Effect of Long-Chain Fatty Acids on Anaerobic Digestion

Qian, Cheng

12 September 2013

An investigation was carried out to study whether long-chain fatty acids (LCFAs) have an effect on digestion of waste sludge under anaerobic conditions. Four different kinds of LCFAs were used in this study. The 18 carbon series with 0, 1, 2 and 3 double bonds were studied to evaluate the degree of saturation on fatty acid degradation. Due to their molecular structure, unsaturated LCFAs are more soluble than saturated LCFAs. Oleic, linoleic, linolenic acid with an ascending number of double bonds were tested as representatives for three different degrees of saturation. In addition, stearic acid, a saturated fatty acid was also tested. LCFAs were added to sewage sludge at concentrations ranging from 5% to 20% on a weight basis and the pH, solids reduction and COD reduction were determined. The results suggested that in addition to degrading in the digesters, all unsaturated acids contributed additional solids removal, compared to the control group. In contrast, stearic acid did not affect the solids removal. The COD reduction was similar to solids reduction in that additional COD was destroyed when unsaturated LCFAs were added to the sludge. The mechanism for additional solids reduction is not known. / Master of Science

anaerobic digestion

long-chain fatty acid

solids removal

lipid concentration

Formation of Monolayered Phospholipids using Molecular Dynamics

Lexelius, Rebecka

January 2018

The very fundamental properties of biological membranes can be understood by studying their formation. This sets a good foundation for research related to how the membranes interact with organic molecules and ions; something of great value in the quest of explaining transport phenomena through cell membranes. It is furthermore of growing interest within the pharmacological research and contributes to the apprehension of life at the molecular level. In this thesis Molecular Dynamics has been used to simulate how evenly distributed phospholipids solvated in water leads to the formation of monolayers. An automation program has been written in Python for performing these simulations and is to be used as the foundation for performing simulations in further studies. The program was used to simulate model systems of high- and low concentrations of DPPC lipids. The DPPC lipid, like most other lipids, consist of a hydrophilic "head" part and two lipophilic "tails", which is the main cause of the lipids interacting in such a manner that forms membranes. The low concentration system was simulated for a total of 3 ns with all lipids having reached the surface at 1.5 ns, and the all lipids in the high concentration system had risen at 41 ns with a total simulation time of 43 ns. / De mest grundläggande egenskaperna hos cellmembran kan förstås genom att studera hur dessa bildas. Detta skapar en bra grund för forskning relaterad till hur membranen interagerar med organiska molekyler och joner; något av stort värde i bemödandet att förklara transportfenomen genom cellmembran. Dessutom är det av växande intresse inom den farmakologiska forskningen och bidrar till kunskapen om liv på den molekylära nivån. I denna avhandling har Molekylär Dynamik använts för att simulera hur jämnt fördelade fosfolipider lösta i vatten leder till bildandet av monoskiktade membran. Ett automatiseringsprogram har skrivits i Python för att utföra dessa simuleringar och ska komma att användas som grund för genomförandet av simuleringar i vidare studier. Programmet användes för att simulera modellsystem med höga och låga koncentrationer av DPPC lipider. DPPC lipiden, liksom de flesta andra lipider, består av en hydrofil ''huvud'' -del och två lipofila ''svansar'', vilket är den huvudsakliga orsaken till att lipiderna interagerar på ett sådant sätt som driver bildandet av ett membran. Lågkoncentrationssystemet simulerades i totalt 3 ns, varav 1,5 ns behövdes för att alla lipider skulle nå vattenytan. Alla lipider i högkoncentrationssystemet hade kommit upp till ytan efter 41 ns och för detta system utfördes simuleringen under en total tid på 43 ns.

phospholipids

lipids

DPPC

monolayer

molecular dynamics

MD

molecular dynamics simulation

GROMACS

biological membrane

lipid concentration

biophysics

Condensed Matter Physics

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