Adsorption of Organic Contaminants from Aqueous Solution using Biochar

Essandoh, Matthew

09 May 2015

The main aim of this research is to provide a low cost and sustainable biochar for the removal of organic pollutants from aqueous solution. Wastewater pollution by organic contaminants of emerging concern has become a subject of intense discussion. Removing these contaminants from aqueous solution is paramount to improve water quality for both humans and animal consumption. Traditional adsorption techniques using activated carbon are universal and fast, however, they are very costly. This dissertation therefore seeks to find an alternative low cost adsorbent which can be used to adsorb contaminants from aqueous solution. In chapter one, an overview of some of the selected organic contaminants of emerging concern is given. Pharmaceutical and pesticide entry into the environment, their fate and ecotoxicity are highlighted. Available techniques for the removal of contaminants from aqueous solution are also given. Chapter two is a study on the adsorption of some selected pharmaceuticals using a fast pyrolysis low cost biochar produced from pinewood feedstocks. The pinewood biochar used as the adsorbent in this study was made by fast pyrolysis in an augered reactor at a temperature of 425 oC and a residence time of 20-30 s during bio-oil production. In chapter three, switchgrass biochar has been tested for its potential for remediating water that is contaminated with two phenoxy herbicides, 2,4-dichlorophenoxyacetic (2,4-D) acid and 2-methyl-4-chloro-phenoxyacetic acid (MCPA). The adsorption capacity was remarkable when compared to commercial activated carbon per unit of measured surface area. Furthermore, in chapter four, magnetic and non-magnetic low cost biochars have been tested for the removal of the herbicide metribuzin from aqueous solution under different experimental conditions. The magnetic biochar synthesized from raw switchgrass biochar does not show a detrimental effect on the adsorption capacity. Additional value of this magnetic biochar is the ease of separation from contaminated solution following adsorption.

Ibuprofen

salicylic acid

biochar

adsorption

solution pH

metribuzin

low cost adsorbent

isotherm

magnetic biochar

MCPA

Impact of material attributes & process parameters on critical quality attributes of the amorphous solid dispersion products obtained using hot melt extrusion

Sabnis, Aniket D.

January 2019

The feasibility of hot melt extrusion (HME) was explored for development of amorphous solid dispersion systems. Controlled release formulations were developed using a cellulose based derivative, AffinisolTMHPMC 100cP and 4M grades. BCS class II drugs ibuprofen and posaconazole were selected due to their difference in glass transition temperature and lipophilicity. This study focused on investigation of the impact the material attributes and process parameters on the critical quality attributes in preparation of amorphous solid dispersions using hot melt extrusion. The critical quality attributes were sub divided into three main attributes of material, process and product. Rheology of ibuprofen-Affinisol 100cP from melt phase to extrudate phase was tracked. A partial factorial design was carried out to investigate the critical parameters affecting HME. For optimisation of 40%IBU-Affinisol 100cP blends, a feed rate of 0.6kg/hr, screw speed of 500rpm and screw configuration with two mixing elements were found to be optimum for single phase extrudates. ATR-FTIR spectroscopy was found to be an indirect technique of choice in predicting the maximum ibuprofen drug load within extrudates. Prediction was based on the prepared extrudates without charging them to stability conditions. An alternative strategy of incorporation of di-carboxylic acids to increase the dissolution of posaconazole-Affinisol 4M blends was investigated. Succinic acid and L- malic acid incorporation was found to increase the dissolution of posaconazole. Although, the extrudates crystallised out quicker than the naïve posaconazole-Affinisol 4M, but free posaconazole formed eutectic and co-crystal with succinic and L-malic acid within extrudates. This lead to an increase in dissolution of the extrudates compared to day 0.

Hot melt extrusion

Solid dispersion

Crystallisation

Ibuprofen

Polyox

Soluplus

Affinisol(TM)HPMC

Controlled release

Interleukin-8 as a genetic modifier and pharmacologic target for cystic fibrosis pulmonary disease

Hillian, Antoinette D.

01 August 2009

No description available.

Biology

Genetics

Immunology

cystic fibrosis

interleukin-8

IL-8

neutrophil

ibuprofen

genetic modifier

Acetaminophen, Affect, and Risk: An Analysis of Psychological and Neurochemical Mechanisms

Keaveney, Alexis A.

January 2016

No description available.

Social Psychology

acetaminophen

risk

risk-taking

ibuprofen

affect heuristic

risk perception

Photochemical Transformation of Three Polycyclic Aromatic Hydrocarbons, Ibuprofen, and Caffeine in Natural Waters

Jacobs, Laura Elizabeth

05 September 2008

No description available.

Environmental Science

Photochemistry

Dissolved organic matter

pyrene

phenanthrene

naphthalene

ibuprofen

caffeine

The effect of preoperative ibuprofen on the efficacy of the inferior alveolar nerve block in patients with irreversible pulpitis

Oleson, Mark L.

29 September 2009

No description available.

Dental Care

Health Care

irreversible pulpitis

ibuprofen

inferior alveolar nerve block

preoperative

The Effect of Preoperative Ibuprofen and Acetaminophen on the Efficacy of the Inferior Alveolar Nerve Block in Patients with Irreversible Pulpitis

Simpson, Michael G.

01 November 2010

No description available.

Dental Care

preoperative ibuprofen

preoperative acetaminophen

inferior alveolar nerve block

irreversible pulpitis

Investigation of injection moulding for novel drug delivery systems. An investigation into the use of injection moulding to produce pharmaceutical dosage forms and to understand the relationship between materials, processing conditions and performance, in particular drug release and stability

Deshmukh, Shivprasad S.

January 2015

The feasibility of the injection moulding (IM) was explored for the development of novel drug delivery systems. Controlled release formulations were developed using a substituted cellulose derivative, hydroxypropyl methyl cellulose acetate succinate (HPMCAS) and a graft co-polymer (Soluplus®). BCS class II drugs ibuprofen and the felodipine were selected based on their physicochemical properties. In the present work, a homogenous dispersion of drugs in the polymer matrices was achieved using Hot Melt Extrusion (HME) and extruded pellets obtained were used for the development of the injection moulded systems. Four systems were developed using the IM consisting of ibuprofen-HPMCAS, ibuprofen-Soluplus®, felodipine-PEO-HPMCAS and felodipine-Soluplus®. The ibuprofen acts as a good plasticiser compared to felodipine therefore, felodipine containing IM systems required a plasticiser (PEO) when processed with HPMCAS. The analysis of extruded pellets and injection moulded systems using modulated DSC (MDSC) and Raman spectroscopy confirmed the formation of an amorphous molecular dispersion (i.e solid solution) in the case of all four systems. The phase separation behaviour and the amorphous stability of the systems was studied at various stress conditions. This revealed the “surface crystallisation” behaviour of the ibuprofen-HPMCAS systems. Temperature-composition phase diagram constructed based on the melting point depression and the Flory-Huggins lattice solution theory provided the explanation for the phase separation and crystallisation behaviour of ibuprofen-HPMCAS systems. The advanced characterisation techniques like DMA, 2D XRD and 3D laser microscopy provided the detailed understanding of crystal habits, phase seperation and surface crystallisation. The significant effect of the stress conditions on the rate of shrinkage was observed where, higher shrinkage tendency of a HPMCAS IM system was observed compared to Soluplus® IM systems. The extruded pellets provided the faster drug release compared to the moulded tablets suggests the effect of particle size as well as the densification during IM on the dissolution rate of the dosage form. The nature of the polymer and processing history were the contributing factors for the dissolution of the dosage forms. / The thesis is hardbound in two volumes. Volume II starts at Chapter 5, page 135.

Hot melt extrusion

Injection moulding

Solid dispersion

Crystallisation

Ibuprofen

Felodipine

HPMCAS

Soluplus®

Controlled release

Drug delivery

DNA Damage in Healthy Individuals and Respiratory Patients after Treating Whole Blood In vitro with the Bulk and Nano Forms of NSAIDs

Najafzadeh, Mojgan, Normington, Charmaine, Jacob, B.K., Isreb, Mohammad, Gopalan, Rajendran C., Anderson, Diana

2016 August 1923

Yes / Non-steroidal anti-inflammatory drugs (NSAIDs) inhibit COX enzyme activity which affects the inflammatory response. Inflammation is associated with increasing cancer incidence. Pre-clinical and clinical studies have shown that NSAID treatment could cause an anti-tumor effect in cancers. In the present study, blood was taken from healthy individuals (n = 17) and patients with respiratory diseases or lung cancer (n = 36). White blood cells (WBC) were treated with either a micro-suspension, i.e., bulk (B) or nano-suspension (N) of aspirin (ASP) or ibuprofen (IBU) up to 500 μg/ml in the comet assay and up to 125 μg/ml in the micronucleus assay. In this study results were compared against untreated lymphocytes and their corresponding treated groups. The results showed, that NSAIDs in their nano form significantly reduced the DNA damage in WBCs from lung cancer patients in bulk and nano compared to untreated lymphocytes. Also, there was a decrease in the level of DNA damage in the comet assay after treating WBCs from healthy individuals, asthma and COPD groups with aspirin N (ASP N) but not with IBU N. In addition, the number of micronuclei decreased after treatment with NSAIDs in their nano form (ASP N and IBU N) in the healthy as well as in the lung cancer group. However, this was not the case for micronucleus frequency in asthma and COPD patients. These data show that lymphocytes from different groups respond differently to treatment with ASP and IBU as measured by comet assay and micronucleus assay, and that the size of the suspended particles of the drugs affects responses. / The present study was part funded by United Kingdom India Education Research Initiative (UKERI) SA 07-067.

DNA damage

Lung cancer

COPD

Asthma

Nanoparticles

Bulk forms aspirin

Ibuprofen

Ibuprofen Nanoparticles and its cytotoxicity on A549 and HaCaT cell lines

Graham, Stan, Phillip, Roy, Zahid, Myra, Bano, Nadia, Iqbal, Qasim, Mahboob, Fidaa, Chen, Xianfeng, Shang, Lijun

January 2016

Yes / Ibuprofen (IBF) is an outstanding non-steroidal drug for analgesic and anti-inflammatory therapies but it exhibits poor solubility in water [1, 2]. Increased dosage administration has been linked to gastrointestinal and cardiovascular complications [3]. Many techniques have been employed to improve the solubility of NSAIDs [4]. In this study, the anti-solvent precipitation method was used to make Ibuprofen nanoparticles (IBF NPs). Optimised preparation parameters such as solvent (ethanol), raw drug concentration (400 mg), solvent/anti-solvent ratio (1:50) and surfactant concentration (0.25 mg/ml) have been studied to yield nanoparticles with a mean size of 58.8 nm, which is confirmed by dynamic light scattering and transmission electron microscopy. These IBF NPs posess increased aqueous solubility compared to the micro counterpart and maintain with chemical integrity indicated by high performance liquid chromatography and Fourier transform infrared spectroscopy. In addition, in vitro cytotoxicity of IBF NPs has been studied on A549 and HaCat cell lines using MTT and LDH assays. Both cells were obtained from ATCC. The A549 cells were grown in a modification of Ham’s F-12, containing L-glutamine, called F-12K. The HaCaT cells were grown in DMEM containing sodium pyruvate (110 mg/l). Normal cell culture and sub-culture were applied and the cells were used after around 45 passages [5]. The cell culture media containing 105cells/ml were placed in a 96-well plate with addition of IBF NPs and Micro form at concentrations in the range of between 6 and 500 ug/ml by diluting them with DMEM and F-12K for use with the HaCaT and A549 cells respectively. After 24, 48 and 72h exposure, the MTT and LDH cytotoxicity assay were performed in triplicates and on three separate experiment cultures and the absorbance was recorded at 570 nm and 492nm respectively with Elisa micro plate reader. The cell viability (%) related to control (cells in culture medium without NPs) was calculated. A very good cytotoxicity profile was observed, indicating an in vitro cytocompatibility of the IBF NPs in these cell culture systems and no significant changes in cytotoxicity compared with Micro IBF. We conclude that our IBF NPs have increased solubility, same chemical integrity and unchanged cytotoxicity compared to IBF Micro drug. Further work will concentrate on optimising more rigorous parameter to produce excellent quality NPs. More detailed characterisation of IBF NPs is to be tested, such as using PXRD and SEM to further corroborate particle shape and size. The range of no toxic in vitro concentrations is also to be further confirmed. Eventually scaled up preparation of IBF NPs will be developed without relinquishing NPs quality. This would improve the potential for in vitro/ in vivo applications and clinical use of IBF NPs and NSAIDs in general.

Ibuprofen nanoparticles

Cytotoxicity

Aqueous solubility

A549 cell lines

HaCaT cell lines