Bioprinting Cellularized Constructs Using a Tissue-specific Hydrogel Bioink

Podsumowanie

We describe a set of protocols that together provide a tissue-mimicking hydrogel bioink with which functional and viable 3-D tissue constructs can be bioprinted for use in in vitro screening applications.

Streszczenie

Bioprinting has emerged as a versatile biofabrication approach for creating tissue engineered organ constructs. These constructs have potential use as organ replacements for implantation in patients, and also, when created on a smaller size scale as model "organoids" that can be used in in vitro systems for drug and toxicology screening.

Despite development of a wide variety of bioprinting devices, application of bioprinting technology can be limited by the availability of materials that both expedite bioprinting procedures and support cell viability and function by providing tissue-specific cues. Here we describe a versatile hyaluronic acid (HA) and gelatin-based hydrogel system comprised of a multi-crosslinker, 2-stage crosslinking protocol, which can provide tissue specific biochemical signals and mimic the mechanical properties of in vivo tissues.

Biochemical factors are provided by incorporating tissue-derived extracellular matrix materials, which include potent growth factors. Tissue mechanical properties are controlled combinations of PEG-based crosslinkers with varying molecular weights, geometries (linear or multi-arm), and functional groups to yield extrudable bioinks and final construct shear stiffness values over a wide range (100 Pa to 20 kPa). Using these parameters, hydrogel bioinks were used to bioprint primary liver spheroids in a liver-specific bioink to create in vitro liver constructs with high cell viability and measurable functional albumin and urea output. This methodology provides a general framework that can be adapted for future customization of hydrogels for biofabrication of a wide range of tissue construct types.

Wprowadzenie

In recent years, a variety of technologies have become available that addresses the need for alternative sources of functional organs and tissues by seeking to manufacture, or biofabricate, them. Bioprinting has emerged as one of the most promising of these technologies. Bioprinting can be thought of as a form of robotic additive fabrication of biological parts, that can be used to build or pattern viable organ-like or tissue-like structures in 3 dimensions.¹ In most cases, bioprinting employs a 3-dimensional (3-D) printing device that is directed by a computer to deposit cells and biomaterials into precise positions, thereby recapitulating anatomically-mimicking physiological architectures.² These devices print a "bioink", which can take the form of cell aggregates, cells encapsulated in hydrogels or viscous fluids, or cell-seeded microcarriers, as well as cell-free polymers that provide mechanical structure or act as cell-free placeholders.^3,4 Following the bioprinting process, the resulting structure can be matured into functional tissue or organ structures, and used for its intended end application.^5,6 To date, a complete fully functional human-sized organ has not been printed, but it remains the primary long-term goal of bioprinting research and development.² However, small-scale "organoid" tissue constructs are currently being implemented in a number of applications, including pathology modeling, drug development, and toxicology screening.

One of the main hurdles that researchers have encountered in applying bioprinting technology is that very few materials have been developed for the explicit purpose of bioprinting. To effectively succeed in bioprinting, a biomaterial must meet 4 basic requirements. The biomaterial needs to have 1) the appropriate mechanical properties to allow deposition (be it extrusion through a nozzle as a gel or an inkjet as a droplet), 2) the ability to hold its shape as a component of a 3-D structure after deposition, 3) the capability for user control of the 2 prior characteristics, and 4) a cell friendly and supportive environment at all phases of the bioprinting procedure.⁷ Historically, bioprinting work has often tried to employ existing traditional biomaterials in bioprinting devices without consideration for their compatibility, instead of designing a biomaterial to have the properties necessary for bioprinting and subsequent post-printing applications.

A variety of bioinks have been developed recently to better interface with the deposition and fabrication hardware. Standard hydrogel systems pose significant problems because they generally exist as either precursor fluid solutions with insufficient mechanical properties, or polymerized hydrogels that if printed can clog nozzles or become broken up upon the extrusion process. Our team, as well as others, have explored various hydrogel formulations to address these bioprinting problems, including cell spheroid printing into hydrogel substrates,^5,8 cell and hydrogel filament extrusion from microcapillary tubes,^9-11 extrudable hyaluronic acid (HA)-gold nanoparticle hydrogels with dynamic crosslinking properties,¹² temporal control of hydrogel stiffness using photopolymerizable methacrylated HA and gelatin,¹³ fibrinogen-thrombin-based crosslinking,^14,15 ionic exchange alginate-collagen gels,¹⁶ and recently rapid polymerizing ultraviolet light (UV)-initiated crosslinking,¹⁷

These examples demonstrate the feasibility of generating materials that can by bioprinted effectively. However, in addition to integration with hardware, to successfully generate viable and functional 3-D tissue constructs, biomaterials must contain biochemical and mechanical cues that aid in maintaining cellular viability and function. These additional factors, biochemical and mechanical profiles, can have a significant influence on the successful function of bioprinted tissue constructs.

Both cells and the native extracellular matrix (ECM) are responsible for presenting a wide range of signaling molecules such as growth factors and other cytokines to other cells. The combination of these signals varies from tissue to tissue, but can be extremely potent and influential in regulating cell and tissue behavior.¹⁸ Employing tissue-specific ECM components from different organs and implementing as a hydrogel or as part of a hydrogel has been explored with success.^19-21 This approach, which is comprised of decellularizing a given tissue, pulverizing it, and dissolving it, can be used to produce tissue-specific biochemical signals from any tissue and can be incorporated in 3-D hydrogel constructs.²²

Additionally, it is widely documented that tissues in the body occupy a wide range of stiffnesses.²³ As such, the ability to tune the mechanical properties of biomaterials, such as elastic modulus E' or shear elastic modulus G', is a useful tool in tissue engineering. As described above, control over bioink mechanical properties allows for extrusion-based biofabrication using a soft gel, which can then further manipulated by secondary crosslinking at a later point, at which elastic modulus levels can be attained that match that of the target organ type. For example, biomaterials could be customized to match a stiffness of 5-10 kPa like a native liver,²³ or match a stiffness of 10-15 kPa like native cardiac tissue,^24,25 in theory increasing the ability of these organoids to function in a similar manner to their native tissue counterparts. The influence of environmental stiffness on cell phenotype has been explored in recent years, particularly with respect to stem cells. Engler et al. demonstrated that substrate elasticity aided in driving mesenchymal stem cells (MSC) towards lineages with tissue elasticity matching that of the substrate.²⁵ This concept has been further explored for differentiation into muscle, cardiac function, liver phenotype, hematopoietic stem cell proliferation, and maintenance of stem cell therapeutic potential.^24,26-29 Being able to tune a hydrogel to different elastic moduli is an important feature of a biomaterial that will be used to biofabricate tissue constructs.³⁰

Here we describe a protocol that represents a versatile approach used in our laboratory to formulate a hydrogel system that can be extrusion bioprinted, and customized to 1) contain the biochemical profile of a particular tissue type and 2) mimic the elastic modulus of that tissue type. By addressing these requirements, we aim to provide a material that can recapitulate the physiochemical and biological characteristics of in vivo tissue.³¹ The modular hydrogel composite system described herein takes advantage of a multi-crosslinking approach to yield extrudable bioinks, and allows a secondary crosslinking to stabilize and increases the stiffness of the end products to match a range of tissue types. Biochemical customization is met by using tissue-specific ECM components. As a demonstration, we employ a liver-specific variety of this hydrogel system to bioprint functional liver organoid constructs. The protocol described uses a custom 3-D bioprinting device. In general, this protocol can be adapted to most extrusion-based printers, specific printing parameters vary dramatically for each type of device and require testing by the user.

Protokół

1. Hydrogel Bioink Formulations and Preparation

1. In order to provide tissue-specific biochemical profiles, prepare tissue-specific ECM digest solutions as previously described for liver.²⁰
   Note: In general, this ECM digest will comprise 40% of the final hydrogel bioink volume that is employed. Several hundred milliliters of ECM digest solution can be prepared, aliquoted, and frozen at -80 °C for future use.
2. Prior to hydrogel formulation, dissolve a photoinitiator, 2-hydroxy-4′-(2-hydroxyethoxy)-2-methylpropiophenone, in water at 0.1% w/v.
   Note: Volumes in the 50-100 ml range can be prepared ahead of time and stored shielded from light at 4 °C for several months.
3. To form hydrogel bioinks, first dissolve the base material components from the hyaluronic acid (HA) hydrogel kits in the water-photoinitiator solution.
   1. Dissolve the thiolated HA and thiolated gelatin separately in water-photoinitiator solution (step 1.2) to make 2% w/v solutions.
   2. Dissolve polyethylene glycol diacrylate (PEGDA), the crosslinker in the hydrogel kits, in water-photoinitiator solution (step 1.2) to make an 8% w/v solution.
   3. Dissolve polyethylene glycol (PEG) 8-Arm alkyne (10 kDa MW) in water-photoinitiator solution (step 1.2) to make an 8% w/v solution.
4. In general, form hydrogels using the following scheme, although additional customization is possible.
   1. Combine 4 parts 2% thiolated HA, 4 parts 2% thiolated gelatin, 1 part crosslinker 1, 1 part crosslinker 2 with 8 parts tissue ECM solution and 2 parts hepatocyte culture media (HCM) (or 10 parts water as a generic non-tissue-specific hydrogel).
      Note: Additional unmodified HA or gelatin can be added to make the bioink extrude more smoothly. This is described below.
5. Vortex the resulting mixture on high (speed 10 out of 10) for 10 sec to mix prior to use.
6. Use of hydrogel bioink
   1. For extrusion or bioprinting testing, transfer the mixture into a syringe or printer cartridge and allow it to crosslink spontaneously for 30 min (stage 1 crosslinking) at 37 °C.
   2. For rheological measurements, transfer the mixture into a 35 mm Petri dish and allow it to crosslink for 30 min.
      Note: The mixture immediately begins to crosslink through thiol-acrylate bond formation and will begin to increase in viscosity. The mixture should be transferred to a syringe, print cartridge, or target location within 10 min to avoid clogging of a pipette or syringe during transfer.
   3. When secondary crosslinking (stage 2) is desired, irradiate the stage 1-crosslinked gels with ultraviolet light (365 nm, 18 W/cm²) to initiate a thiol-alkyne polymerization reaction.
      Note: Duration of irradiation is dependent on the surface area of the material. In general, a square centimeter of material only requires 1-2 sec of UV exposure at this UV power.

2. Printer Compatibility Testing

1. Prior to integration testing with bioprinting devices, test extrusion characteristics on the laboratory bench with simple extrusion tests using standard syringes and small gauge needle tips (20-30 gauge).
   1. Push the bioink through a standard syringe to achieve smoothly extruded filaments of hydrogel with few or no bumps. Extruding of lines or simple patterns is sufficient to determine success.
2. For bioprinter integration, load bioink preparations by pipetting them into printer cartridges, and allow 30 min for the bioink to undergo spontaneous stage 1 crosslinking within the cartridge.
   Note: Volume of bioink depends on the specific application and should be determined by the user. Printer cartridges may resemble or be syringes that are compatible with the bioprinter device.
3. Evaluate extrusion compatibility for bioprinting by printing a simple pattern using the bioink. For example, print a 7 x 7 mm pattern comprised of parallel lines. Apply pressure (e.g., 20 kPa pneumatic pressure) while the printhead moves in the X-Y plane at a velocity of approximately 300 mm/min.
   Note: Printhead nozzle diameters of various sizes can be used, but conical nozzles with 400-500 µM diameter openings are optimal for printing spheroids in the 250-350 µm range.
   1. If the extruded materials are lumpy or irregular, see step 2.4, or reduce the amount of PEGDA to soften the stage 1 crosslinked material. Properly prepared bioink formulations extrude smoothly, allowing precise deposition in desired patterns or architectures.
      Note: The bioprinting procedures described use a custom 3-D bioprinting device designed in house specifically for tissue construct printing.³² As such, specific printing parameters vary dramatically for each type of device and require testing by the user.
4. To improve extrusion properties, supplement unmodified HA and gelatin to the bioinks (1.5 mg/ml and 30 mg/ml, respectively).

3. Validation by Bioprinting with Primary Liver Constructs

1. Prepare 3-D primary cell liver spheroids by hanging drop methods as the cellular component³³
   Note: Bioprinting can be performed without spheroids, but instead with individual cells suspended in the hydrogel bioinks as well. Spheroids are employed here to accelerate cell-cell interactions and construct functionality. The number of spheroids or cells employed depends on the specific application and should be determined by the user. These steps should be performed under sterile conditions, using sterile supplies.
   1. Prepare HCM by adding the thawed contents of the HCM supplement component kit to the hepatocyte basal media (HBM) and sterile filtering.
      1. Thaw the supplement components until liquid.
      2. Add the supplement components (ascorbic acid, 0.5 ml; bovine serum albumin [fatty acid free], 10 ml; gentamicin sulfate/amphotericin B, 0.5 ml; hydrocortisone 21-hemisuccinate, 0.5 ml; insulin, 0.5 ml; human recombinant epidermal growth factor, 0.5 ml; transferring, 0.5 ml) to the 500 ml HBM.
      3. Sterile filter through a 0.45 μm or 0.22 μm filter using a bottle-top filter unit or a syringe tip filter.
   2. Determine the cell density of primary human hepatocytes, Kupffer cells, and stellate cells by counting on a hemocytometer after each cell type has been thawed according to manufacturers' instructions.
   3. Combine primary human hepatocytes, Kupffer cells, and stellate cells in an 80:10:10 ratio by cell number in HCM media that has been warmed to 37 °C in a conical tube.
      Note: The volume of media to be used depends on the overall cell number specific to the application and should be determined by the user.
   4. Centrifuge the cell suspension for 5 min at 520 x g at 20 °C.
   5. Aspirate the supernatant, leaving behind the cell pellet.
   6. Resuspend the cell pellet in HCM media to yield a cell suspension containing 1,000 cells per 40 µl media. Total volume is dependent on the number of spheroids being produced.
   7. Transfer the cell suspension to 96-well format hanging drop plates. Add a total of approximately 1,000 cells to each well in HCM and maintain at 37 °C, in 5% CO₂ for 3 days during which multicellular spheroids form.
   8. Collect liver spheroids from the hanging drop plate using a pipettor. Transfer to a sterile 15 ml conical tube.
2. Bioprint liver spheroids in liver-specific hydrogel bioink
   1. Prepare a formulation of liver ECM-containing hydrogel bioink as described in Step 1, employing 8% PEGDA and 8% 8-Arm PEG alkyne as crosslinkers. Use this combination for its capability in resulting in a hydrogel close in shear elastic modulus to native liver tissue.
   2. Let the spheroids settle to the bottom of the conical tube in which they were placed in Step 3.1.7. This varies based on spheroid size and density, but generally occurs within 1-2 min. Remove all media by carefully aspirating or with a pipettor.
   3. Transfer the desired volume of freshly prepared hydrogel bioink solution to the conical tube containing the spheroids. Generally, an appropriate volume is 10%-25% greater than the volume of the 3-D construct to be printed. Carefully pipette up and down to resuspend the spheroids in the hydrogel bioink solution. Transfer to a bioprinter cartridge using a pipettor or serological pipette.
   4. Inside the bioprinter cartridge, allow the solution to undergo the first crosslinking stage (thiol-acrylate reaction) for 30 min.
      Note: Depending on spheroid size, the cartridge may need to be slowly rotated or the contents may need to be mixed with a sterile spatula to keep the spheroids distributed throughout the bioink during the stage 1 crosslinking. This is less of a necessity for bioinks prepared with suspended cells instead of spheroids.
      Note: Following stage 1 crosslinking, users have an operating window of several hours. However, it is recommended to perform the bioprinting process quickly to improve cell viability.
   5. Following stage 1 crosslinking, use a bioprinting device to create desired hydrogel structures containing the primary liver spheroids (or other cells).
      Note: This technology provides a system for biofabricating a wide variety of structures. Parameters such as total volume, number of cells or spheroids, the printed structure geometry, and substrate on which constructs are printed are highly dependent on the goals of the user.
   6. After deposition into the desired configuration, administer UV light for 2-4 sec to initiate the secondary crosslinking mechanism, stabilizing the constructs and increasing stiffness to the desired level.
      Note: The concentration of PEG-alkyne, and thus the overall final crosslinking density, primarily controls the final construct stiffness.
   7. Repeat the steps 3.2.4 and 3.2.5 in order to create multi-layered constructs.

Wyniki

When the procedures described above are followed correctly, hydrogels should contain a biochemical profile specific to the target tissue type,²⁰ allow for a high degree of control over bioprinting and final elastic modulus,³⁴ and support viable functional cells in tissue constructs.

Hydrogel Customization
To best mimic native liver, the hydrogel bioink was supplemented by liver ECM so...

Dyskusje

There are several components that are critical to consider when attempting to biofabricate 3-D tissue constructs, for eventual use in humans or for in vitro screening applications. Employing the appropriate cellular components determines the end potential functionality, while the biofabrication device itself determines the general methodology for reaching the end construct. The third component, the biomaterial, is equally important, as it serves dual roles. Specifically, the biomaterial component must be compati...

Materiały

Name	Company	Catalog Number	Comments
Hyaluronic acid	Sigma	53747
Gelatin	Sigma	G6144
2-Hydroxy-4′-(2-hydroxyethoxy)-2-methylpropiophenone	Sigma	410896
Hyaluronic acid and gelatin hydrogel kit (HyStem-HP)	ESI-BIO	GS315	Kit contains the components Heprasil (thiolated and heparinized hyaluronic acid), Gelin-S (thiolated gelatin), and Extralink (PEGDA)
PEG 8-Arm Alkyne, 10 kDa	Creative PEGWorks	PSB-887
Primary human hepatocytes	Triangle Research Labs	HUCPM6
Primary human liver stellate cells	ScienCell	5300
Primary human Kupffer cells	Life Technologies	HUKCCS
Hepatocyte Basal Media (HBM)	Lonza	CC-3199
Hepatocyte Media Supplement Kit	Lonza	CC-3198	HCM SingleQuot Kits (contains ascorbic acid, 0.5 ml; bovine serum albumin [fatty acid free], 10 ml; gentamicin sulfate/amphotericin B, 0.5 ml; hydrocortisone 21-hemisuccinate, 0.5 ml; insulin, 0.5 ml; human recombinant epidermal growth factor, 0.5 ml; transferring, 0.5 ml)
Triton X-100	Sigma	T9284	Other manufacturers are ok.
Ammonium hydroxide	Fischer Scientific	A669	Other manufacturers are ok.
Fresh porcine cadaver tissue	n/a	n/a
Lyophilizer	any	n/a
Freezer mill	any	n/a
Bioprinter	n/a	n/a	The bioprinter described herein was custom built in-house. In general, other devices are adequate provided they support computer controlled extrusion-based printing of hydrogel materials.
Hanging drop cell culture plate	InSphero	CS-06-001	InSphero GravityPlus 3D Culture Platform