1 / 56

System for Micropatterning and Cell Encapsulation

System for Micropatterning and Cell Encapsulation. GROUP 3 Sailaja Akella Caroline LaManna Tereissa Mak Rupinder Singh. Overview. Design Project and Customer Criteria Current Technology -Photolithograpy -Soft Lithography -Contact Printing -Ink-Jet Printer

shalom
Download Presentation

System for Micropatterning and Cell Encapsulation

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

E N D

Presentation Transcript


  1. System for Micropatterning and Cell Encapsulation GROUP 3 Sailaja Akella Caroline LaManna Tereissa Mak Rupinder Singh

  2. Overview • Design Project and Customer Criteria • Current Technology -Photolithograpy -Soft Lithography -Contact Printing -Ink-Jet Printer • Technical Considerations -Fluid & Cell Mechanics -Software -Encapsulation -Biopaper • Brainstorming

  3. Design Project & Customer Criteria • Design a system that facilitates cell deposition and micropatterning to be used in the creation of neuron and polymer based circuits. • Customer Criteria • suitable for printing biological macromolecules, sterile • programmable for desired patterning, accurate & precise • cost-efficient (<$500)

  4. Cell Patterning • Tissue Engineering Applications • Individual cells  Functional customized organs • Tissue rejection or lack of available donor organs • Bioengineering Applications • Genomics  high-density DNA microarrays  colony arrays for genomic libraries • Biosensors  Enzyme arrays for bioanalysis

  5. Photolithography • A photosensitive surface (a photoresist) is selectively exposed to light using a template and exposed areas are etched (carved by chemical means) • Production of silicon chips that make up modern-day computers, circuitry

  6. Procedure: wafer cleaning barrier layer formation photoresist application soft baking; mask alignment exposure and development hard-baking. Photolithography Photolithography process.1

  7. The manipulation of surfaces to create channels and substrate patterns to facilitate protein deposition and cell adhesion Microcontact Printing Microfluidic Patterning Soft Lithography Microcontact printing with different inking solutions.2

  8. Microcontact Printing uses a PDMS microstamp, coated with protein, cellular factors, to leave pattern for later adhesion transfer a specific cell type onto a substrate in specified pattern deposit cellular factors that will allow or hinder the deposition of a specific cell type Soft Lithography Microcontact printing process schematic.3

  9. Soft Lithography • Microcontact Printing • Current Technology • Used to print self-assembled monolayers of alkanethiols on gold • Used to pattern ECM proteins on polystyrene to grow rat embryonic cortical neurons in patterns • Advantages • Applied to circuitry grid formations • Suitable for cell growth • Disadvantages • Expensive & complex • Limits to cell precision and confinement

  10. Microfluidic Patterning Uses channels on PDMS microfluid networks to direct cells, protein, etc. onto substrate in specified patterns Soft Lithography Microchannels for pattern formation4

  11. Soft Lithography • Microfluidic Patterning • Advantages • Rapid prototyping • Effectively patterns on non-planar substrates • Disadvantages • Efficiency of pattern transfer, not repeatable • Highly complex and specialized, not automated

  12. Contact Printing • Quill • Solid • Pin-and-ring (Matrix Dot) • Disadvantages • Due to the impact at contact, pin structure deformation, and clogging from contaminants collected at contact, pin-based arraying is prone to suffer from slide-to-slide inconsistency

  13. Disadvantages Less precise cell patterning Protein cell attachment Resolution limited to nozzle Advantages High throughput Low cost Automation Complex patterning flexibility No Surface contact Printing and maintaining viable biological solutions Ink-Jet Printer • Printing Technique • Biological reconstruction of digital data • Non-contact reprographic technique • Thermal/Bubble & Piezoelectric

  14. Thermal/Bubble • Commercial ink-jet printers • Hewlett-Packard DeskJet 550C • Canon Bubble Jet 2100 • Printing Mechanism • High temperature heating system5 • Current pulse is applied for microseconds, which raises temperature ~300oC • Heated plate in the nozzle causes vapor bubble to form and eject a droplet of ink

  15. Advantages Deposit large amounts Deposit multiple layers Suitable for printing: polymer encapsulated cells6 cell solution6 Disadvantages Limited Resolution 300-400um Low precision single cell patterning High Temperature Bubble/Thermal Motor neurons printed in ring. Neurons forming connections7 viable mam

  16. Bubble/Thermal • Okamoto et al.8 • Fabrication of DNA Microarrays • Presynthesized oligonucleotides are ejected onto glass surface • Conventional DNA hybridization measured • Used to detect SNPs • Advantage • Low cost compared with photolithography • Less uncertainty • Disadvantage • Exposure of DNA to high temperature ~200oC • Shear stress (10m s-1) Microarray using inkjet technology

  17. Piezoelectric • Commercial Printer • Epson (patented use of piezo crystals) • Printing Mechanism • A crystal located at each nozzle receives an electric charge causing vibration • Crystal vibrates forces tiny amount of ink5

  18. Advantages Small drop sizes Picoliter High-ejection rate Several thousand Complex patterns Low cost Disadvantages Clogging Biomaterials Environmental effect Effect of Printing Technique High frequencies Compression Friction9 Piezoelectric

  19. Piezoelectric • Neville et al.10 • Micropattern for neural cell culture • Utilize substrate-bound patterns as a simulation environment and test-bed • Technique • Deposited collagen/poly-D-lysine (+) & polyglycol (-) • Plated neurons and glial cells • Advantage • Low cost compared with lithographic techniques • Experimentation with different patterns (testing environment) • Disadvantage • No direct printing of neurons • Drying of neurons • Changing osmolarity

  20. Technical Considerations • Mechanical Limits • Fluid & Cell Mechanics • Mechanical Forces created in Printing • Printing Systems • Bubble Jet • Piezoelectric • Software & Printer Integration • Cell Encapsulation • Biopaper

  21. Boundary Conditions • Nozzle diameters: 30-100 um • Potential range of viscosity: 0.5-20 poise • Potential surface tension: 25-50 mN m-

  22. PreventingContinuous Flow

  23. Intermolecular Forces

  24. Surface Energy/Tension • behavior and many properties of liquids can be attributed to intermolecular forces. • quantifies the disruption of chemical bonds that occurs when a surface is created • surfaces are intrinsically less energetically favourable than the bulk of a material; otherwise there would be a driving force for surfaces to be created, and surface is all there would be • sphere has a smaller ratio of surface area to volume than any other three-dimensional figure, free-falling liquids tend to form spherical drops.

  25. Surface Energy/Tension

  26. Ejection of Droplet

  27. Capillary Action Force

  28. Viscosity • Measure of a liquid’s resistance to flow (poise) • Has little effect on the ability of a penetrant material to enter a defect but it does have an effect on speed at which the penetrant fills a defect • Fill time is directly proportional to penetrant viscosity

  29. Viscosity

  30. Viscosity • η = K·(db-dl)·t [1] • where η is the viscosity in cP, K is the viscometer constant (we used a value of 0.3), db is the density of the ball (2.53), dl is the density of the liquid (g/ml) and t is the time of ball descent

  31. Thermal Printing

  32. Thermal Printing • An electrical resistor heats ink at more than 1 million degree C • A film of ink about 0.1 micrometer thick is heated to about 340 C • Cardiac Cells: 10x60x100 um • Collage Protein: Type I is 300nm long, 1.5nm in diameter and consists of 3 coiled subunits

  33. Thermal Printing • Normal evaporation will occur whenever the vapor pressure in the ambient gas is less than the saturation pressure of the liquid at the liquid temperature • Since the saturation pressure of a liquid increases with increasing temperature, the rate of evaporation will also increase with temperature • Evaporation from the liquid surface causes a decrease in liquid surface temperature

  34. Theories for Droplet Ejection • Note that while several theories exist concerning the mechanisms of liquid droplet ejection, no model exists for prediction of the ejected droplet rate, size or velocity • Heterogeneous nucleation • Homogeneous nucleation

  35. HeterogeneousNucleation • Heterogeneous boiling occurs when vapor bubbles are formed below the surface at a nucleation site • When the nucleation site temperature exceeds the saturation temperature of the liquid, vapor bubble formation and growth may occur

  36. Superheated Liquid • If the heat rate is fast enough, the liquid may become superheated, that is the liquid temperature can exceed the boiling temperature • A superheated liquid is in a metastable state • Temperature continues to increase, the spinodal is reached and the liquid becomes unstable and catastrophically relaxes to a liquid-vapor mixture

  37. P-T Characteristic

  38. Homogeneous Nucleation • Once in the metastable region a liquid need not reach the spinodal in order to change to a liquid-vapor mixture • Homogeneous nucleation • the spontaneous creation of vapor nuclei within the liquid, without the aid of preexisting nucleation sites

  39. Bubble-Jet Printing • As the vapor bubbles grow and coalesce, a large bubble may be formed below the surface • When the bubble reaches a critical size it will burst, propelling liquid droplets into the plume

  40. Piezoelectric Transducer • Mechanical Vibrations • This alignment of molecules will cause the material to change dimensions - electrostriction

  41. Piezoelectric Transducer

  42. Piezoelectric Transducer

  43. Printer Software • The software drivers of the HP 550C are rewritten to allow for protein solutions of different viscosities and electrical charges to be printed • The source code for the HP550C printer was provided by the manufacturer at no cost • The new driver software constantly adjusts the voltages applied to the nozzle gate to account for different electrical resistance values in the solutions • This allows the appropriate amount to be dispensed, regardless of concentration, viscosity, or pH

  44. Potential Software • Code original PLC for particular printer • Use DDK (Desktop Driver Kit) • Change manner of printing • Dpi • Quality of Paper / Printing

  45. Printer Circuit Board

  46. Communication With Printer Head

  47. Cell Encapsulation • A technology used for the microencampsulation of live cells and tissues within protective membrane • Drug delivery systems • The polymeric semipermeable membrane provides a physical barrier, preventing any direct contact between the entrapped cells and its surrounding environment

  48. Encapsulation Polymer • Poly(Ethylene Glycol) Diacrylate: • Biocompatible • Nontoxic • Non-immunogenic • Hydrophilic • Can be chemically cross-linked into hydrogels

  49. Encapsulation Polymer • Poly(lactic Acid) (PLA) • Aliphatic polyester Derived from lactic acid • Biodegradable • Thermoplastic

  50. Encapsulation Polymer • Poly(lactic-co-glycolic acid) (PLGA) • Copolymer of PLA and PGA • Microphase separation • Crystallinity • Water-solubility • Biodegradability

More Related