gel diffusion experiment stem ed/chm nanotechnology 2015 presented by jennifer welborn
TRANSCRIPT
Gel Diffusion Gel Diffusion ExperimentExperiment
STEM ED/CHMSTEM ED/CHM
Nanotechnology 2015Nanotechnology 2015
Presented by Jennifer Welborn Presented by Jennifer Welborn
Learning GoalsLearning Goals
In this activity, nanotech participants will:In this activity, nanotech participants will: See how food dyes and gelatin are See how food dyes and gelatin are
used to model the delivery of nanoscale used to model the delivery of nanoscale medicines to cells in the human bodymedicines to cells in the human body
Measure diffusion distances of 3 Measure diffusion distances of 3 different colors of food dye by: Eye, different colors of food dye by: Eye, photo image on a computer, ADI photo image on a computer, ADI software (Analyzing Digital Images)software (Analyzing Digital Images)
Diffusion and Teaching StandardsThis lab has content which is applicable to various disciplines/standards
Physical Science/Chemistry: particle motion theory
Biology: passive transport; cellular structure, etc.
Ecology/Environmental Science: environmental effects on living systems
Math: rates; proportions, data collection, measurement, precision/accuracy
DiffusionDiffusion– movement of a substance from a region of higher concentration to a region of lower concentration.
Diffusion continues until equilibrium--- the concentration of a substance is equal throughout a space
https://www.youtube.com/watch?v=n5nubvwJJQMhttps://www.youtube.com/watch?v=pjg7ryrDxdghttps://www.youtube.com/watch?v=qBig2wevHhw
Diffusion and Cells
• Dissolved particles that are small or non-polar can diffuse through the cell membranes.
• The process of diffusion is one of the ways in which substances like oxygen, carbon dioxide and water move into and out of cells.
Carbon dioxide from the environment diffuses into plant cells
Background For Lab ActivityBackground For Lab Activity
The delivery of nanoscale medicines to The delivery of nanoscale medicines to cells in the human body requires cells in the human body requires diffusion through organs, tissues and cell diffusion through organs, tissues and cell membranesmembranes
This activity will explore the affect of This activity will explore the affect of particle size (molecular weight) on particle size (molecular weight) on diffusion ratesdiffusion rates
Understanding molecular diffusion Understanding molecular diffusion through human tissues is important for through human tissues is important for designing effective drug delivery systems designing effective drug delivery systems
A Model for Nanomedicine A Model for Nanomedicine Delivery Delivery
Measuring the diffusion of dyes in Measuring the diffusion of dyes in gelatin is a model for the transport of gelatin is a model for the transport of drugs in the extra-vascular space drugs in the extra-vascular space
Gelatin: biological polymeric material Gelatin: biological polymeric material with similar properties to the with similar properties to the connective extracellular matrix in connective extracellular matrix in tumor tissuetumor tissue
Dyes are similar in molecular weight Dyes are similar in molecular weight and transport properties to and transport properties to chemotherapeuticschemotherapeutics
Some Uses of Nanoscale Some Uses of Nanoscale Particles in Medicine Particles in Medicine
Youtube video made by the Center Youtube video made by the Center for Hierarchical Manufactoring at for Hierarchical Manufactoring at UMASS, Amherst:UMASS, Amherst:
http://www.youtube.com/watch?v=bUvi5eQhPTc
5:40-7:40 shows some of the uses of 5:40-7:40 shows some of the uses of nano-scale particles in medicine. nano-scale particles in medicine.
Nanotechnology for Nanotechnology for Targeted Cancer TherapyTargeted Cancer Therapy
https://www.youtube.com/watch?v=RBjWwlnq3cA
5-minutes5-minutes
Experiment OverviewExperiment Overview
Gelatin will be cut into cylindrical disks, Gelatin will be cut into cylindrical disks, placed in Petri dishes and colored placed in Petri dishes and colored solutions will be added to the outer ringsolutions will be added to the outer ring
The distance that the dye particles The distance that the dye particles diffuse into the gelatin disks will be diffuse into the gelatin disks will be measured over timemeasured over time
The diffusion of the dyes will be The diffusion of the dyes will be compared to model the effect of compared to model the effect of molecular weight on movement of molecular weight on movement of molecules in tumors molecules in tumors
Lab PrepLab Prep
Collect materialsCollect materials– Petri DishesPetri Dishes– Food DyeFood Dye– Syringes/10 ml Syringes/10 ml
graduated cylindersgraduated cylinders– Paper CupsPaper Cups– Plain GelatinPlain Gelatin– Crisco/Petroleum JellyCrisco/Petroleum Jelly– Baking PanBaking Pan– Biscuit cutterBiscuit cutter
Prepare Gel DisksPrepare Gel Disks– Determine amount of Determine amount of
water needed to fill up a water needed to fill up a pan to a depth of 1 cm. pan to a depth of 1 cm.
– Dissolve gel into cold Dissolve gel into cold water (2Pks/Cup/200 ml)water (2Pks/Cup/200 ml)
– Microwave for 90 Sec.Microwave for 90 Sec.– Pour into pan which has Pour into pan which has
been coated with been coated with petroleum jelly and let petroleum jelly and let set.set.
Lab ProcedureLab Procedure
Gel DisksGel Disks– Cut disks--bisquit Cut disks--bisquit
cuttercutter– Thin coating of Thin coating of
Petroleum jelly on Petroleum jelly on inside bottom of Petri inside bottom of Petri dishdish
– Put gel disk –top side Put gel disk –top side down and centered- down and centered- on bottom of dishon bottom of dish
– Gently press disk to Gently press disk to secure secure
Adding DyeAdding Dye– Mix dyes in cupsMix dyes in cups– Inject one Inject one
color/petri dishcolor/petri dish– No dye on top of gelNo dye on top of gel– No seepage under No seepage under
gelgel– Do not move dishes Do not move dishes
after dye insertedafter dye inserted
Important Details For ProcedureImportant Details For Procedure Make the dye solutions according to directions.Make the dye solutions according to directions. Inject dye towards the outside of the petri dish, Inject dye towards the outside of the petri dish,
not towards the gel.not towards the gel. Photograph the gel: same time, same distance, Photograph the gel: same time, same distance,
same ambient lighting, flash off, cover off petri same ambient lighting, flash off, cover off petri dish, same sequence. Keep camera parallel to gel dish, same sequence. Keep camera parallel to gel (do not tilt) to avoid parallax. (do not tilt) to avoid parallax.
Data CollectionData Collection
Method 1-- By eyeMethod 1-- By eye: measure (in mm) : measure (in mm) the distance each dye has diffused for the distance each dye has diffused for each time interval. Record data in a each time interval. Record data in a data table or use excel spreadsheet data table or use excel spreadsheet
Method 2--Using a digital cameraMethod 2--Using a digital camera: take : take photos of each petri dish at the same photos of each petri dish at the same time each day, 8:45 and 4:45, from the time each day, 8:45 and 4:45, from the same height and angle same height and angle
Data CollectionData Collection3 Food Dyes3 Food Dyes
Start
4 hours
Diffusion is first visible
Gel Diffusion AnalysisGel Diffusion Analysis
Gel Diffusion AnalysisGel Diffusion AnalysisMethod 1: Determining Rate of Method 1: Determining Rate of
Diffusion by Eye Diffusion by Eye
Create a graph by hand, in excel, plotly or other graphing program
https://plot.ly/
Diffusion AnalysisDiffusion AnalysisMethod 2: Using a Digital CameraMethod 2: Using a Digital Camera
Group Pictures by Color in date/time Group Pictures by Color in date/time
orderorder
7-9-1600 7-10-0800 7-10-1600 7-11-0800
Pick one color to startPick one color to start Load the first morning shotLoad the first morning shot
– Windows Photo Gallery or other image Windows Photo Gallery or other image programprogram
Using the magnifier, expand the Using the magnifier, expand the photophoto
Using a mm ruler, measure from the Using a mm ruler, measure from the edge of the gel disk to the inner most edge of the gel disk to the inner most edge of the diffusion for each color. edge of the diffusion for each color.
Calculate the diffusion distances for Calculate the diffusion distances for each dye and for each time period: each dye and for each time period:
--Gel diameter measurement (mm) on the --Gel diameter measurement (mm) on the computer screen/65 mm = multiplier. computer screen/65 mm = multiplier.
--Gel diffusion distance (mm) on screen x --Gel diffusion distance (mm) on screen x multiplier = actual distance.multiplier = actual distance.
Record calculated diffusion distances Record calculated diffusion distances for each color and time period in a for each color and time period in a data table or spread sheet. data table or spread sheet.
Calculate Mean Percentage of Diffusion
For the last time period measured and for each colorof dye, calculate and record the mean percentage
of diffusion
Use: total distance traveled by dye in mm / 32.5 x 100 = ________%
Record the mean percentage of diffusion for each color in your data table or spread sheet
Diffusion Analysis
Method 3: Using ADI (Analyzing Digital Images Software Download DEW software from: http://umassk12.net/adi/
Click on Analyzing Digital Images
Open a picture, then trim the photo to increase processing time
Click on the drop down menu
Choose Full Image at Selected Resolution
Then click on trim and use image
Choose this option
Draw a line across the diagonal of the petri dish
Record petri dish diameter and
units
Then, clickdone
Select line tool option
Zoom in to see diffusion lineand edge of gel more clearly
Note length of line
Draw a line from the edgeof the gel to where the diffusion of dye molecules appears to end
Click on the blue and red adjustment tools to help you place the blue and red dots atThe beginning and end of the line
QUALITATIVE OBSERVATION OF DIFFUSION
You can also use ADI software to see a qualitative graph of the diffusion of the yellow dye molecules at a particular time. You can compare the qualitative graph with the quantitative measurements. A qualitative graph also helps to see that diffusion is a dynamic process with a trend in movement but no clear end point.
Draw a line across theGel going through the diagonal
Choose line tool option
Choose graph colors option
This graph shows the intensities of red, green and blue pixels along the line drawnacross the gel. Notice that around 20/100 the lines level off, indicating edge of diffusion
If you turn off all colors but green, you can more easily see that around both 20 and 80 is where the diffusion of the dye molecules tapersoff. So, diffusion of the yellow dye particles at this time interval is about 20/100, or .20. Compare this with 1.09 (diffusion distance)/6.03 (gel diameter) = .18
Questions to considerQuestions to consider
Which dyes diffused the fastest? Which dyes diffused the fastest? Does fast diffusion mean greater or Does fast diffusion mean greater or
poorer retention?poorer retention? How could diffusion and retention be How could diffusion and retention be
optimized? This is an important optimized? This is an important consideration for the delivery of consideration for the delivery of nanoscale medication nanoscale medication
Molecular Weights of The Molecular Weights of The Food ColoringsFood Colorings
Red 40Red 40 Molecular Formula: C18H14N2Na2O8S2
Molecular Weight: 496.421900 [g/mol]
Red 3Red 3
Molecular Formula: C20H6I4Na2O5
Molecular Weight: 879.856060 [g/mol]
Yellow 5Yellow 5
Molecular Formula: C16H9N4Na3O9S2
Molecular Weight: 534.363370 [g/mol
Blue 1Blue 1
Molecular Formula: C37H34N2Na2O9S3 Molecular Weight: 792.848400 [g/mol]