1 / 18

Investigation of diffusion ouf of different fat matrices – especially for iron in palm fat

Investigation of diffusion ouf of different fat matrices – especially for iron in palm fat. Master Thesis Presentation of Vincent Keehnen. Supervisor: Christina Käppeli Co-Referee: Dr. Hanselmann Referee: Prof. Windhab. Presentation structure. Introduction Objectives Methods

otis
Download Presentation

Investigation of diffusion ouf of different fat matrices – especially for iron in palm fat

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Investigation ofdiffusionoufof different fatmatrices – especiallyforiron in palmfat Master Thesis Presentation of Vincent Keehnen Supervisor: Christina Käppeli Co-Referee: Dr. Hanselmann Referee: Prof. Windhab

  2. Presentation structure Introduction Objectives Methods Results Discussion Summary Outlook D-AGRL, IFNH, Laboratory of Food Process Engineering

  3. Introduction Iron deficiency affects 2 billion people worldwide  especially severe in Third World Countries1 Damages physical performance, cognitive abilities, immune system  severe impact on individual health and national productivity2 One strategy to combat iron deficiency: Iron supplementation  iron pills or injections containing iron Many iron supplementation treatments rely on diffusion  iron pills: Fat matrix releases iron into the stomach Palm fat fraction with a high melting point of around 61 °C  palm fat matrices suitable for tropical climates! D-AGRL, IFNH, Laboratory of Food Process Engineering

  4. Introduction Diffusion Definition:3  mass transferprocess Diffusion coefficient D:3  causedbyconcentrationgradient Mobility of an agentmigratingthrough a certain medium  carried out byBrownianmotion  results in gradual mixingof material Mathematics:  Fick’s second law: concentration changes with time and position Fick’sfirstlaw: matter flowstowardslowerconcentration Diffusion coefficient D [m2/s] D-AGRL, IFNH, Laboratory of Food Process Engineering

  5. Introduction Frame: PhD Projectaimingatdeveloping different fatcapsulesloadedwithiron in collaborationwith Human Nutrition Group  remainupto 24 hours in the human stomach  slowlyreleaseiron in a controlledfashion Central: Controlledrelease! = toset a particularagentfreewith a definedamount, at a certain timeandatspecific location4  too fast: non-transferrinboundiron infections2  tooslow: capsuleleavesstomach  lessironreleased Challenges:  howtoensurereproducibility?  howtoachievecontrolledandfullreleaseduring 24 hours? D-AGRL, IFNH, Laboratory of Food Process Engineering

  6. objectives Develop a reproducible method to measure the diffusion coefficient D of iron out of palm fat Optimize the controlled release of iron out of palm fat to achieve 80 to 100 % release after 24 hours in vitro Demonstrate the technical feasibility of the project in vitro! D-AGRL, IFNH, Laboratory of Food Process Engineering

  7. Methods Idea: Place palmfat-based films loaded with iron in an acidious solution to simulate the release behavior of fat capsules in the human stomach Preparation of palmfat-based films homogeneously loaded with a specified amount of iron sulfate (~ Quinbin, 2006) Carry out unsteady-state diffusivity measurements with these films to obtain the diffusion coefficient D simulating stomach conditions D-AGRL, IFNH, Laboratory of Food Process Engineering

  8. methods CalculationoftheDiffusion Coefficient D:5 y slope [s-1] intercept t = independent variable (x) [s] D [m2/s] D-AGRL, IFNH, Laboratory of Food Process Engineering

  9. Results Preparation of palmfat-based films Problems and Solutions Inhomogeneous crystallization  faster pouring and homogeneous surrounding temperatures Fractures and cracks  homogeneouscooling temperatures Air bubbles  slow and careful flat-rolling of the cover sheet Inhomogeneous distribution of iron  replace manual stirring with high intensity automated stirring D-AGRL, IFNH, Laboratory of Food Process Engineering

  10. Results Unsteady state diffusivity measurement Problems and Solutions Down-Bending  cagestir bar in plasticdeviceto prevent spout formation (partial solution due to density difference) Up-bending  Increase volume of HCl-solution to ensure coverage in spite of up-bending D-AGRL, IFNH, Laboratory of Food Process Engineering

  11. Results Conditions: 37 ˚C, 0.1 M HCl, 800 mL D-AGRL, IFNH, Laboratory of Food Process Engineering

  12. Discussion Objective: Reproducibility? Achievedbyhomogeneouslyprocessingthefilms  similar treatment due to automated stirring  homogeneous distribution of iron by high intensity stirring  avoidance of damage and irregularities  reduction of pouring volume D-AGRL, IFNH, Laboratory of Food Process Engineering

  13. Discussion Objective: Reproducibility? Comparison: Before: After: D-AGRL, IFNH, Laboratory of Food Process Engineering

  14. Discussion Objective: Controlledandfullrelease? Almostcompletelyachievedbyincreasingironsulfatecontentto 17.2 % [w/w] reaching 90 % within 24 hours  Reduced stirring: reducedreleaseprobablydue to less homogeneous mixing of the iron within the solution  Reduction in particlesize: reducedreleaseprobably due tosmaller particles moreeasilytrapped in fatcrystalmatrix(analogousto chromatography)  Increase in FeSO4-Content: increasedreleaseprobablydue to stronger concentrationgradient D-AGRL, IFNH, Laboratory of Food Process Engineering

  15. Discussion Outlook Surfactants and emulsion-matrices? Influence of different microstructures and additives? Fat-mixtures and different fatmatrices? Other possibilitiestoinfluenceandchangerelease? Optimum settings for maximum release? Possibilities forapplication:  Flavorreleasetechnology  Functionalfoodsproducts  Fight againstothermicronutrientdeficiencies D-AGRL, IFNH, Laboratory of Food Process Engineering

  16. Conclusionand Summary Method with high reproducibility developed Controlled release of iron out of palm fat achieved Technical feasibilityoftheprojectdemonstrated D-AGRL, IFNH, Laboratory of Food Process Engineering

  17. References 1Hurrell et al.:Particle size reduction and encapsulation affect the bioavailability of ferric pyrophosphate in rats, Journal of Nutrition, 2004 2WHO: Iron deficiency anemia: Assessment, prevention, and control, Geneva, 2005 3 Cussler: Diffusion: Mass transfer in fluid systems, 1997 4 Pothakamury and Barbosa-Cánovas: Fundamental aspects of controlled release in foods, Trends in Food Science & Technology, 1995 5 Han: Mass transfer modelling in closed systems for food packaging, particulate foods and controlled release technology, Food Science and Biotechnology, 2004 D-AGRL, IFNH, Laboratory of Food Process Engineering

  18. Thank you for your attention D-AGRL, IFNH, Laboratory of Food Process Engineering

More Related