Theoretical Studies on Perfluorinated Acids of Environmental Significance

Hidalgo-Puertas, Abdel

04 September 2015

A new approach for predicting octanol-water partition coefficients (Log P) of linear perfluorinated compounds, making use of the limited experimental data available, previous observations and the consistent similarities observed between the experimental and calculated (with electronic structure methods and using EPI suite) slopes of the linear plots of Log P values with the number of carbon atoms (N = 2 to 11) is described here. Eight families of linear organic compounds were investigated: carboxylic acids, perfluorinated carboxylic acids, sulfonic acids and perfluorinated sulfonic acids, together with their corresponding conjugate bases. To the best of our knowledge, this work reports the first application of density functional theory methods to the calculation of Log P values of perfluorinated compounds. A second part of the thesis, describes the study of the thermodynamic stability of the PFOA family of 39 structural isomers with the M06-2X, LC-ωPBE, B97D and B3LYP functionals and with the PM6 method. The PM6 results closely resemble the M06-2X results for neutral PFOAs, but greatly disagree regarding anions. The four functionals applied behave similarly from a qualitative point of view, but quantitatively speaking, the LC-ωPBE and B97D results are between the M06-2X and B3LYP stability results. M06-2X ranks highly substituted isomers as more stable than did B3LYP, and ranks less-branched isomers quite low in relative stability compared to B3LYP. Various similarities with a former PFOSs study applying the M06-2X and B3LYP functionals have been identified. The degree of branching within structural isomers cannot always be precisely determined, and is not the only aspect that determines thermodynamic stability; the pattern of substitution seems to also play a significant role. / Graduate

Perfluorinated compounds

Log P

Kow

octanol-water partition coefficient

isomer profiling

PFOA

PFOS

Prediction of Human Intestinal Absorption

Patel, Raj B., Patel, Raj B.

January 2017

The proposed human intestinal absorption prediction model is applied to over 900 pharmaceuticals and has about 82.5% true prediction power. This study will provide a screening tool that can differentiate well absorbed and poorly absorbed drugs in the early stage of drug discovery and development. This model is based on fundamental physicochemical properties and can be applied to virtual compounds. The maximum well-absorbed dose (i.e., the maximum dose that will be more than 50 percent absorbed) calculated using this model can be utilized as a guideline for drug design, synthesis, and pre-clinical studies.

Aqueous Solubility

Dose

Human Intestinal Absorption|

Melting Point

Octanol-water Partition Coefficient

Predictive Modeling

Solubilité aqueuse, coefficient de partage octanol-eau et pression de vapeur de contaminants alimentaires organiques de la famille des phthalates et alkylphénols : détermination expérimentale et modélisation / Aqueous solubility, octanol-water partition coefficient and vapor pressure of organic food packaging contaminants : experimental determination and modeling

Ishak, Hanane

18 September 2017

Cette étude s’attache à la caractérisation physico-chimique des contaminants des emballages alimentaires organiques, précisément les phtalates et les alkylphénols, en terme de solubilité aqueuse, coefficient de partage octanol-eau et pression de vapeur. Cette caractérisation se situe dans le cadre des règlementations REACH concernant l’identification des substances chimiques toxiques. Les mesures expérimentales de solubilité aqueuse sont effectuées par la méthode dynamique de saturation dans un intervalle de température [298.15-328.15K], celles du coefficient de partage octanol-eau avec la méthode « shake-flask » à 298.15. Les mesures de pression de vapeur sont réalisées avec la méthode dynamique de saturation dans un intervalle de température [313.15-423.15K] et validées avec la méthode statique. A partir de ces mesures, les coefficients de partage air-eau et octanol-air sont déterminés. En addition des mesures expérimentales, une prédiction de ces propriétés est effectuée avec les modèles thermodynamiques : UNIFAC originale, UNIQUAC, NRTL et COSMO-sac-dsp. A l’issue de ces résultats, une évaluation quantitative et qualitative de chacun des modèles est effectuée. Cette évaluation facilitera l’optimisation des paramètres de chacun des modèles des deux familles dans le but de créer un modèle de prédiction du phénomène de migration de l’emballage vers l’aliment / The aim of this study is the physical-chemical characterization of the organic food packaging contaminants, particularly phthalates and alkyl phenols, in terms of aqueous solubility, octanol-water partition coefficient and vapor pressure. This characterization falls within the scope of REACH regulations for the identification of chemical substances. The aqueous solubility measurements are performed using the dynamic saturation method in a temperature range of [298.15 – 328.15K], those of octanol-water partition coefficient with the “shake-flask” method at 298.15K. The vapor pressure measurements are carried out with the “dynamic saturation method” in a temperature range between 313.15 and 423.15K, and validated with the static method. These measurements are used in the determination of air-water and octnol-air partition coefficients. Beside experimental measurements, these poperties are predicted using thermodynamic models: UNIFAC originale, UNIQUAC, NRTL and COSMO-sac-dsp. A qualitative and quantitative evaluation is performed for each model. This evaluation will facilitate the optimization of the models’ parameters concerning phthalates and alkyl phenols in order to generate a model for the contaminants migration process

Phtalate

Allkylphenol

Solubilité aqueuse

Pression de vapeur

Coefficient de partage octanol-eau

Modelisation

Phtalate

Alkylphenol

Aqueous solubility

Vapor pressure

Octanol-water partition coefficient

Modeling

540

Optimizing Sample Dissolution Methods of Low Water Soluble Intermediate Organic Compounds to Support Environmental Risk Assessment during Active Pharmaceutical Ingredient Manufacturing.

Mohammed, Warda

January 2021

This project focus on investigating the dissolution of low water-soluble intermediate organic compounds called active pharmaceutical ingredients (API) and organic substances that are manufactured by a pharmaceutical company, Cambrex Karlskoga in Sweden. Several dissolution methods were used and evaluated using methods including total organic carbon (TOC), chemical oxygen demand (COD), biochemical oxygen demand (BOD) and Microtox toxicity test. The selection of solvents were based on previous studies and specifications from the Swedish Institute of Standards, SIS.The performance of eight solvents for different organic substances were evaluated using the above mentioned methods. Solvents that are highly volatile and have low solubility in water were excluded. Therefore, dimethyl sulfoxide (DMSO), dimethylformamide (DMF) and Pluronic F-68, that had highest water solubility, low acute toxicity and not degradable by microorganisms, were further used to dissolve four organic substances. Furthermore, DMSO and DMF were then also used to dissolve four censored chemicals with addition of physical treatment and solvent mixtures (DMF:DMSO with ratio 1:2).Results from each method were discussed and statistical tests were also performed in order to compare different dissolution methods. In addition, quality control and quality assurance were made in order to ensure the quality of measured values from analytical methods. Four organic substances were dissolve in DMSO, DMF and Pluronic F-68 with dissolution ≥79% using six ratios of DMSO and DMF and five ratios of Pluronic F-68 which were analyzed using TOC. Physical treatment increased dissolution of two APIs with 40%. Using BOD, para-aminobenzonic acid (PABA) and 5-nitroisophthalic acid (5-NIPA) had values higher than the guideline values, which indicate high biodegradability of these organic substances. PABA, 5-NIPA and bupivacaine base were acute toxic where PABA showed EC50 values of 27.9 mg/L using DMSO and 36.0 mg/L using DMF, and EC50 values of 5-NIPA were 102 mg/L using DMSO and 84.0 mg/L using DMF, and bupivacaine base had EC50 value of 174 mg/L using solvent mixture (DMF:DMSO with ratio 1:2). With increasing amount of Pluronic F-68, 5-NIPA had increased values of EC50, thereby Pluronic F-68 was not appropriate to use.In conclusion, DMSO and DMF were most appropriate solvents to use in order to dissolve APIs and organic substances with analyte: DMSO ratio of 1:0.5 and analyte: DMF ratio of 1:0.25. In addition, physical treatment could be used in order to increase dissolution of the APIs.

Active pharmaceutical ingredient

API

total organic content

TOC

chemical oxygen demand COD

biological oxygen demand

BOD

Microtox

octanol-water partition coefficient

Kow

solubility.

Chemical Sciences

Kemi