Jet‐based methods to print living cells

Ringeisen, Bradley R.; Othon, Christina M.; Barron, Jason A.; Young, D.; Spargo, Barry J.

doi:10.1002/biot.200600058

Cited by 219 publications

(162 citation statements)

References 98 publications

(178 reference statements)

Supporting

Mentioning

158

Contrasting

Unclassified

Order By: Relevance

“…The printer can be useful in analysis in many fields, including but not limited to: single cell mechanics, tissue engineering, gene transfection, biosensor micropatterning, and direct cell therapies. [1][2][3][4][5][6][7][8][9][10][16][17][18][19][20][21][22] In this example, an HP Deskjet 500 printer and HP 26 series ink cartridges were modified for bioprinting. Using this printer setup with a bioink consisting of a fibroblast cell suspension in a g-actin monomer solution, cells were printed onto glass microscope coverslips.…”

Section: Representative Resultsmentioning

confidence: 99%

“…[2][3][4][5][6][7][8] This modified printer setup can be used for applications other than cell printing. [16][17][18][19][20][21][22] Matrix proteins, such as collagen or fibronectin, can be easily printed onto substrates with this technique, which can be useful for cell patterning. For instance, collagen type I printed into line patterns will result in aligned collagen substrates that can be used for in vitro cell culture studies.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Creating Transient Cell Membrane Pores Using a Standard Inkjet Printer

Owczarczak

Shuford

Wood

et al. 2012

JoVE

View full text Add to dashboard Cite

Bioprinting has a wide range of applications and significance, including tissue engineering, direct cell application therapies, and biosensor microfabrication. [1][2][3][4][5][6][7][8][9][10] Recently, thermal inkjet printing has also been used for gene transfection. 8,9 The thermal inkjet printing process was shown to temporarily disrupt the cell membranes without affecting cell viability. The transient pores in the membrane can be used to introduce molecules, which would otherwise be too large to pass through the membrane, into the cell cytoplasm. 8,9,11 The application being demonstrated here is the use of thermal inkjet printing for the incorporation of fluorescently labeled g-actin monomers into cells. The advantage of using thermal ink-jet printing to inject molecules into cells is that the technique is relatively benign to cells. 8,12 Cell viability after printing has been shown to be similar to standard cell plating methods 1,8 . In addition, inkjet printing can process thousands of cells in minutes, which is much faster than manual microinjection. The pores created by printing have been shown to close within about two hours. However, there is a limit to the size of the pore created (~10 nm) with this printing technique, which limits the technique to injecting cells with small proteins and/or particles. 8,9,11 A standard HP DeskJet 500 printer was modified to allow for cell printing. 3,5,8 The cover of the printer was removed and the paper feed mechanism was bypassed using a mechanical lever. A stage was created to allow for placement of microscope slides and coverslips directly under the print head. Ink cartridges were opened, the ink was removed and they were cleaned prior to use with cells. The printing pattern was created using standard drawing software, which then controlled the printer through a simple print command. 3T3 fibroblasts were grown to confluence, trypsinized, and then resuspended into phosphate buffered saline with soluble fluorescently labeled g-actin monomers. The cell suspension was pipetted into the ink cartridge and lines of cells were printed onto glass microscope cover slips. The live cells were imaged using fluorescence microscopy and actin was found throughout the cytoplasm. Incorporation of fluorescent actin into the cell allows for imaging of short-time cytoskeletal dynamics and is useful for a wide range of applications. 13-15

show abstract

Section: Representative Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Creating Transient Cell Membrane Pores Using a Standard Inkjet Printer

Owczarczak

Shuford

Wood

et al. 2012

JoVE

View full text Add to dashboard Cite

show abstract

“…The distinctive feature between such processes is the inclusion of either an optical absorbing material (MAPLE DW) or a sacrificial absorbing layer (BioLP) at the interface between the laser-transparent ribbon and the material to be transferred [128,163]. In BioLP, the laser absorption interlayer, usually a thin metal coating (Au, Ag, Ti, TiO 2 *100 nm), displays several functions, such as: (1) eliminate the interaction between the laser and the biological material, (2) protect cells from light exposure, (3) minimize the bioink heating, (4) promote a quick thermal expansion with a more efficient droplet ejection, and (5) increase the printing reproducibility [14,57,128,165].…”

Section: Laser-assisted Bioprintingmentioning

confidence: 99%

“…As a result, these processes are promising as they allow the combination of biomaterials and cells in 3D environments, enabling the formation of close cell-cell and cell-matrix interactions. In contrast to inkjet, laser-assisted bioprinting enables the processing of bioinks with a broad range of viscosities (1-300 mPa s -1 ) and higher cell concentrations (10 8 cells mL -1 ) [59,89,125,165], which is a prime requisite to mimic the native organization of human tissues. Although the absence of an orifice reduces the stresses to which cells are subjected, cell injury and dysfunctionality may occur due to thermal heating, optical irradiation and mechanical impact with the receiving substrate [57,128,165].…”

Section: Laser-assisted Bioprintingmentioning

confidence: 99%

“…In contrast to inkjet, laser-assisted bioprinting enables the processing of bioinks with a broad range of viscosities (1-300 mPa s -1 ) and higher cell concentrations (10 8 cells mL -1 ) [59,89,125,165], which is a prime requisite to mimic the native organization of human tissues. Although the absence of an orifice reduces the stresses to which cells are subjected, cell injury and dysfunctionality may occur due to thermal heating, optical irradiation and mechanical impact with the receiving substrate [57,128,165]. Previous research has shown that these effects can be significantly reduced, or even eliminated, by controlling the laser pulse characteristics, the bioink viscosity, the thickness of absorbing layer and the substrate properties [27,53,101].…”

Section: Laser-assisted Bioprintingmentioning

confidence: 99%

See 1 more Smart Citation

Advances in bioprinted cell-laden hydrogels for skin tissue engineering

et al. 2017

View full text Add to dashboard Cite

Bioprinting technologies are powerful additive biofabrication techniques to produce cellular constructs for skin tissue engineering owing to their unique ability to precisely pattern living and non-living materials in predefined spatial locations. This unique feature, combined with the computer controlled printing and medical imaging techniques, enable researchers and clinicians to generate patient specific constructs partly replicating the intricate compositional and architectural organization of the skin. Bioprinting has been used to automatically dispense hydrogels with skin cells located in prescribed sites that promote skin formation in vitro and in vivo. Current skin bioprinting approaches mostly rely on the sequential printing of fibroblasts and keratinocytes embedded within a homogeneous hydrogel. Although such approaches have already been translated to pre-clinical scenarios, they still present limitations in terms of fully replicating the cellular and extracellular matrix (ECM) heterogeneity in native skin. The success of bioprinting for skin repair strongly depends on the design of printable bioinks capable of supporting the function of printed cells and stimulating the production of new ECM components. To better mimic the human skin, novel developments in dedicated bioprinting technologies, in the design of bioinks, as well as in the printing of vascularised constructs are necessary. This paper presents an overview regarding the use of bioprinting for skin tissue engineering applications. The operating principles of bioprinting technologies are outlined along with requirements of printed skin constructs. Finally, preclinical results are summarized and future perspectives for the field are highlighted.

show abstract

Medical Applications

2018

3D Industrial Printing With Polymers

View full text Add to dashboard Cite

Jet‐based methods to print living cells

Cited by 219 publications

References 98 publications

Creating Transient Cell Membrane Pores Using a Standard Inkjet Printer

Creating Transient Cell Membrane Pores Using a Standard Inkjet Printer

Advances in bioprinted cell-laden hydrogels for skin tissue engineering

Medical Applications

Contact Info

Product

Resources

About