An Assay to Measure Chemically-Induced Cytotoxicity in Human Precision-Cut Lung Slices

Published: November 30, 2023

Abstract

Source: Neuhaus, V. et al., Assessment of the Cytotoxic and Immunomodulatory Effects of Substances in Human Precision-cut Lung Slices. J. Vis. Exp. (2018)

This video illustrates a technique for evaluating cytotoxicity in human precision-cut lung slices through the WST-1 assay. Human precision-cut lung slices are subjected to incremental concentrations of a cytotoxic chemical to quantify their cytotoxicity. A decrease in color intensity serves as confirmation of the chemical's detrimental impact on lung cells.

Protocol

All procedures involving sample collection have been performed in accordance with the institute's IRB guidelines.

1. General Preparation of Human precision-cut lung slices (PCLS) and Subsequent Exposure to Chemicals

NOTE: Two persons are required to fill a lung. An up-to-date vaccination record for hepatitis A and B is recommended. Patients are routinely screened for hepatitis C virus (HCV) and human immunodeficiency virus (HIV) prior to lung transplantation. If an active infection with Mycobacterium tuberculosis is diagnosed or suspected, the lung should be rejected. Nevertheless, all fresh human lung tissue and samples derived from it must be treated as potentially infectious, and corresponding protective measures must be taken (particle filter masks (FFP2), protective eyewear, gloves) to ensure the occupational safety of the staff. The procedure takes 60 – 90 min.

  1. Confirm the intactness of the human lung lobe.
    NOTE: A tear in the pleura prevents homogeneous filling of the tissue. Human lung material must be from the day of resection. Storage periods of about 2 h at room temperature (RT) prior to filling it with agarose on ice are tolerated. The tissue that we use in this protocol is obtained from patients undergoing resection. It is not from deceased patients. If the tissue has been stored on ice, pre-warm it to RT before filling it, otherwise, the agarose will polymerize immediately, and no homogeneous filling will be possible.     
    CAUTION: Ensure that all persons in contact with native human material put on protective clothing consisting of a lab coat, two pairs of gloves, a cap, a face mask, and a pair of safety glasses. Human material is potentially infectious.
  2. Weigh 7.5 g of low-gelling agarose and add it to 250 mL of bi-distilled water. Boil the agarose in a microwave until the agarose is dissolved. Cool it to approximately 40 °C, depending on the melting and gelling point of the agarose.
    NOTE: Several flasks are required, depending on the lobe size.
  3. Pre-warm and keep the culture medium (Table of Materials) at 37 °C.
    NOTE: If the agarose is too hot, vitamins in the culture medium will lose effectiveness and cells will be damaged. If the temperature of the medium/agarose solution is below 37 °C, the gelling process will start and impair the homogeneous filling of the lung. Only a temperature range of 37 °C to 39 °C is recommended.
  4. Place all the required materials within reach before starting: 5 – 10 clamps, a flexible catheter of approximately 1 m length, a suitable syringe (e.g., 50 mL) fitting the connection to the catheter, and an ice box filled with ice.
  5. Cannulate the trachea/main bronchus by inserting the silicone tube and fixating it with a clamp oriented parallel to the tube, so that the clamp squeezes the tissue together alongside the silicone tube without pinching it off. Verify that the silicone tube is fixated inside and cannot slip out during the filling procedure. Close all other bronchi, blood vessels, and injuries with clamps, so that no agarose can leak out during the filling procedure.
  6. Mix an equivalent volume of 3% low-gelling agarose with culture medium in a beaker. Instill the mixture into the lung using a 50-mL syringe. Prior to refilling the syringe with medium, clamp shut the catheter with fingers or a clamp to avoid air bubbles and agarose reflux. Fill the lung lobe until it is fully inflated. Carefully touch the lung pleura on the side; the pleura should be even and hard.
    NOTE: Depending on the size of the lung lobe, up to 2 or 3 L of agarose/medium solution can be required.
  7. Repeat steps 1.5 – 1.6 for each bronchus in the case of several bronchi within a single specimen.
  8. Put the lung on ice for polymerization of the agarose to gel for 20 – 40 min, depending on the amount of instilled agarose. Carefully touch the pleura on several sides to check whether it is hard and cool, indicating that polymerization is complete, otherwise, continue to wait. The pathologists will cut the lung into slices, take their samples, and store the lung material on ice for transportation.
  9. Cut the human lung tissue into 3 – 5 cm slabs with a sharp knife.    
    NOTE: Use a new blade for every lung to ensure sharpness.
  10. Fill the tissue slicer with 400 mL ice-cold Earle's balanced salt solution (EBSS). Immediately cut cylindrical tissue cores out of the lung slabs using a semi-automated screwdriver with a coring tool of the preferred diameter (e.g., 8 mm; 10 mm).
    NOTE: This diameter must be equivalent to the diameter of the tissue holder inside the machine.
  11. Adjust the thickness of the lung slices to the desired thickness value.
    NOTE: A thickness of approximately 250 µm is commonly used in PCLS experiments. The manufacturer of the tissue slicer recommends their Tissue Slice Thickness Gauge for verification of the slice thickness. Alternatively, whole-mount staining combined with confocal microscopy can be used to determine the slice thickness as described by Brismar et al.
  12. Transfer the tissue cores into the tissue holder of the tissue slicer. Put the weight (part of the tissue holder) on top of the tissue core. Set the arm speed and blade speed to 6 on the tissue slicer. Start slicing the tissue core into PCLS.
  13. Supplement 500 mL of commercially available Dulbecco's Modified Eagle Medium (DMEM): Nutrient Mixture F-12 DMEM/F12 (1:1) with 5 mL of penicillin (10,000 units/mL) and streptomycin (10,000 µg/mL). Store the culture medium for several days under sterile conditions in a refrigerator. Pre-warm only the required volume of the medium.      
    NOTE: Penicillin will be inactivated if kept at 37 °C for longer periods. Use serum-free and dye-free culture medium, as serum composition varies from batch to batch, and dyes, such as phenol-red, can interfere with assays.
  14. Fill a Petri dish (100 x 15 mm) with 25 mL ice-cold culture medium. The medium should be drained out of the tissue slicer into a beaker by opening the clamp of the glass cylinder. Transfer the slices from a beaker into the Petri dish with culture medium by using an applicator (e.g., inoculation loop). Put the Petri dish into an incubator (37 °C, 5% CO2, 100% humidity). Allow the medium to warm up prior to washing steps.
    NOTE: All further steps are performed under sterile conditions.
  15. Place a cell strainer into the Petri dish for washing the PCLS. Completely remove the culture medium with a 10-mL serological pipette through the cell strainer and add 25 mL of 37 °C pre-warmed fresh medium. Repeat this step 3 – 4 times every 30 min.     
    NOTE: The cell strainer prevents the slices from being sucked into the pipette, to avoid any damage to the slices.
  16. Transfer the lung slices carefully into a 24-well culture plate with a minimum of 500 µL culture medium for two slices per well. Expose the lung tissue to substances (see steps 3.1 – 3.4), e.g., for 24 h at 37 °C, 5% CO2.      
    NOTE: For the transfer, preferably use an inoculation loop and let the slices float onto the loop in order to prevent tissue damage. No further separation of the slices is needed, as only a shortage of sufficient fresh medium will induce cell death in tissue slices. Slices can overlap or touch each other in the well: this has no influence on tissue viability.
  17. Put all residual human material into a plastic flask with a fixative (e.g., 10% buffered formaldehyde) for at least 24 hours and burn this in the disposal process.
    CAUTION: Formaldehyde is toxic, perform this step under a hood.

2. Preparation of Solutions for Substances

NOTE: Prepare working solutions and controls immediately before use.

CAUTION: Handle substances according to safety instructions or, if unknown, as potentially harmful and follow routine safety precautions.

  1. Dissolve water-soluble substances directly in the culture medium. For insoluble or poorly soluble chemicals, first dissolve the substance in the appropriate solvents depending on substance solubility. Substances with limited water solubility (<0.1 mg/mL) can be dissolved, for example, in dimethyl sulfoxide (DMSO) or ethanol. Non-toxic solvent concentrations should be determined by titration beforehand. Make sure the substances do not precipitate out of the solution when diluted into the medium.
    NOTE: ammonium hexachloroplatinate (HClPt) and sodium laureth sulfate (SLS) solutions are prepared.
  2. Prepare substance stock solutions at 100-fold of the desired highest concentration in the culture medium or solvent. Weigh 12.5 mg HClPt and 34.4 mg SLS and prepare stock solutions by dissolving the chemicals in 1 mL culture medium.
    NOTE: No solvent is required for these chemicals.
  3. Prepare a final dilution of 1:100 in a pre-warmed medium. In the case of prior use of solvent, this approach results in the same final solvent concentration for all substance concentrations.
  4. Use the final solvent concentration (e.g., 1% as described in step 3.3) for reference treatment of PCLS. No solvent control was required for the chemicals mentioned in the results section.

3. Positive and Negative References for Cytotoxicity Assays

  1. For all viability assays, prepare the following positive and negative controls:
    1. Tissue control: incubate PCLS in a culture medium only as a reference for untreated PCLS for 24 h at cell culture conditions (37 °C, 5% CO2, 100% humidity).
    2. Vehicle control (if necessary): incubate PCLS with the final solvent concentration as a reference for PCLS treated with vehicle only (see step 3.4) for 24 h at cell culture conditions (37 °C, 5% CO2, 100% humidity).
    3. Positive control: incubate PCLS with 1% detergent in buffer solution for 1 h at 4 °C.     
      NOTE: If PCLS becomes colorless, the tissue is dead. Total L-lactate dehydrogenase (LDH) is determined in the supernatant, with an absorption of approximately 1.9 – 2.3. The tissue is used for the WST-1 assay, with an absorption of approximately 0.

4. Measurement of Chemically-induced Cytotoxicity in Human PCLS by water-soluble tetrazolium salt (WST-1) Assay

NOTE: The WST-1 assay is performed in a 24-well plate with two PCLS per well. Preferably, use duplicates for each parameter and pool the results of these duplicates after measurement.

  1. Prepare the working solution by diluting the WST-1 reagent in the medium immediately before starting. The required amount of working solution is 250 µL/well of a 24-well plate. Therefore, mix 25 µL of the reagent with 225 µL of the culture medium for one well.
  2. After incubation of PCLS from step 1.16, discard or use the supernatant for cytokine measurements or other tests such as the LDH assay. The remaining tissue is used for the next step.
  3. Pipet 250 µL of the working concentration of the WST-1 reagent per well and incubate the plate at 37 °C and 5% CO2 for 1 h. Ensure that the PCLS are fully covered by the WST-1 reagent during incubation.
  4. Place the plate on an orbital shaker (200 rpm) and shake carefully for 30 s to ensure thorough mixing of the WST-1 reagent. Take a new flat-bottom 96-well plate and pipet 100 µL in duplicates from the supernatant of each well of the 24-well plate.
  5. Measure the absorption of each well at 450 nm (reference: 630 nm) using a microplate reader. Subtract the absorption at 630 nm from 450 nm. NOTE: Reliable data for cytotoxicity assessment can be obtained only from viable tissue. Therefore, these acceptance criteria published should be met in each experiment. If these criteria are not met, the experiment should be repeated.
  6. Absorption of the untreated medium control should be above 0.6, otherwise, the experiment should be repeated. If the data meet this requirement, set the absorption value of the tissue control to 100% and calculate the WST-1 reduction of treated samples in relation to the tissue control.

開示

The authors have nothing to disclose.

Materials

Silicon hose 3.0 x 5.0 mm A. Hartenstein (Leipzig, Germany) SS04
Syringe Faust Lab Science (Klettgau, Germany) 9.410 050
Coring tools custom-made custom-made
Trimming Blade Handle (FEATHER) pfm medical ag  (Cologne, Germany) 205530001
Trimming Blades (FEATHER) pfm medical ag  (Cologne, Germany) 205500000
Microtome: Tissue Slicer Alabama R&D (Bad Homburg, Germany) 303400-ADPT Krumdieck Tissue Slicer (MD6000)
Microtome blade Wilkinson Sword (Solingen, Germany) ENR-4027800011506
Cell strainer filter (100 µm Nylon) Becton Dickinson (Heidelberg, Germany) BD352360
Inoculation loop Copan Diagnostics (Murrieta, USA)  CD176S01
TPP Tissue culture plates 24wells Sigma (München, Germany) Z707791-126EA
Nunc MaxiSorp flat-bottom Fisher Scientific GmbH (Hannover, Germany) 44-2404-21
Nunc MicroWell 96-Well  Thermo Scientific (Schwerte, Germany) 260836
Multiwell-Reader Tecan Group Ltd. (Männedorf, Switzerland) Tecan infinite F200Pro Plate Reader
Plate shaker Edmund Buehler GmbH (Hechingen, Germany) KM-2 Akku
Assays
Cell Proliferation Reagent WST-1 Roche (Basel, Switzerland) 11644807001
Reagents
Agarose, low gelling temperature  Sigma (München, Germany) A9414-100G
Balanced Salt Mixtures and Solutions, Cell Culture, Classic Media and Salts, Earle's Balanced Salts (EBSS) Sigma (München, Germany) E2888-500ML
Penicillin and streptomycin Lonza (Verviers, Belgium) 17-602E
Dulbecco´s Modified Eagle´s Medium Nutrient Mixture F-12 Ham (DMEM F-12) Gibco (Darmstadt, Germany) 11039-047 Culture medium
Dulbecco´s Phosphate with Ca and Mg (DPBS) Lonza (Verviers, Belgium) BE17-513F   Buffer solution
Detergent Sigma (Saint Louis, USA) X100-100ML Triton X-100

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記事を引用
An Assay to Measure Chemically-Induced Cytotoxicity in Human Precision-Cut Lung Slices. J. Vis. Exp. (Pending Publication), e21848, doi: (2023).

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