mn and Zn from coke, whereas bicarbonate enhanced Al, Mo and V releases from coke. With respect to toxicity, increasing bicarbonate decreased the 7-day Ni2+ IC50 from 6.3 to 2.3 ¦Ìg Ni2+/L suggesting enhanced Ni toxicity at high pH or alkalinity. Conversely, sulfate showed a protective effect against V toxicity to C. dubia. The research presented in this thesis suggests that coke will not be inert when stored in reclamation landscapes and that metals, particularly Ni and V, could reach ecotoxicologically relevant levels in surface waters or substrate porewaters, under favourable leaching conditions. Operationally, efforts should focus on remediation and monitoring of metals released from coke, particularly Ni and V, in impacted wetlands, especially before discharging water into natural wetlands and/or local streams and rivers.

oil sands

coke

vanadium

toxicity

nickel

speciation

metals release