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Design of Device to Stretch Tunable Stiffness Substrates for Cell

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1. aa 72 Appendix G Polyacrylamide Curing Guide scssi esiseriniioissrniiesisiei ninii eteni 74 Table of Figures Figure 1 Examples of Stretching Directions 11 Figure 2 Free Body Diagram of Cells Under Uniaxial and Strip Biaxial Stretch 13 Figure 3 Diagram of a PA sample with PE gripsS a a E 18 Figure 4 Polyacrylamide cured with HDPE Biased Loose Mesh 19 Let EE A EE E 21 Figure 6 Total Lateral Mechanical Strain leale 22 Proure 7 Lateralssadun with HOOK oen ite ae kanan ANGAL Naka pts iero 23 Figure 5 Squat stretchins e ET e ieena 25 Figure 9 Definition or Unusable ATE i eoi aia 24 Figure 10 Normalized Width Definition 25 Figure Ll Central tram Data Anastasia 29 Fiore 12 Usable Area Asses MEN od cepe cett oue tT ed e ese UY yy 26 Large E O ILE Fo 21 Figure 14 Toothed Canna AGA CG ido FR 27 Froure 15 5baped Tooth Camp aries mne iso uoo pg ber ara AGA ias 28 Figure 16 Gear Rack System Alternative Desen 28 Figure 17 Moving well Alternative Design ssssseeeeeeesssssssssssssssseeeeerrrrresssssssssssseseeee 20 Figure 18 Threaded Rod Alternative Design with Cover 30 Figure 19 Threaded Rod Alternative Design without cover 30 Figure 20 Threaded Rod Alternative Design 31 Figure 2 E Threaded Rod Prototype A AA 31 Figure 22 Covered Threaded Rod Alternative Design nn Y Y
2. TIME 1 EPTOY AWG Noncommercial Use only R3Y3 0 DMX 001096 JHN 161282 3MX 514522 22 55 07 3 1 UY Strain 65 Ratio 1 4 NODAL SOLUTION 3TEF 1 e PAI SUB 1 YE gt TIME 1 EPTOX AVG Noncommercial Use only RSYS D DMX 004002 SMN 124062 SME 264012 OCT 30 2006 23 09 52 NODAL SOLUTION HTEP 1 gt A STE 1 d d d t TIME 1 ned dai Noncommercial Use Only R3Y3 OCT 30 2008 DEE 004002 23 07 14 uMN 117512 JMX 106461 117512 1 4 UY Strain Ratio 4 1 HODAL SOLUTION JIEE 1 dUB 1 TIME 1 EPTOX AWG EK kd DME 001151 DMR 002159 JMX 301666 Noncommercial Use Only CCT 20 2008 23 11 51 E A 9 oo _ gt 002153 HODAL SOLUTION STEP 1 30B 1 TIME 1 EPTOY AWG EK kal 001151 201785 E E22231 4 1 UY Strain Noncemmercial Use Only OCT 30 2008 23 15 36 67 Ratio 13 1 HODAL SOLUTION STEP 1 dUB 1 TIME 1 EPTOX AWG R3Y3 DME 001509 SUN 120476 JMX 494274 NODAL SOLUTION STEE 1 dUB 1 TIME 1 EPTOY AWG GK Kan E 001509 JHN 2B3474 sax 1 051 2Haa74 13 1 UX Strain 13 1 UY Strain gt M Noncommercial Use Only int Noncommercial OCT 30 20086 23 41 11 M Use Only OCT 30 2006 23 38 33 68 Ratio 16 1 HODAL SOLUTION JIEP 1 dUB 1 TIME 1 EETOX AVG R3Y3 0 DME 001591 SUN 137932
3. 195 x 205 21 1925 19735 2025 2075 Figure 9 Definition of Unusable Area 4 2 5 Analysis With the stretch configuration established and an accurate model of polyacrylamide functioning it was necessary to determine the final dimension of the samples that the device will ultimately stretch For a sample to be considered usable there must be a region of at least 1 cm of homogenous strain that 1s as close to the desired strain as possible and have a transverse strain the 15 within 10 of the desired axial strain The smallest geometry that meets both these criteria should be considered the optimal sample size for this device A sample 15 considered to exhibit strip biaxial capabilities when the transverse strain 15 reduced to a point such that it 15 10 of the desired axial strain in this case that means attaining a strain value of less than 2 To determine this a study Data in Appendix E was done to determine the effect of normalized width as defined in Figure 10 of a sample has on this strain at the center of the sample In this study multiple combinations of unit length and width were sguat stretched and the results were analyzed It was shown that unit length had no impact on the strain pattern and the central 24 Normalized Width B H Figure 10 Normalized Width Definition transverse strain depended on the width of the samples After width normalization and data regression it was found that normalized width W and centra
4. 45 confident that completing a more complete analysis will show that the membranes will see strain similar to those in the Finite Element Analysis Once this 15 completed and the reproducibility of the individual samples 1s in order then this device will be able to run experiments that will test combined stretch and stiffness of membranes on cell cultures 2 Recommendations This section 1llustrates the suggestions that the project team believes will improve the current designed device These recommendations include ideas for validation of the device and for cell adhesion as well as other ideas for possible future manufacturing While the project team 15 very proud of their final design they provide these suggestions to possibly improve the effectiveness of the device and better control the stiffness and stretch of the polyacrylamide Performing strain and cell adhesion tests would be the obvious first step in continuing this design project While in theory our device should stretch and keep cells alive based on our FEA analysis and material selection human error can always occur making 1t possible that the strains and cell behavior might vary from the expected Testing these would ensure that our device runs as it 15 supposed to Finding a more reliable adhesive would be very beneficial if wells ever need to be constructed During the manufacturing process the project team had a very difficult time with the adhesive provided to us from Gatew
5. JMX 510303 NODAL SOLUTION JTEP 1 3UB 1 TIME 1 EPTOY AWG R3Y3 0 DEE 001591 JHN 295102 DRS 1 112 16 1 UX Strain 16 1 UY Strain Noncemmercial Use Only OCT 30 2008 23 50 39 Noncommercial Use Only OCT 30 2006 lt 23 52 38 69 Usable Area cm Usable Area Center 2 70 6 0 2 9 Norm Width 8 2 07 i HO AO sj 16 520 470 3 66 390 4 ap 608 7 8 96 566 239 10 1 24 7 A ES w N ER E E HR D W N E O E O NIe u Uu1 LI SB 2 x cm 0 3 6 38 80 6 0 3 6 I 7 1 2 12 14 2 sex as Table 8 FEM Data 2 5 4 A pu N o e Boxes highlighted red indicate a usable are lt 1cm e Boxes highlighted green indicate approximate strip biaxial behavior 70 Results Formula Variable Definitions e W Normalized WidtZZ e Y Strain in Center e A Usable Area e A Initial Area e Vere Effective Poisson Ratio 0 5 cm Unit Length ey 0 0183In W 0 0647 R 0 992 A 0 33594 In W 0 1218 R 0 8862 A 0 3085W 0 6765 R 0 9994 Verg 0 0921n W 0 3235 R 0 992 1 cm Unit Length 0 0184 In W 0 0655 Ri 0 9964 A 0 2856A In W 0 2498 R 0 8977 A 1 1814W 2 1314 R 0 9998 Verg 0 092 In W 0 3235 R 0 9964 2 cm Unit Length ey 0 0
6. per second for 10 cycles without breaking Finally the PA was stretch at 57 without failure The limits of the stretch environment of the test were the only limit to how much the gels could be strained While the actual failure 1s not Known the polyacrylamide was 18 cycling well outside the ranges that this device will put on it This test served to validate that as a material polyacrylamide could be stretched to or beyond the reguired strains and frequencies that the client desired These results however we gained with a gripping method that was timely and difficult so an easier method must be determined 4 1 2 PE Mesh as a Gripping Alternative To remedy the difficult gripping situation the project team looked into alternatives to the sandpaper and clip configuration Porous polyethylene sheets have been shown to cure well in polyacrylamide so the project team investigated other polyethylene geometries to determine 1f they provide any advantage over porous sheets The desirable guality of the PE sheets was there porosity so the project team decided to validate PE meshes as analogs of porosity albeit large The tests conducted were largely gualitative and were carried out by attaching wire hooks through the PA samples and gently pulling them by hand to roughly 20 as it was already shown the material should with stand this The first samples used a natural HDPE cut into small rectangles and cured on each side of the PA Two meshes
7. 077 dH4 N d SSdHd SS 91 OCL LLVW SILON A A ll A H UGC 4 Slide Arm Drawing 57 3931d INO WOY4 TIIN 4N41AdOMdA lOd Lut SILON PIL X 8 L Case Drawing 58 NOTES MAT L ACETAL DELRIN Grip Arm Drawing NOTES MAT L POLYPROPYLENE MILL FROM ONE PIECE Well Drawing 59 Appendix E Finite Element Analysis Goal To determine the effect of the dimensional ratio on the strain maps of polyacrylamide PA gel 6 using ANSYS software Samples are stretched 10 in either direction creating an overall stretch of 20 Though pure strip biaxial stretch cannot be achieved with given volume parameters we can get a rough approximation to within 10 of the length wise stretch percent Standard Model Parameters Thickness 1 5mm E 4800 Pa v z 0 35 Element Type Solid Ouad 4node 42 o Behavior Plane Strs w thk Real Constants 0 0015m thk Material Model Structural gt Linear gt Elastic gt Isotropic Mesh Size 0 0005m Loading o Each vertical edge displaced 0 10 L in UX o Corners are constrained in UY Sample Ratios Shown 1 1 1 2 Ae 1 3 3 1 1 4 4 1 13 1 16 1 60 Strain Plots Ratio 1 1 HODAL SOLUTION STEE 1 30B 1 TIME 1 EPTOX AWG RSYS DEE 005073 JMN 046666 SeX lt 947072 048868 HODAL SOLUTION STEP 1 SUB 1 TIME 1 EETOY AVG RSY9 0 DMX 005073 SMM 257275 SE
8. Sep 377 386 Bender Jeffrey R Heart Valve Disease Yale University School of Medicine Heart Book 2002 167 176 Brown T D Techniques for mechanical stimulation of cells in vitro a review J Biomech 2000 33 1 p 3 14 Butcher Jonathan T Nerem Robert M Valvular endothelial cells and the mechanoregulation of valvular pathology Phil Trans R Soc B 2007 362 1445 1457 Butcher J T B C Barrett and R M Nerem 2006 Equibiaxial strain stimulates fibroblastic phenotype shift in smooth muscle cells in an engineered tissue model of the aortic wall Biomaterials 27 30 Oct 5252 5258 Butcher J Craig A Simmons Warnock J Mechanobiology of the Aortic Heart Valve Department of Biomedical Engineering Cornell University Ithaca NY USA 2Institute of Biomaterials and Biomedical Engineering University of Toronto Toronto Ontario Canada 3Department of Agricultural and Biological Engineering Mississippi State University Mississippi State MS USA Engler Adam J Richert Ludovic Wong Joyce Y Picart Catherine Discher Dennis E Surface probe measurements of the elasticity of sectioned tissue thin gels and polyelectrolyte multilayer films Correlations between substrate stiffness and cell adhesion Surface Science Vol 570 Issues 1 2 10 October 2004 Pages 142 154 He Y Macarak EJ Korostoff JM Howard PS 2004 Compression and tension differential effects on matrix accumulation by periodontal
9. Stepper Motor Controller 24 4 6 Optimization The optimization process of this design focused primarily on the environment that the device had to operate in This presented 1ssues of both material selection and of size This section details the 1teration process for designing around these parameters 4 6 1 Dimensional The driving parameter for the size of the device was the shelf size of the incubator that it will ultimately operate in The shelf is roughly 18 x 18 with adjustable heights As this device will be in the incubator for extended periods of time 1t should take up as little space as possible while still stretching a considerable amount of samples Because of this the project team sought to maximize the number of sample along the width of the shelf and minimize the height The depth of the device was kept and roughly half the width of the shelf as well This along with the minimized height could allow two devices to be operated simultaneously either stacked on top of one another or run side by side 4 6 2 Material Selection Most materials used in the device had to be corrosion resistant and any parts that enter the culture environment needed to also be autoclaved This limited the list of materials that the project team had to work with All metal components were to be made of 316 Stainless Steel or other corrosion resistant metals Plastics were a bit more difficult to select however The high pressures and temperatures in t
10. device begins to function Once placed into the device these delrin arms will attach to the driving mechanism 7 2 Driving Mechanism The physical means of stretching the gels 1s outlined in Figure 28 below This right side view shows just the moving parts with the exception of the motor which 15 stationary of the STAINLESS STEEL SLIDE ARM Figure 28 Driving Mechanism 41 device minus the polyacrylamide samples The linear motor drives the coupling assembly which in turn moves the slide arm back and forth The motor 1s attached to the coupling by existing threads on its shaft and the arm 1s fixed to the coupling by a set screw Individual grips arms that enter the cell culture environment are attached to the slide arm by threaded stand offs and nuts The ball slide was included to reduce the friction of the device and limit the power that the motor must output All surfaces that mate with the device case will have acrylic adhesive Teflon tape applied to them as well as on the corresponding surface on the case to further limit the friction in the system 7 3 External Casing Two key characteristics of the casing of the device are that it must be autoclavable and that its interior must be air tight to avoid contamination To adhere to the first characteristic the parts are made of polypropylene which performs well after repeated autoclave sessions The case Figure 29 must also not allow the passage of particles fro
11. ligament fibroblasts in vitro Connect Tissue Res 45 1 28 39 H Hsieh N Li J Frangos 1992 Shear Stress Induced Gene Expression In Human Endothelial Cells Department of Chemical Engineering Pennsylvania State University University Park PA 16802 Ku C H P H Johnson P Batten P Sarathchandra R C Chambers P M Taylor M H Yacoub and A H Chester 2006 Collagen synthesis by mesenchymal stem cells and aortic valve interstitial cells in response to mechanical stretch Cardiovascular Research Cardiovascular Research 71 3 Aug 1 548 556 Lee AA Delhaas T McCulloch AD Villarreal FJ 1999 Differential 48 responses of adult cardiac fibroblasts to in vitro biaxial strain patterns J Mol Cell Cardiol 31 10 1833 1843 Li Yong Hu Zhibing Li Chunfang New method of measuring poisson s ratio in polymer gels Journal of Applied Polymer Science v 50 n 6 p 1107 1111 Nov 10 R M Nerem M Mitsumata T Ziegler 1992 Mechanical Stress Effects on Vascular Endothelial Cell Growth Biomechanics Lab and School of Mechanical Engineering Georgia Institute of Technology Rosamond Wayne et al for the American Heart Association Statistics Committee and Stroke Statistics Subcommittee Heart Disease and Stroke Statistics 2008 Update Circulation 2008 117 4 e25 146 Vesely Ivan Tissue engineering of heart valves Encyclopedia of Biomaterials and Biomedical Engineering 2004 1545 1558 Wang H Ip W Boissy R
12. way to interface with polyacrylamide to have strong substrate attachment e A method for curing and attaching the substrate to the stretch device The combination of each of these aims and tasks allowed the cellular environment to be subjected to controlled levels of stretch and stiffness 4 0 Alternative Designs 4 1 Feasibility Studies 4 1 1 Failure Testing of Polyacrylamide In order to determine 1f polyacrylamide gels could withstand the strains that the device would impose on them a failure test was conducted The objective of this testing was to see how polyacrylamide could withstand cyclic stretching of different strains and strain rates A 11 PA gel E 153600 Pa was attached to the Instron MTS grips by porous polyethylene sheets PE cured into each side as represented in Figure 3 The sample was cycled at 1 per second and easily reached a 5 strain but broke when the parameters were increased to 2 per second with a 10 strain this however was a result Figure 3 Diagram of a PA sample with PE grips of a pre existing tear in the failure area The test cycled 6 PA gels E 4800 Pa except this time the sample were mounted to the Instron hooks using small pieces of drywall sandpaper and small clips Although more difficult to attach the PA gels held up better because there was no place to easily rip on the grip edge Starting at just a 5 stretch at 1 per second the project team was able to eventually achieve a 40 stretch at 8
13. with multiple samples the risk of one sample becoming contaminated and spreading to the others 15 quite high However if each sample was separated then 1f one did become contaminated it would be an isolated incident meaning that the others would still be usable Another downside of such a design dealt with having a motor on only one side With such a case 1f there was any sort of friction the sides would not move egually meaning some samples might stretch differently than F SSL AM others Figure 17 Moving well Alternative Design The model shown in Figure 17 was created by trying to compensate for the downsides of the previous model In terms of the interface between the samples and the device hooks are still being utilized One difference to this design 15 the system of wells In order to prevent cross contamination of samples individual wells are being used This can all be connected as one unit or can simply be made up of individual wells which are placed next to one another Several steps were also taken in order to deal with the issue of friction One step taken was to adjust the way the rotational movement of the motor was translated to linear motion With this model 1t 1s the wells that are moving away from the hooks This 1s done by the use of a threaded rod or ball screw placed under the 29 center of the wells As these would turn with the motor it would cause the wells to move pulling them away from the hoo
14. 186 In W 0 0644 Ri 0 8875 A 0 31324 In W 0 2091 R 0 9144 A 4 6904W 8 825 R 0 9996 Verg 0 093 In W 0 3219 R 0 8875 Critical Values e W Area Critical Normalized Width o Theoretical Normalized Width that yields 1cm of Usable Area e Wei Threshold Strain Normalized Width o Theoretical Normalized Width where y 2 e Wc gt Absolute Strain Normalized Width o Theoretical Normalized Width where y 0 71 Appendix F Motor Controller Set Up and Programming Set Up The first step in interfacing with the controller 15 to download two programs The first 15 the Allmotion EZcommander program This can be found at http www allmotion com software_windows software_windows html This program is very user friendly and easy to learn The second 15 the USB driver in order to interface with the controller which can be found at http www allmotion com support htm A useful tool to have as well 15 the guide for programming the controller This 1s titled the Command Set for the EZHR17EN which can be found at the same site Once these are downloaded and installed open the EZcommander program Programming The best way the team found to understand the coding for the controller was to break down sample codes 1gP50000M1000D50000M1000G10R lt CR gt All the codes for this controller must start with a Then after that the lowercase g means that the program will repeat and that this
15. 6 Figure 13 Toothless Clamp The design in Figure 13 uses pressure and friction in order to hold the sample in place This clamp works by placing the sample along the bottom then folding the top down The two side clips then clamp down tightening the clamp making 1t hold the sample This was a simple concept however the team was nervous that it would not be secure enough in order to hold the sample Figure 14 Toothed Clamp The first clip design was a modified technique of what was being used with the hair clips By flattening out the clip and tailoring this idea specifically for our samples the gripping process would prove much easier Figure 14 When closed this grips teeth would puncture the sample and then proceed to the corresponding whole This clip can then easily be attached for stretching through the bracket on the back One downside of this design 15 in ensuring that both ends are clipped in the same manner If one side 15 clamped straight on while the other has a slight angle it would cause unegual stretching thereby throwing off the results 27 Figure 15 Shaped Tooth Clamp By making a slight alteration the design in Figure 15 uses the same idea of a toothed grip however this one would provide more consistent clamping The toothed section has been cut into the clamp This means by placing the sample against the back of the cut section you guarantee that it 1s straight on and the same as other samples Th
16. DN 0 0 5 1 15 Usable Area cm Figure 12 Usable Area Assessment It even begins to exhibit strip biaxial behavior With that said the samples should have an aspect ratio close to 1 11 5 as to not waste media However some other constraints make it necessary to make the samples a little larger than the minimum to increase ease of use and ensure reliable data from the end device This includes a 1mm offset from all edges to account for the presence of edges effects Also as samples needed to be seeded with cells extra usable surface would be beneficial Because of this as well as the rest of the data in this section the project team has chosen to deal with samples that are 0 5 x 6 cm with a thickness of 1 5 mm With this parameter determined the overall size of the device can be minimized to ensure the most efficient use of space on an 1ncubator shelf 4 3 Conceptual Designs The project team had several ideas of how to attach the stretching device to the samples of polyacrylamide One of the first ideas was the use of clips Previous experiments done using polyacrylamide used a combination of drywall sandpaper as well as small toothed hair clips The team found these were hard to manipulate onto the samples Even once they were put on it was even more challenging to get both sides to be symmetrical to yield accurate results For this reason the team designed several clips which they felt might make this process easier 2
17. Grood ES 1995 Cell orientation response to cyclically deformed substrates experimental validation of a cell model J Biomech 2 12 1543 1552 Wang JH Goldschmidt Clermont P Wille J Yin FC 2001 Specificity of endothelial cell reorientation in response to cyclic mechanical stretching J Biomech 34 12 1563 1572 Wang JH Goldschmidt Clermont P Moldovan N Yin FC 2000 Leukotrienes and tyrosine phosphorylation mediate stretching induced actin cytoskeletal remodeling in endothelial cells Cell Motil Cytoskeleton 46 2 137 145 Yang G Crawford RC Wang JH 2004 Proliferation and collagen production of human patellar tendon fibroblasts in response to cyclic uniaxial stretching in serum free conditions J Biomech 37 10 1543 1550 Yeung Tony et al Effects of Substrate Stiffness on Cell Morphology Cytoskeletal Structure and Adhesion Cell Motility and the Cytoskeleton 2005 60 24 34 Yost Michael J David Simpson Kimberly Wrona Stephen Ridley Harry J Ploehn Thomas K Borg and Louis Terracio 2000 Design and construction of a uniaxial cell stretcher 49 Appendix A Interview with Professor Billiar What are the specific functions this project must obtain My current today 1s strip biaxial stretching it 1s going to be I think relatively straight forward and be able to do experiments more short term equibiaxial 1s a lot harder how to attach things 1f it breaks get uniaxial Eguibiaxial systems exist but hard to wo
18. Polyethylene Wide x2 Porous Polyethylene Narrow x2 Polyethylene Block Glass Backed Grip Arms x2 Casting Well x2 Locking Washer Guide for Set Up Autoclave necessary parts a Case A Lid N Arm B 2 Chambers C and 2 Locking Washers M in one bag per case b Well kits of parts G L in one bag per well kit Insert Casting Wells L into Stretching wells G so that they lie flush to one another Fix the narrow Polyethylene Grip I to the glass slide with a small amount of Silicone Adhesive Position grip so that it is pressed against the long glass wall of the Casting Well Place into Well Slots in Case A NARROW POROUS PE GRIP FIXED SEE FIGURE BELOW STRETCH ARM Tighten Locking Washer M down over every pair of wells Press PE Block J into the hooks in Grip Arm K until it touches the surface of the arm Glue wide Polyethylene Grip H to the bottom of Polyethylene Block J Insert the end of Sliding Arm B through the holes in Case A Tighten 4 Set Screws E through Transition Chambers C to lock Arm B in place 9 Attach Grip Arms K to threaded standoffs on Arm B with hex nuts 10 Pre soak Polyethylene Grips H I with uncross linked liquid PA and place entire unit in bell vacuum for five minutes Discard excess fluid 11 Add 2000 uL of cross linked liquid PA and place in bell vacuum for ten minutes 12 Remove Casting Well L glass cover slip and an
19. Project Number KLB 0801 Design of Device to Stretch Tunable Stiffness Substrates for Cell Studies A Major Oualifying Project Submitted to the Faculty of In partial fulfillment of the reguirements for the Degree of Bachelor of Science In Mechanical Engineering Submitted by Andrew Kenoian Derek Pepicelli Ryan Rasmussen Approved Prof K L Billiar Advisor April 30 2009 Table of Contents PADI eU ar ur CD eee a Or AA 3 TA AK ied EE EE EE 6 ADS assets CH AA AA DIN 7 e E ROVE saei idee too uds o6 iapiaueie idea onde Menta A munimen Qranteue piu 9 2 Stretehime Withini the Body oui oe ibi 9 2 2 Replicatimg cellular response v5 90 aq paio oda etas op MIR bani D Ra itane miM td 10 2 0 Project ir dte Yin vies teri Mio da YD elia oli 14 Sil Initral Chent Statement nella 14 3 2 Objectives Functions and CONStraints a 14 55 Revised Probl mi statemen ae A AA FO Ea 17 A LG lello 17 SALA 17 3 2 Spero Arms and TasK amp ceu i lena 17 ZO AN DES lai 18 SU sais uth Steeles a dda O 18 4 1 1 Failure Testing of Polyacrylamide sonia iii ld eii 18 4 1 2 PE Mesh as a Gripping Alternative iii sc 19 4 1 3 Preliminary Validation of Squat Stretching Method 20 4 2 Sample dize Vaidai E 20 4 21 D termimauon of Sample IZ ii 20 4 2 2 Finite Element Model of Polyacrylamide 20 4 2 5 Modeline Umaxal St
20. The aim of this project was to design and validate a device to cyclically stretch human cells on tunable stiffness substrates to enable the study of these two mechanical stimuli simultaneously FEA indicated that squat stretching should yield near pure uniaxial behavior Polyacrylamide PA hydrogel was utilized as the compliant substrate for tissue culture in a temperature controlled sterile environment Testing verified that PA gels have sufficient durability in squat configurations and can reach 20 strain at rates up to 10 sec This device represents the first method available for mechanobiological studies into the response to combined stretch and stiffness stimuli 1 0 Introduction Over 100 000 heart valve replacement procedures are performed in the United States every year as a result of a variety of different valvular diseases Rosamond ef al 2008 Vesely 2004 These conditions can often go untreated for years but may result in structural degeneration causing congestive heart failure and thromboembolism which could possibly lead to stroke 1n extreme cases Bender 2002 With these risks 1t 1s 1mportant to more completely determine the mechanical behavior of heart valves and the effect this has on cellular expression in order to create new and safer replacement options Valvular interstitial cells VICs perform multiple functions within the heart and are able respond to changes in their mechanical environment These reactions include c
21. X 860542 1 1 UY Strain FAN Noncommercial Use Only gt AN Noncommercial Use Only OCT 30 2006 21 45 54 61 Ratio 1 2 MODAL SOLUTION aha HUE a AVG BSWS 0 DMX 005015 SMM 056294 SME 34701 _1925 NODAL SOLUTION _ AVG 1732B4 082 1 2 UY Strain _ Noncommerc ial Use Only r 30 2006 x 21 58 01 ial Use Only a 22 06 18 62 Ratio 2 1 NODAL SOLUTION STEE 1 I EXE J SUB 1 y RE AN TIME 1 EPTOX ave Noncommercial Use Only R3Y3 DO 002643 052751 4643264 OCT 30 2008 22 18 26 HODAL SOLUTION JIEE 1 JUB 1 ma TIME 1 dl Noncommercial Use Only R3Z3 0 DE 002643 i 22 24 10 SMW 254652 JMX 5587 65 OCT 30 2006 1 Gm Wm 254652 lt 08 D 1 2 1 UY Strain Ratio 1 3 NODAL SOLUTION 3TEE 1 3 VI SUB 1 Z Yum Noncommercial Use only FT OCT 30 2006 003003 22 40 46 123301 26352 HODAL SOLUTION STEE 1 se j 1 A n 306 1 a A TIME 1 di deg Noncommercial Use Only lt i OCT 30 2008 E eee 22 43 24 dMH 11773B SME 1B6B183 1 3 UY Strain 64 Ratio 3 1 HODAL SOLUTION 3TEF 1 EN FX M SUB 1 7 Z MN TIME 1 dn Noncommercial Use Only R3Y3 i OCT 30 2008 Dex 001096 22 49 16 SMW 032535 ME 323522302 032939 NODAL SOLUTION STEP 1 SUB 1
22. Y Y Ynon 32 Figure 23 Second Generation Threaded Rod Prototype esseeessesee 33 Eisure 24 StepperCan Stack MOL eeh 36 Figure 25 Linear Ee ee EE ow Figure 26 EZHRI7EN Stepper Motor Controller sees 37 Eisure 27 Well CODD cir aon o lle 4 Eistre 25 Drvne Mechanis Mis 4 Hu O Boag ered Gc Creer cca 42 Figure e e Te eo ues 43 Figure 31 Electronics ContieuratiOn oia 43 Figure 32 Final Cyclic Stretch DEVICE ai 44 Figure 33 ital Prototype A baa naa 45 Table of Tables Table d Project DISC CS ns iia 15 Table 2 Project PUNCHONS una 15 Table Pro ec EC Ons sesion NC lane 15 Table 4 WershiedObjecive Tree a dd 16 Table o ModelCharaeterstes siii 21 Table 6 Stretching Arm Material Selection nn 34 Table 7 Case Materials ele cOn 35 Acknowledgements The team would like to thank the following individuals for their respective contributions to our project e Professor Billiar for giving us this opportunity and for his guidance and wisdom e Angela Throm for sharing her expertise of cell studies and polyacrylamide e Andrew Capulli for his tireless efforts with gel casting e Benjamin Lessard for his help with CNC machining e Jeremy Skorinko for his efforts with the HDM analysis of the gels e John Benton and John Manero for their assistance with the project s electrical components e Jaco Inc for donating their services to the manufacture of the slide arm Abstract
23. ach one having its own properties It was determined that polypropylene would suit the needs the best mainly due to its chemical un reactivity as well as high temperature resistance 34 Polyester Table 7 Case Material Selection Polystyrene Translucent w Polyetherimide Translucent w Polypropylene Translucent w Polysulfone Translucent Clear w no tint white tint yellow tint white tint Translucent Amber Lowest Temperature 99 1 F 0 60 F 99 1 F 0 60 F 199 100 F Highest Temperature 100 200 F 100 200 F 301 400 F 201 300 F 301 400 F Operating Temperature 30 150 F 40 148 F 32 210 F 150 320 F Yes but for only a few Autoclavability Yes Yes Yes Yes cycles Expensive No No No No Yes Additional High Energy Chemically un Stability at high Comments Absorption Limited flexibility reactive temperatures High Can compress in temperature Resistant to oxidizing autoclave resistance agents Not resistant to organic solvents 4 5 Design Decisions 4 5 1 Motor Selection With the selection of the final design and controller coming together the project team needed to select a motor that would connect to the threaded rod When selected a motor the project team knew they would be choosing between a servo motor or a stepper motor A brushed D C motor would not work for the application because 1t only rotates in one direction unless the current from its power supply 15 alternated Servo and stepper motors provide a m
24. ain pattern Figure 7 and limits the amount of homogenous area To more closely model strip biaxial elongation more cl O E D1 ESB 195 a 205 21 1925 1975 2025 2075 Figure 7 Lateral Strain with Hooks hooks would have to be added to the sample It can be seen that as the number of hooks increases the amount of usable area reduces significantly It 15 because of this and perhaps more importantly design feasibility that hooks were discredited as method of creating strip biaxial stretch 4 2 4 2 Squat Stretching Method The method of squat stretching employs the Poisson Effect to attain near strip biaxial conditions In this situation the smaller dimension of a long thin sample 15 stretched Figure 8 Because of the length is so large as compared to the width the of lateral edge if properly constrained causes homogeneous and predictable local strain Figure 8 Squat Stretching Configuration that is very close to the overall strain The longer the sample gets the closer the transverse strain gets to zero as it gets further and further away from any curved edges that could cause fluctuation The edge effects Figure 9 of this configuration make up so 23 little of the overall area that the vast majority of the sample is usable This proves to be a suitable method to precisely control the transverse strain values to ensure near strip biaxial conditions UNUSABLE UNUSABLE 329977
25. ally stretch a rubber band using the drill as a motor Figure 23 Second Generation Threaded Rod Prototype 4 4 Design Calculations One of the first material issues dealt with was that of the polyethylene being cured in to the polyacrylamide Past work showed that it cures in effectively however with the strain being put onto the polyethylene the interface between that and the polyacrylamide must be strong There were two options of what type of polyethylene to use The team initially thought that the polyethylene mesh as seen in Figure 4 would work better than the previously used porous polyethylene sheet in Figure 3 After mechanical testing of both scenarios it was found that the polyacrylamide cured into the mesh was not strong enough to handle the strain put onto 1t The polyethylene sheet however was able to hold up to 57 stretching This is when it was decided to use the sheets over the mesh 33 Due to the specific environments which the device would be subjected to the materials used would be crucial One example of this 1s the fact that cells will be contained within the device This means that the internal structure of the device must be sterilized in order to not contaminate the samples The most common way to do this 15 to use an autoclave machine What this does 15 use high pressures and temperatures to kill any contaminants present This was one of the major factors in finding an appropriate material One part this dir
26. and used for a relatively low cost The following section details the last design decisions by subsystem but does discuss specific dimension To view these and other part characteristics see Appendix D 7 1 Curing System The polyacrylamide samples will be cured and stretched in the same well which allows for the samples to make it to testing with the least amount of damage possible The wells are efficiently designed with little wasted space to not only save material costs but also to allow for the largest number of samples to be stretched on one incubator shelf The wells themselves as seen in Figure 27 have four walls made of polypropylene with a glass bottom The glass bottom serves two purposes Firstly it lets 40 the polyacrylamide be cured directly into the well as polyacrylamide cures well when surrounded by glass Secondly DELRIN GRIP ARM POLYETHYLENE BLOCK POLYPRO WELL PA GEL W POROUS PE GRIPS GLASS SLIDE Figure 27 Well Configuration glass allows the wells to be placed under a microscope which 15 important to the future applications of this device A clear polyester lid was also added to each well to aid in monitoring of the cell cultures The porous polyethylene grips have a block of polyethylene glued to them that in turn are fixed to the delrin grip arms via steel hooks During well transportation these arms are fixed so that the gels only see strain once the
27. ay that would not harm the cells However it seemed this adhesive would wear overtime and made our wells frequently leak Having a stronger more reliable adhesive that would not harm the cultured cells would prevent any similar problems from occurring again More working space between wells would make curing polyacrylamide much easier When the stainless steel arm was originally designed and built the project team wanted to be able to fit as many samples as possible into the case while still Keeping it a reasonable size After necessary redesigns of the model the user 1s no longer able to remove the wells once the stretching arm 15 put into the device and the PA 1s cured This makes removing the casting wells more difficult because the spacing between each stretching arm 15 exactly the same size as the width of the wells 46 Improving the well lid covers will improve the sterility of the device and would allow the cell experiments to run for a longer period of time Currently the lids only cover approximately one half of the wells leaving room for the stretching arm to move cyclically Creating a lid that could cover the entire well while moving with the stretching arm would be most effective 47 9 0 References Atance J M J Yost and W Carver 2004 Influence of the extracellular matrix on the regulation of cardiac fibroblast behavior by mechanical stretch Journal of Cellular Physiology Journal of Cellular Physiology 200 3
28. crylamide gel 6 which has mid range stiffness The physical characteristics of PA gels vary with measurement technigues but typical values will be used for this experiment A Young s Modulus of 4800 Pa Engler ef al 2004 and a Poisson s Ratio of 0 35 Li ef at 1993 will be used as these values are the close to the average of values available in literature 4 2 3 Modeling Uniaxial Stretch Once an accurate material model was determine preliminary tests were run to verify 1f this model returns results that are typical of isotropic materials under uniaxial stretch The most satisfactory attempt to model uniaxial stretch 1s pictures in Figure 5 Here the sample 15 elongated a total of 20 along its width by displacing each vertical edge by 10 of the original width It was determined that this method yields identical results to holding one edge fixed and displacing the opposite edge 209o of the original a A a KE EEN Figure 5 Stretching Parameters width This was a key finding to simplify the design process To ensure pure uniaxial stretch the corners of the samples were constrained to only move in the lateral direction This assure that the entire edge 1s displaced the full 2090 21 The aforementioned parameters were applied to a 2 x 3 cm ANSYS sample with a 0 25 mm mesh size to gain a high resolution The total mechanical strain in the lateral direction was plotted Figure 6 and examined This plot shows a substantial region Ye
29. e top plated would then come down to ensure that the sample stayed in place With this as well as the previous model the problem of tearing was discussed By having the teeth dig into the samples the chance of tearing increases which would mean a ruined sample Figure 16 Gear Rack System Alternative Design One of the earliest models created utilized a gear rack system in order to convert the rotational movement of the motor into linear motion Figure 16 This would be able to be created simply by attaching a gear to the shaft of the motor and placing a gear rack on the edge of the slide This slide would have hooks attached on the end which would drop into the bath On the opposite side also dropping into the bath are fixed hooks attached to the wall This means as the slide would move the hooks attached to them would pull one side of the sample while the other end would remain fixed This means that it 15 the hooks that are moving and not the samples This type of device would work 28 primarily for samples which are being stretched parallel to the samples longest side One of the major advantages of such a design 1s its simplicity Very little machining would have to be done in order to create the parts Also in terms of moving components there are so few it would be easy to troubleshoot if there was a problem However there were also several downsides to such a design One of which dealt with contamination By having one large bath
30. e aspect of the motor that needed to be validated specifically was its precision Since the device is only stretching a small amount if the motor 15 not precise it would greatly affect the results of the project So in order to measure the displacement of the linear actuator a digital dial indicator was used The Mitutoyo Absolute dial indicator used was accurate to one thousandth of a millimeter The motor was able to move 1ts desired distances to within 0 5 This was well within the tolerances of the device Another validation test conducted was that of the heat given off from the controller The entire device needs to be in an incubator which 15 a very controlled environment If the controller was giving off a lot of heat then this could alter the environment and 1n turn alter the results of the experiment By using a thermocouple the team analyzed the heat given off by the controller It was found that the temperature ranged between 20 25 or just around room temperature after a day of running continuously 6 0 Discussion The overall objective of this design project was to design and test a device to cyclically stretch a soft substrate in a tissue culture temperature controlled and sterile environment While there was many design difficulties along the way the project team believes they were able to successfully complete the client statement given to them The device built 1s able to stretch eight samples of polyacrylamide simultaneous
31. e distance needed Being low cost and spatially efficient the linear actuator motor proved to be a perfect choice for the application 36 e w Figure 25 Linear Actuator Motor 4 5 2 Controller and Driver Selection While deciding upon a motor the project team was also researching what controllers and drivers were available to govern it Engineering catalog websites were consulted for different controller companies The project team researched the product line prices and help support with each individual company until the company All Motion was decided upon All Motion had a very user friendly website with a Help Desk to submit questions when having difficulty with the controller After explaining the proposed device to the company s Help Desk the project team received a timely and helpful answer on what model to choose and why This exceptional customer service helped finalize the decision The model chosen was EZHR17EN Stepper Motor Controller This controller was one of the higher end models All Motion offered It could be programmed to all the motions the project team desired included a sinusoidal wave motion Most 1mportantly it was also capable of stand alone operation with no connection to a PC needed Once delivered the project team was able to set up the controller and having it working in just a few hours 1 firm Ea Mag na Fer E di na ne a D IL LS Figure 26 EZHR17EN
32. e to stay sterile for three days objective as long as possible be durable enough to handle a week but 1f it can only handle a day well have to do experiments in a day but 1f that s the limit of the stuff Is 1t the attachment or the material gets stretch out can we do something about it or put a backing on 1t then we have to deal with its limitations then we could look at PEG I have a college at Georgia tech we have all the materials and he does 1t all the time so attaching cells will not be a problem 1f you could get it stretching he can give us the surface chemistry to get it going the polyacrylamide has had all sorts of problems with it maybe peg can be stretched when you learn how to make polyacrylamide you cane make some peg to and just play with them and get them to be the same stiffness and pick one If you have to make a bunch 1f there s an easier way to do within the constraints of the problem Might have to precycle the material to avoid plastic deformation while cells on 1t 32 Fluid stresses will affect growth of cells could use baffolds to break up fluid movement Anything contacting tissues needs to be sterile the polyacrylamide can t be sterilized not a sterile system What if you could use magnets have magnets outside metal inside sterilized and little posts of how far it could move you turn it on and the thing inside 15 totally sealed and 1ts Just the magnet going through the wall moving the way you want 1t no
33. econd which 1s well beyond the necessary parameter 4 2 Sample Size Validation 4 2 1 Determination of Sample Size In order to determine an effective scale for the device is was necessary to first determine the size of the samples that will be stretched The finite element analysis program ANSYS was used to determine an accurate model for polyacrylamide evaluate load patterns to replicate stretch modes and to arrive upon a sample size with sufficient usable area and near strip biaxial conditions 4 2 2 Finite Element Model of Polyacrylamide To correctly determine the nature by which polyacrylamide sees strain an accurate model of the material must be made in finite element software These parameters outlined in the below table determine such factors as the dimensions of the sample its stretch nature as well as how the software interprets its results For the purposes of this project it was necessary to model the samples as membranes with minimal thickness to closely mimic the shape of the samples generated in the lab A 20 solid element type was chosen and given a thickness of 1 5mm as this 15 the easiest Table 5 Model Characteristics Element Type Solid Ouad 4node 42 Behavior Plane Strs w thk Material Model Structural gt Linear gt Elastic gt Isotropic E 4800 Pa v 0 35 thickness to make in the current lab conditions To approximate the mechanical properties the project team decided to use the data for polya
34. ectly affected was that of the slide arm It also had to withstand the stresses of cycling and be strong enough that it would not deform for this would cause the cells to stretch non uniformly For these reasons it was decided that steel would be used to create the arm However there are several different types of steel as can be seen below in Table 6 One of the main reasons 316 Stainless Steel was used was because 1t 1s considered Surgical Stainless Steel meaning it 1s easily sterilizable It also has the best corrosion resistance of all the steels Table 6 Stretching Arm Material Selection 303 Stainless Steel 304 Stainless Steel 316 Stainless Steel Corrosion Resistance Low Excellent Best of all Steel Weldability Poor Good Good Best for flat rolled Additional Comments Free machining version Most common grade product Not produced in flat rolled product Good for being drawn Surgical Stainless Steel Once the device 1s ready to run it will then be placed in an incubator meaning that it will then be subjected to controlled temperatures humidities and other factors If the casing would deform when brought to high temperatures then it would be useless This material also had to have the basic capabilities of being relatively inexpensive as well as strong enough to be structurally sound Included with these factors 1s again the ability to be put into an autoclave machine There were several plastics which were looked into as seen in Table 7 e
35. f design attributes would then be divided into project objectives functions and constraints Pairwise comparison analysis was then completely to prioritize these objectives Finally a function means tree was created to graphically represent the primary and secondary functions of the design Once completed these guidelines were used to begin developing alternative designs The section discusses the preliminary procedures to developing our design attributes to eventually create a revised client statement 3 1 Initial Client Statement The client presented the project team with the following preliminary project statement Design and test a device to cyclically stretch a soft substrate in a tissue culture temperature controlled and sterile environment In order to clarify this statement background research was conducted This included but wasn t limited to scientific journals previous Major Qualifying Projects and existing patents As a result of the question raised by this research a secondary interview with the client was conducted to clarify the questions of the team Transcript in Appendix A This interview helped to create a list of design attributes which could then be formed into objectives functions and constraints to help create the revised problem statement 3 2 Objectives Functions and Constraints The first step in the design process was to determine the requirements of the design and separate them into objectives wha
36. f stretching 15 better for one particular end result while another 1s better for some other desired end One example of such a test was performed by Yang et al 2004 and involved human tendon fibroblasts Researchers stretched these cells uniaxially over a range of 4 8 at a frequency of 0 5 Hz for 4 hours It was found that under these conditions the cell proliferation increased as did the type I collagen gene expression and the protein production The team discovered that the increase of these properties was directly related to the stretch magnitude They subjected the same material to biaxial stretch Here it was found that it was not the magnitude of the strain that determined the final properties but rather the strain rate This shows that different modes of stretch affect the cells in different ways and by different factors He et al 2004 conducted another experiment examining similar phenomenon while testing peridontal ligament fibroblasts Here the team was looking to determine if tensile strain testing would affect the cells differently than compressive testing In the first case the samples were stretched biaxially 10 for 24 hours Upon examination it was found that the fibronectin content increased five fold while no difference was found in the presence of type I collagen from that of the unstretched control sample However when the sample was compressed in the same manner it was found that it had radically different effects The Ty
37. hanges in morphology size shape orientation etc and cell expression and can be affected by factors such as stretch direction strain percentage and the freguency of stretch Butcheret al 2006 To test these phenomena in vitro cells are stretched on a pliable substrate The stiffness of this medium can also cause morphologic and phenotypic changes in the cells Yeung ef al 2005 It is clear to see that while stretching cells in vitro that there many variables and a wide range of combinations thereof Currently there are no devices available which can test these multiple permutations of these variables simultaneously effectively and at a low cost The primary goal of this project was to design a device to cyclically stretch cell cultures on pliable polyacrylamide PA substrates PA was chosen for 1ts range of stiffness and reputation for favorable cell adhesion This device will replicate in vivo stress that VICs would typically undergo and accommodate multiple samples These samples can have different stretch parameters as well as varying substrate stiffnesses to gain a wider breadth of data from one test In addition to stiffness variable parameters will include strain percentage cycle freguency strain pattern and stretch modality The device 15 able to function in an incubator for an extended 3 7 days period of time to allow for complete contaminant free data With the wide range of permutations that can be tested on this device in ju
38. hat stretched with it and the media was Just within that area then you could use 1 ml and do the test and do the whole test and do each one independent if you had 5 in a bath I L each one 1s taking 200 ml of everything else 15 in the bath and has a chance of getting infected Each sampled use less than 10 ml of media What is the consistency More like soft jello to stiff jello if you put too much water in the jello or you left it out in the fridge and the top layer 1s stiff were up to that its that same goopy when you make 1t soft so its kind of hard to hold on its more like soft jello So if you do reology in that you take a simplest one is a parallel plate and it oscillates and it measures shear stress and strain and you calculate stiffness but when ins hear its shear stiffness g there s g prime and g double prime g prime 15 the elastic component g double prime 15 the viscous component so if something 15 liquid it is more g double will be high if more elastic then g prime will be higher It usually changes as frequency changes so something that 1s pretty liquidy when you cycle it fast it acts more like an elastic it doesn t have time to flow with fluid you ll see the stretch 15 proportional to the strain rate not to the actual strain so not elastic at all You should go make some with Angie You need to go in there and play with the stuff with Angie I didn t even think about the volume before that would be a very beneficial design t
39. he autoclave can cause some plastics to warp or fracture not optimal for a device that would need to be autoclaved before each use Plastics such as polypropylene polyester and delrin could withstand such use 5 0 Design Verification 5 1 Well Verification In order to move forward with the design the team needed to confirm that the newly created well system would work In past experiments the gels were cured vertically within glass plates This new system has them being cured horizontally which had never been done before In order to test this the team created a test well made of glass slides as seen below Then in creating the gels are the same steps were taken as 1f 38 we were curing them horizontally The test was successful in that the gels were created and displayed the same properties as gels made 1n other technigues This meant that the team could continue with their design based around horizontal based wells 5 2 Motor System Verification One of the main aspects of the motor system 1s that it must be durable The device 1s designed to run for 3 5 days in the incubator So one of the first tasks was to ensure the motor and controller could run for that long without any problems In order to test this the team tested the motor and controller cyclically for two days The team applied a small load to the motor and had it run for two days It was found that both the controller and the motor were able to handle this load On
40. he design The top level of the tree begins with the functions that need to be met with each succeeding level having primary and secondary functions to complete the top function This graphical representation helps note which functions would be common to all possible design alternatives or would be specific to just one design Lastly a pairwise comparison chart was created using the project objectives to prioritize the importance of each objective Professor Billiar Angela Throm one of the end users of the device and the design team weighed each of the objectives The results of this comparison can be found in Appendix C This ranked the objectives highest to lowest as follows Effective Reliable Durable Easy to use Inexpensive 16 3 3 Revised Problem Statement Once all objectives functions and constraints of the design were established and organized the project team was able to further clarify the initial problem statement Using the analysis described above the revised problem statement was expanded to Desien and test a device to cyclically stretch soft substrate strip bi axially in a tissue culture temperature controlled and sterile environment This method should be able to apply a 20 25 strain and allow for adjustable strain increments of 5 Additionally the device should have an adjustable strain frequency between 0 1 and 2 0 Hz and be able to apply strain in different types of waveforms This statement highlig
41. hts the most important objectives functions and constraints of the design and gives specific numbers that must be considered when creating design alternatives 3 4 Project Approach This section identifies the approach and development of device which will stretch polyacrylamide samples of varying stiffnesses strip biaxially All assumptions made in the approach and methods for developing the final project statement and for reference at the conclusion of the project are identified Specific aims and tasks are discussed to outline the guidelines and constraints used to determine what the project ultimately accomplished This was creating a device which was able to control levels of strain and stiffness of polyacrylamide samples 3 4 1 Assumptions In order to develop our method the project statement was simplified using several assumptions One of the preliminary assumptions was that the cells attached to the substrate are subjected to the same strain percentages and patterns as the substrate This assumption would then later be verified during validation The polyacrylamide was also assumed to be a flat isotropic and homogenous material in order to simplify analysis relative to changes 1n stretch stiffness 3 4 2 Specific Aims and Tasks Completion of specific tasks was required in order to develop a device to control strain on various stiffnesses of polyacrylamide These tasks included 17 e Selecting a stretch type e Creating a
42. iability in different experiments Based on the size of the incubator shelf up to four devices could be run off of on motor and with the motor controller s ability to control multiple motors at once it is possible to conduct experiments with upwards of thirty samples Figure 32 Final Cyclic Stretch Device 44 The final device met or exceeded the preliminary specifications put forth in the client statement and in that regard it 15 a success With a completed design in hand prototyping must occur to validate the various subsystems and the device as a whole ns wi Figure 33 Final Prototype 8 0 Conclusions and Recommendations 8 1 Conclusions A device to cyclically stretch polyacrylamide gels for extended periods of time was successfully designed While the device 1tself still needs some validation the project team 15 confident that upon testing all subsystems will perform satisfactorily The device met the key functions as set forth by the client statement and all constraints were accounted for Cyclic strains can be applied to gels in such a way that will not tear and will allow for favorable cell growth This along with the high number of samples that could possibly be run at one time makes this device 1deal for the types of experiments that it will be used for Before experiments can be conducted however the device needs further validation of the actual strains the device applies to the cells The project team 1s
43. ifferent types of stretching on different types of cells Some studies have even the examined the effects of different strain rates on the same cells However by studying the research of other experiments it can help show what sorts of effects to look for Among these experiments some of the most common results dealt with cell proliferation Extra Cellular Matrix gene expression as well as protein expression Looking at these experiments previous it can clearly be seen which technigues worked best for each case In order for researchers to understand the types and magnitudes of mechanical forces to apply to cells they determine what occurs naturally This can be examined by conducting in vivo experimentation For instance in terms of strain the magnitude of force on a muscle cell will be much greater than that of a brain cell So by characterizing each type of cell and what sort of environment it 15 in researchers can much more accurately imitate natural conditions as well as expand on them One type of cell that research of this magnitude 1s lacking in 1s that of strain on valvular interstitial cells or VIC s These cells in vivo normally have a pressure gradient of about 80 mmHG With such a gradient this causes the valve leaflet to change in length in both the circumferential as well as radial directions This intuitively means that the strain 15 increasing as well However there 15 little data currently of the effects of altering the s
44. is the beginning of the repeating code The P50000 means that the motor will move 50 000 microsteps in the positive direction The M1000 means that after moving in the positive direction it will pause for 1000 milliseconds or 1 second before doing the next action The D50000 means 1t will move the motor negative 50 000 microsteps The GIOR means that the code 15 over and that it should repeat 10 times before stopping 1s0gV20000AP12480D1248 0G10R lt CR gt Below are some sample codes that the team put together throughout testing the controller With each one 1s a basic explanation of what it does Rotate back and forth with pause 1gP50000M1000D50000M1000G10R lt CR gt Save to controller when turned on rotate back and forth no pause 1s0gP50000D50000G10R lt CR gt Velocity control and movement 1V 50000P50000D50000R Send Home 1ZOR 72 Go 6 mm out 1AD5249R 1 hz stretch 20 backward first repeat 10 times 1V20000AP12480D12480GIOR CR Same as above w 3 second pause between each side 1V20000AP10498M3000D10498M3000G10R CR 73 Appendix G Polyacrylamide Curing Guide 74 Cyclic Stretch Device User s Manual for Two Samples Andrew Kenoian Derek Pepicelli Ryan Rasmussen Device Case Stretching Arm Transition Chamber x2 Motor Coupling Set Screw x6 Arm to Arm Coupling Parts List x x E U A T O H PF na W gt Stretching Well x2 Porous
45. ks In order to do this the wells would be placed on ball slides in order to assure friction free movement This device while having its advantages over previous models also had flaws in it One such flaw dealt with the contamination of samples Though the team did have individual wells for each sample while being in the incubator the system needed a way to cover it This would prove challenging because the hooks would be moving making a static cover hard to be successful Another issue dealt with having the wells move instead of the hooks The team was concerned that with the movement of the wells the medium within them would shift which could affect the experiment negatively Figure 18 Threaded Rod Alternative Design with Cover Figure 19 Threaded Rod Alternative Design without cover 30 The next generation prototype attempted to alleviate the flaws of the previous models Figure 18 amp Figure 19 In order to stop the issue of the medium sloshing in the wells the means of stretching was altered The team returned to the 1dea of moving the hooks relative to the wells instead of moving the wells themselves In this case however the ball screw 1s attached through the center of the slide which has the hooks protruding from it Again as this screw rotated it would move the slide on top of the ball slides thereby stretching the samples By using this technigue friction would not be a problem while the samples are stretched The othe
46. l strain r were related exponentially according to Equation 1 It is important to note that Central Transverse Strain vs Normalized Width Begin Strip Biaxial 11 5 Theoretical Zero 34 3 CentralStrain 0 10 20 30 40 Normalized Width Figure 11 Central Strain Data Analysis 1 r 0 086 In W 0 0648 the actual transverse strains are negative and should be input thusly however in the above graph they are displayed as positive By plotting this formula Figure 12 it can be shown that a sample begins to show strip biaxial behavior at a normalized width of 11 5 and should theoretically reach pure strip biaxial stretching at a value of 34 3 With these values in hand it was necessary to determine the most efficient use of area 4 2 6 Size Considerations Having the above definitions a final decision on the size of the samples needed to be made An ANSYS study Data in Appendix C of samples with various H Values and normalized widths was conducted to determine when a squat sample attains 1cm of usable area as defined previously Figure 9 In Figure 12 it is shown that a sample s H Value increases the sample reaches the desirable area more quickly which was expected It should also be noted that even the smallest H Value reaches 1cm of usable area before 25 nn r r Normalized Width vs Nominal Usable Area H 0 5 H 1 H 2 Normalized Width O e N O a O
47. llenges with all the models 1s the issue of covering By having moving components the way in which you arrange the system determines the covering system By enclosing the wells all within one unit as seen in Figure 22 a cover can be placed over the whole thing while all the moving components are self contained The motor 1s located outside which 1s connected to a ball screw This connects to a ball slide which in turn 15 connected to the slide This enters the unit through a small hole in the outside walls which also has a small bellow to deal with the slide moving As the ball slide moves horizontally it moves the ball slide in turn moving the slide This slide branches into the hooks which attach to the samples Inside the unit 32 at the front and back there are also ball slides which help alleviate the friction of the slide moving within the unit A second generation mock up prototype Figure 23 of the threaded rod design was created using two ball slides and a welded piece of steel A drill was attached to the threaded rod to simulate a motor to see how the movement of the threaded would move the entire device This prototype helped the project team visualize how the stretching arm would move cyclically The team also decided that a design without ball slides on each side of the arm would be more efficient It also helped bring attention to the possibility of a balance 1ssue along the arms Using this model the team was able to cyclic
48. llow Green 0 2025 0 205 that 1s homogeneous predictable and within the a 1925 1975 2025 2075 Figure 6 Total Lateral Mechanical Strain tolerances given in the design objectives Also the strain pattern 1s symmetrical about both the lateral and transverse midlines which shows that this 15 indeed a proper model of an isotropic material Having a valid material and stretch model identified a method of gaining strip biaxial stretch needed to be determined 4 2 4 Attaining Strip Biaxial Stretch There were two methods of possibly attaining strip biaxial stretch that needed to be tested The first was the application of hooks along the bowing edges of a sample and the second 1s sguat stretching Each of these was evaluated to determine 1f the method produced results that could mimic strip biaxial stretch An accurate method should be able to create a transverse strain of less 2 and ideally zero as set forth by the design criteria 4 2 4 1 Hook Method The hook method uses evenly spaced hooks to counter the Poisson Effect by keeping the edge being stretched in tension While this solves the issue of altering the strain in transverse direction 15 creates another problem longitudinally Because polyacrylamide 1s an 1sotropic material the Poisson Ratio 1s the same in any direction of stretch By pulling on the stretched edge the same effect occurs in the longitudinal 22 direction This causes distortion in the lateral str
49. ly with a 39 theoretical strain of 20 FEA analysis confirmed that the polyacrylamide would stretch homogeneously if the stretching region were the correct dimensions as discussed in Chapter 4 However the project team was not able to confirm the actual strains of the polyacrylamide due to lack of time and a corruption on the HDM computer The actual validation will be conducted by a biomedical engineering undergraduate during the summer of 2009 One of the major difficulties in designing this device was there need for extremely precise machining Most of the parts built had to be accurate to 0 01 inches The machining eguipment at Worcester Polytechnic Institute was not intended for such small accurate machining To overcome this the project group special ordered new wells and casting wells from a plastic machining company that could accurately machine parts to a tolerance of 0 01 inches The quotes have been submitted and the parts will arrive in time for validation in the June 2009 Overall the project was quite successful and even with the difficult machining the project team was able to produce a professional looking effective device to meet the client s needs The validation of each subsystem in the device is discussed in the following chapter 7 0 Final Design and Validation After multiple design iterations and compromises a final design was decided upon that would not only meet the needs of the client but also be easily made
50. m the outside environment into the cell culture environment Silicon sealant or plastic welding should be used to ensure that the case 1tself 1s sealed properly Though difficult Figure 29 Device Case the project team recommends machining the case out of one solid block as it produces more predictable results and a cleaner look The case also has a removable clear polyester lid which is gasketed to guarantee that minimal amounts of particles if any get into the culture environment An area of contamination concern in the case is where the slide arm enters the cell culture environment The project team originally sought to use bellows to fulfill this task but after an exhaustive search no bellows were found that met our parameters as well as 42 the size constraints of the device Because of this it was necessary to design a bellows like system to achieve this end The result is depicted in Figure 30 A short section of collared PVC tube is fixed around the opening in the case A thin membrane is fixed to the inside of this tube left with slack and a hole slit 1s cut into it The slide arm 1s fed through this and the hole is adhered to it in such a way to allow for sufficient motion of the device When the device 15 extended left side of figure the membrane 1s slackened and when the arm 1s at home position right side of figure then membrane 1s slightly Mm tensioned Figure 30 Bellow Replacement 7 4 Electronic Com
51. motors that starts being a very big thing it must be sterilized must have this functions of doing things but must be done in a aseptic way 50 Functions Means Tree Appendix B ITEM Ja AOTLIESCH f 2peugejq go ELI UI loggen To 4q0WOd Jeddays resur Jaddags oaJ spa pue NWI peue SIO OW SULY BAYS Joeamos STO UCD J paessa idu1on EO Tue qoe Jal SOI NeIp H Demand NGAGE 2081141 ost JUIEQUCD S 22 pens jere 1g dos Kucke SYO OI eue Ame A od 1193021841 dI SYOOHSUILYSIY IEMAIQ seus Sno y RUE UTES A BUDOAIJ lade g pues aux Apo Alog soe ayu dun neh aprue Aned od Eise 54 Appendix C Pairwise Comparison Charts Objectives Project Group Reliable X 1 1 1 0 3 Durable 0 X 1 1 0 2 Inexpensive 0 0 X 0 0 0 Easytouse 0 0 1 X 0 1 Effective 1 1 1 X 4 Objectives Professor Billiar Client Reliable X 1 1 1 0 3 Durable 0 X 1 1 0 2 Inexpensive 0 0 Easytouse 0 0 Objectives Angie Throm Client Reliable X 1 1 1 0 3 Durable 0 X 1 1 0 2 Inexpensive 0 0 X 1 90 li Easy to use 0 0 0 X 90 In Hehe 1 1 i i X a_ 39 Appendix D Dimensioned Drawings of All Custom Parts Slide Arm Case Well Walls Grip Coupling 56 FILL WOO 13NW3d WOW 9
52. mponents that contact the substrate must be able to be sterilized In order to determine which designs best fit our objectives the team assigned weighted these objective based on priority In this way it can be found which model fits best our overall concept and design parameters The most 1mportant objective was 15 determined to be the effectiveness of the device If the device itself does not work effectively or with accurate results then there 1s no reason to have it The purpose of this device 1s to provide accurate and precise results After this the most important objective 15 that of reliability The team felt it was very important that the device be able to give dependable repeatable results If the outcomes are not consistent from one test to another it will be difficult to determine the accuracy of the results The project team felt the remaining objective were all egually Important though lesser than the previous two While low cost durability and ease of use are significant objectives 1f the device 1s not effective and reliable the device would be considered a failure Table 4 Weighted Objective Tree Objectives Weight Sub Objectives Effective 50 e Accurate Results e Precise Stretching Reliable Durable o 0 o Inexpensive 10 e Minimize use of polyacrylamide growth factors amp cultured cells A function means tree See Appendix B was created to organize the primary and secondary functions of t
53. nd cure She has a lot of Knowledge you could use right away Again this stuff 15 porous so if you made a will out of it then put a well in there so underneath has to be media too 1f it 15 really soft it might just bow Optimized design based on finite element to find out what would be the shape of the pulling thing to get the largest homogenous stretch for size and make the bath as small as possible around that 15 going to minimize your volumes for everything you won t have to have much media above ore beneath it so these are all details Incubator you need to talk to Angie in term of what performs best metals that rust are not good but you need to sterilize things you are going to use more than once so you need to deal with what can be sterilized and Angie knows that and some things can be sterilized and if you do it too many times they degrade Polypropylene can be sterilized and doesn t react with any chemicals real soft Talk to Angie about it has to fit on the shelf in the incubator Minimizing size 1s critical stacking certain ways and being creative with the design No power restrictions Polyacrylamide it comes back to original size who does it cyclically no one it might be until 100 times then plastically deform have a silicone membrane stretching these things and they start waffling l a sec ten hours 36000 cycles 24 hours 80000 cycles a day a high strain this stuff might totally stretch out after one hundred would lik
54. nsating in order to avoid further strains Another of the major factors 1s that of the stiffness that the cells are adhered to This topic 15 one in which 15 currently being researched on its direct effects One such study focused on stem cells and how the stiffness of the substrate affects them Adam Engler at the Pennsylvania Muscle Institute have found that these cells are extremely sensitive to the stiffness of the substrate They found that Soft matrices that mimic brain are neurogenic stiffer matrices that mimic muscle are myogenic and comparatively rigid matrices that mimic collagenous bone prove osteogenic Engler 2006 Making 10 these two factors adjustable in the same experiment 1s something that has never been done before With the ability to study how these factors combined affect cells and their alignment new research can be done In vivo VICs undergo mechanical stretching in various directions including uniaxial biaxial strip biaxial and equibiaxial as illustrated in Figure 1 Uniaxial Biaxial Strip Biaxial Eguibiaxial N7 AS Figure 1 Examples of Stretching Directions Cellular response will vary greatly on the type greatly on the type of stretch that 1s applied to it Cell stretching devices available today in literature and commercially attempt to mimic the complicated mechanically stimulations that occur in vivo Biaxial stretching devices stretch cells along two axes perpendicular to one an
55. nsitive and accurate motor The more accurate of a servo motor however the more expensive 1t tends to be All Motion the company that manufactures the controller selected by the project group recommended that motors produced by Portescap worked very well with their controllers Using this information the project team called an engineer at Portescap and after explaining the application to them were told that an inexpensive stepper motors would work for the device After studying the products distributed by Portescap and following the advice of their engineer the project group decided to select a stepper can stack motor with a 26mm shaft The reason behind this decision was because it was very inexpensive and could be used to experiment with until the controller was fully programmed and properly working Figure 24 Stepper Can Stack Motor After several weeks testing the motor the project team decided they were unsure how reliable to stepper motor would be attached to the threaded rod Looking into other options for motors the project team discovered a linear actuator motor in Professor Billiar s lab at Gateway The motor was produced by the same company Portescap as the stepper motor previously used Therefore 1t was also compatible with the controller and driver already purchased from All Motion Using the linear actuator eliminated the need of the threaded rod and allowed the project team to bring the actuator shaft in and out exactly th
56. o have a limited volume for a lot of reasons The polyacrylamide 15 very goopy and when 1t gets soft it probably gets more viscous however it is considered by people that use it as elastic solid They re just real soft it s a fully elastic matrix just very soft And new would be made each time casting 1t it will not cure against plastic so 1f you make this neat little mold for it oxygen radicals will stop It from solidifying so between two pieces of glass it works very will in a vacuum or in nitrogen without any oxygen it will be much better we know much more about that now because we were trying to get it to attach to the surface and we get a nice gel and 1t slides around what you are trying to do is attach a liquid to something liguids don t attach they re not getting a good bond with he liquid under nitrogen we could get them to attach we could actually not put a glass cover slip above 1t and Just do it under nitrogen and get a flat surface you don t have to worry about taking the cover slip off and ruining the surface 51 You might just make one in between two pieces of glass pull off the glass slap it in there and grab 1t with grips and go and there s no problem at all or you might need to solidify it into something now that material 15 plastic and doesn t work then you do it and start stretching it and it comes off the grip she actually knows porous polyethylene material are very porous especially with the vacuum will suck in the pores a
57. other without shear stress Uniaxial stretching devices stretch in only one direction which creates a compression in the perpendicular direction of the cells To prevent this a strip biaxial stretch device applies a tension in the perpendicular direction that will prevent the Poisson effect from occurring An eguibiaxial stretch device applies uniform strain in all directions eliminated the variable cell orientation Yost 2000 Another similar experiment conducted by Wang et al 1995 sought to compare the effects of stretching compared to static conditions To do this smooth muscle cells were subjected to different strains The team examined the affect this would have on the orientation of the cells In static conditions the cells were randomly oriented with no pattern or uniformity Once stretched uniaxially it was found that the cells all aligned to form an angle 657 from the stretch direction As further research was done Wang and Grood 2000 the team found that the angle formed by the cells depended on the stretch magnitude It was concluded that a large number of cells when subjected to cyclic 11 stresses align in order to have minimum substrate deformation in order to subject themselves to the least amount of stress possible One of the more important variables being tested 1s the mode of stretching that the cells undergo Researchers are trying to determine 1f one of these modes benefit cells in any way or perhaps if one type o
58. pe I collagen mRNA decreased by two thirds and the fibronectin decreased by half The data from this experiment showed that even one variable change can lead to drastically different effects Other researchers took a step back from this approach and tested to see 1f the strain itself affected the results Lee et al 1999 kept all variables constant while allowing the strain percentage to change This would show 1f cells react differently when stretched to differing lengths One of these tests was conducted by stretching adult cardiac fibroblasts to different strains Initially the cells were cyclically stretched to 10 in the uniaxially It was found that the levels of type I collagen and Fibronectin mRNA tripled under this strain However when the team increased the strain to 10 it was 12 found that the amount of mRNA decreased compared to the levels from after the original test while the type I collagen remained the same This shows that even the amount of strain put on cells makes a difference in terms of how they will react to different stimuli By examining the different research it was found that there are many mechanical variables that can affect cellular properties By adjusting strain rate strain percentage and mode of stretch desired cellular results can be achieved With this being a relatively new topic the effect of mechanical properties on cell response 1s not completely known This uncertainty creates a particular gap in re
59. ponents The electronic components list of this device consists of the motor motor controller USB adaptor a computer for programming and the power supply These are configured as shown in Figure 31 The power supply is a 3 A 13 8 VDC supply which power the controller A Device USB Adaptor ne AC Input Ser Controller Supply Figure 31 Electronics Configuration The controller in turn 1s linked to the USB adaptor and powers the linear motor The adaptor allows for an easy interface between the controller and the user while allowed 43 the motor to run while unattached from the source PC To aid in the mobility of the device the wire from the motor was shortened and had a connector added This will connect to an extension cable which will then attach to the control case which includes the controller and adapter A shorter extension cable connects this controller box to the power supply which would be situated nearby These connections allow for the device to be easily transported in segments to avoid large amounts of excess wire 7 5 Design Evaluation By combing these subsystems the total device 1s shown in Figure 32 The small four well based design for PA gels to be cured seeded with cells and transported to the incubator without subjecting them with strains until the device begins its cycles With this design also comes the ability to run multiple test groups in different cases to allow for greater var
60. r issue which was addressed was that of a cover In this case the team felt that perhaps a slotted cover would work Though simple while placed on top of the wells it would prevent contamination while still allowing the hooks to move m Figure 20 Threaded Rod Alternative Design 31 One concept different than the others was to stretch the samples parallel to their shorter sides None of the previous model configurations addressed this 1dea for they all stretched length wise The model in Figure 20 though fundamentally similar to the others had some different features This concept has the stretching device simply be placed over the system of wells The backbone of the device branched off into side arms which had hooks These hooks would attach to the sample and coincide with fixed hooks which are located in the wells These side arms then attach to ball slides along the wells which keep the device moving smoothly As the ball screw moves it would move the backbone and in turn stretch the sample A steel prototype of this model was welded together and attached to four ball slides Using this model as a visual reference the project team concluded that this concept s major problem dealt again with the issue of covering By having the stretching occur directly over the wells it proves difficult to cover the samples to prevent contamination F Figure 22 Covered Threaded Rod Alternative Design One of the biggest cha
61. rel WEE 21 4 2 4 AttaiNins Strip Biaxial Strette insis 22 KIANA AA 24 ALO ZO CONSIGCEALIONS aue oe ee 25 Ad Conceptual DES cnu ita a aaa 26 4 4 Desi n Calculations nakak NG BAGAN GANA 33 ci 35 45 I NA GH pio tata anota oca Adr 33 T2 Controller and Driyer35eleclOb eat 37 L0 OpumizIlon si pono cre d ewe AR ober sede 38 2 0 Re EE TT EE 38 4o Material e ed ice 38 ISA o AA aio 38 UEM MN Crt CAV ON Y sah Sarat a FYN 38 GEHEESCHT ege 39 El ET EE 39 TUO Final Dest ena Valdaora 40 CARRO RR HAF UT 40 T2 Daing Mechas bado dsd 41 o EE iii 42 1A EBlectrome COMmponeniS ein a 43 RIDES Mile V ANU AMO lo 44 8 0 Conclusions and Recommendations 45 EEN A 45 a F ec onedd AA 46 Appendix A Interview with Professor Billiar 50 Appendix Eu Ee e Ee 54 Appendix C Pairwise Comparison Charts 55 Appendix D Dimensioned Drawings of All Custom Rate 56 Appendix E Emite Element Amala 60 AR 61 AA AA 61 Pe KG AA 62 Roo II O 63 FOE EEN 64 Roo lella 65 LES GL a M EE 66 ROA Label 67 a e a e dd 68 E A HR 69 IRC ii ila 70 BROS NUS sean sce ana 71 Appendix F Motor Controller Set Up and Programming
62. rk with Heart Valves go at very high strain rates and strains I would like to be able to go to 20 25 percent stretch 1f only fifteen and works all other ways but if you can go 25 percent that would be ideal for strip biaxial Do you want it to be adjustable in terms of the strain I would like it to be adjustable 5 10 25 20 25 and each one being plus or minus ten percent of their strain So if you are at 25 percent it is plus or minus 2 5 percent Then what if you are doing 25 percent strain and the other axis goes to 95 it s not zero its 5 percent That s 10 percent of zero so in that axis you want to be within 10 percent of your stretch axis so 1f you stretch to 25 then in the latter axis if you are within 2 5 percent As long as within the area 1t is within those specs you made it I m going to say a 1 cm squared area 1s what I want then to get those cells you are going to need five of theses to be enough so 1 you can go to five cm squared on 1 that would be ideal or for another assay that s fine so there we have to talk to her as a client because then you have a big five cm one 1t s a big thing now you can only have five but 1f their smaller you can have 25 of them 1f it s a square thing then she could pool five together from one assay for all the other it satisfies It has to go with the design 1 m envisioning different type of designs if you start making them bigger and bigger you are going to use a lot of material you have to talk
63. search that the result of this project 1s hoping to fill A common problem with uniaxial stretching 1s the compressive strains that occur perpendicular to the stretch direction that are created by the Poisson Effect In this case cells are subject to both of these strains and respond differently To attain pure uniaxial stretch also called strip biaxial cells must on feel strains in one direction Figure 2 While strip biaxial behavior 1s not physically possible for entire substrates portions of UNIAXIAL STRIP BIAXIAL On MO gt CER Figure 2 Free Body Diagram of Cells Under Uniaxial and Strip Biaxial Stretch stretched membranes can approximately achieve strip biaxial properties Wang et al 2000 achieved this by only seeded cells on a particular area of a large membrane This area could be assumed to undergo homogeneous strain thus accomplishing strip biaxial stretch This project will take a similar approach as Wang ef al by trying to determine a more effective way to attain pure uniaxial stretch of substrates to gain pure data on the effect of strain on cell cultures 13 3 0 Project Strategy For this project the design team followed the design process as presented by Dym and Little in Engineering Design A Project Based Introduction The process began with a basic project statement from the client Professor Billiar followed by a formal interview with him to help compile a list of design attributes The list o
64. st one experiment the project team believes that this 1s a cost effective mechanically efficient method for testing cellular response to mechanical stimuli The second chapter in this report 1s a literature review that provides essential background on previous research and testing that has been done on relevant to this project including background research on mechanobiology and the different methods of stretching The Project Strategy chapter introduces the reader to the initial client problem and the specific aims and tasks needed to solve it This chapter also identifies the project s specific objectives functions constraints and assumptions Preliminary validation was conducted and conceptual designs were generated and evaluated In Chapter 4 Chapter 5 discusses the validation of each designed subsystem and Chapter 6 analyzes our results The seventh chapter presents the final design and its validation Finally in Chapter 8 conclusions are drawn about our design and recommendations are illustrated for future work 2 0 Literature Review 2 1 Stretching Within the Body Mechanobiology 1s the study of how mechanics affect molecular biology This topic 15 growing increasingly popular as the technology and knowledge of the subject grows With so many variables like stiffness strain cycle rate etc to take into account a multitude of experiments have been conducted that deal with these differences Researchers have tested the effect of d
65. t the design should achieve functions what the design should do and constraints design limitations The design attributes were expanded upon and detailed which resulted in the objectives functions and constraints shown 1n Tables 1 2 and 3 respectively 14 Table 1 Project Objectives Project Objectives Reliable Durable Inexpensive a Minimize use of polyacrylamide growth factors amp cultured cells Easy to use a Easy to Sterilize b Ouick to setup c Portable Effective a Accurate and precise stretch Table 2 Project Functions Project Functions 1 Stretching device will apply a 20 25 strip bi axial uni ax1al without compression stretch to the cells Strain should be adjustable in 5 increments 5 10 15 etc Stretching device will be able to measure strain Stretching device will have an adjustable strain frequency between 0 1 and 2 0 Hz Strain rate will have different types of waveforms Stretching device will be able to hold polyacrylamide Stretching device will be able to be sterilized Table 3 Project Constraints Project Constraints 1 Must function in an incubator and fit on a shelf Cost to produce must be less than 500 Stretching device much achieve a 1cm area of pure stretch Applied strain should be accurate to within 10 The device should not tear or plastically deform the substrate The device must remain sterile for at least 3 days and durable for a week All co
66. to the client about what they need My feeling right now 15 1 cm sguared 1s the minimum but not at the expense of using a lot of material or not being able to run a lot of experiments Things that cost money cells culture mediums and growth factors So we will have to deal with that as an issue The medium and the cells and if you need ten million cells growing them up and using them sometimes it matters sometimes 1t doesn t if you only feed it in a small area 1f you define well where that homogeneous area is so you only functionalize that part and only allow cells to attach to that part you can make up a restraint around it so only the media stays in that area if you need to cover this large thing with media it will be too expensive The function 1s to stretch it the device has to stretch at a certain rate high as strain rate as possible Constraints 1 2 hertz 1f not possible just 1 hertz well have to deal wouldn t be as useful if you could put it whatever strain rate you wanted hold it and bring it back down and do any 50 waveform you wanted that would be 1deal but I want low cost also and easy to use and reliable It has to do all that but we know 1t has to be able to hold onto without tearing the soft gels that s not external objective its within there a sub objective of course limiting the amount of media used would be very good lets say you have a design where you could pull on it and it stretch beautifully 1f it had walls t
67. train and what it does to the VIC Researchers have found that the cells which were 1solated from the pulmonary valve were less stiff than those that were isolated from the aortic valve thereby showing that the stresses put on the cell affect its stiffness This fact shows that VIC s are able to remodel their ECM in response to their surrounding mechanical environment Butcher al 2007 Currently these researchers are trying to apply this knowledge of VIC s to creating new in vitro samples This 1s being done by taking cells from blood vessels and mesenchymal stem cells and putting them into a PGA PLLA copolymer By using mechanical stimulation the team caused the cells to remodel the scaffolding and secrete an ECM Though there are setbacks and still some problems this work still is promising in showing that by the use of mechanical stimulation the properties of cells can be altered 2 2 Replicating cellular response Cells will respond to the changes in their mechanical environment in a variety of different ways Examples of possible responses may include changes in the production of growth factors and vasoactive agents an altered pattern of gene expression and the remodeling of the extracellular matrix Ku ef al 2006 One of the major factors in the mechanical environment 1s that of strain For instance as a muscle 1s strained it starts to tear In the healing process the body rebuilds these muscles making them bigger overcompe
68. uch more accurate and precise position based on the location given by the controller A DC stepper motor works very similarly to a brushed DC motor As opposed to the brushed motor a stepper motor has several negative and positive poles This means as the armature rotates when current 15 applied it does not necessarily have to rotate a full 180 This feature has both positive and negative aspects With such a system this type of motor has more precise control over where it stops As the number of poles within the motor increases so does its accuracy For example 1f there are 90 poles surrounding the internal shaft then there will be able to rotate the motor in 4 increments It also with multiple poles has a high holding torgue Stepper motors tend to be more inexpensive in comparison to a servo motor One of the disadvantages to using a stepper motor 1s that it does not have a smooth cycle when 1n continual rotation 35 A servo motor uses a potentiometer that gives the position feedback signal These two signals both enter a summing operational amplifier which then creates the error signal or the difference between the actual and desired output position This signal 15 then put through a power amplifier since most traditional operational amplifiers cannot provide enough power to move the motor This signal then proceeds to the motor which then can move to the precise output position defined by the user This system leads to a highly se
69. were cured in 9 PA gels Both were high density PE HDPE with different mesh densities These we cured with the grids parallel and biased rotated 45 The finer denser mesh appeared visually to set well into the gels while the looser mesh seen in Figure 4 had varied results Figure 4 Polyacrylamide cured with HDPE Biased Loose Mesh 19 Stretching also provided mixed results The denser mesh consistently failed at the edge of the grips and barely reached 20 strain As this was a fault of the grip it must be discredited The looser mesh did show some promising results However because of the varied curing quality it was hard to verify 15 this was repeatable Some tests had the gel fail at 1ts center after 2090 strain and others had the mesh slip out entirely and no difference was seen between perpendicular and biased configurations It 1s difficult to determine how well it could work but the loose HDPE mesh definitely deserves a closer look 4 1 3 Preliminary Validation of Sguat Stretching Method FEA analysis conducted by the team proved that sguat stretching would garner results that closely resemble strip bi axial behavior Tests were conducted to verify if PA gels with this type of dimensions could be strained to 20 in such a small dimension The tests showed that the gels have sufficient durability in this configuration and easily reached 20 strain and more importantly could withstand strain rates as high as 10 per s
70. y excess polyacrylamide 13 Cells are to be seeded on the middle 2 cm of the gel 14 Apply individual well lids and case lid Tighten case clamps 15 Couple Arm B to motor using Coupling and set screw D E 16 Attach additional units to Arm B by Coupling and 2 set screws F E 17 Carefully transport entire assembly to incubator 18 Remove 4 Set Screws E from transition chambers and power the controller

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