Summary

The Culture of Primary Motor and Sensory Neurons in Defined Media on Electrospun Poly-L-lactide Nanofiber Scaffolds

Published: February 15, 2011
doi:

Summary

Aligned electrospun fibers direct the growth of neurons in vitro and are a potential component of nerve regeneration scaffolds. We describe a procedure for preparing electrospun fiber substrates and the serum-free culture of primary rat E15 sensory (DRG) and motor neurons. Visualization of neurons by immunocytochemistry is also included.

Abstract

Electrospinning is a technique for producing micro- to nano-scale fibers. Fibers can be electrospun with varying degrees of alignment, from highly aligned to completely random. In addition, fibers can be spun from a variety of materials, including biodegradable polymers such as poly-L-lactic acid (PLLA). These characteristics make electrospun fibers suitable for a variety of scaffolding applications in tissue engineering. Our focus is on the use of aligned electrospun fibers for nerve regeneration. We have previously shown that aligned electrospun PLLA fibers direct the outgrowth of both primary sensory and motor neurons in vitro. We maintain that the use of a primary cell culture system is essential when evaluating biomaterials to model real neurons found in vivo as closely as possible. Here, we describe techniques used in our laboratory to electrospin fibrous scaffolds and culture dorsal root ganglia explants, as well as dissociated sensory and motor neurons, on electrospun scaffolds. However, the electrospinning and/or culture techniques presented here are easily adapted for use in other applications.

Protocol

1. Poly-L-lactic Acid (PLLA) Spinning Solution

  1. Dissolve 0.4 g PLLA in 9 mL chloroform by stirring over low heat.
  2. Add 1 mL dimethylformamide to the solution, bringing the final concentration of the solution to 4% PLLA (w/v) in chloroform:DMF 9:1 (v/v).
  3. Place the solution in a polypropylene or glass syringe with a blunt 23ga metal tip.

2. Spinning Substrate Preparation1

  1. Make an 8% (w/v) solution of 85:15 PLGA (poly-lactic-co-glycolic acid) in chloroform by stirring over low heat.
  2. Coat clean glass cover slips in PLGA by covering the surface of each cover slip with the PLGA solution. Allow the PLGA to dry to a thin film (approx. 30 min).

3. Electrospinning2

  1. Secure PLGA coated glass cover slips to collector with conductive carbon tape. For aligned fibers, the collector is a motor-driven wheel. For random fibers, the collector is a stationary plate.
  2. Place syringe in pump with tip 20 cm from collector wheel. Set pump to approximately 2 mL/hr and if using a wheel, set the motor to 300-400 RPM. If possible, apply a -2 kV DC bias to the collector and +15 kV to metal tip. In the absence of access to a bipolar power supply, ground the collector.
  3. Fibers will jet from the syringe tip and collect on the rotating wheel. Continue spinning until the desired density of fibers is obtained. Swipe the metal tip with a paper towel affixed to a non-conductive rod periodically to prevent clogging at the tip.

4. Moating1

  1. Following spinning, ‘moat’ the electrospun samples by pipetting a line of PLGA around the perimeter of the cover slip. Allow the PLGA to dry. This will maintain the alignment of the fibers during culture.

5. Protein Coating

  1. Electrospun fibers and glass controls need to be coated in protein prior to cell culture. Cover the substrates in a protein solution for at least one hour and then aspirate excess solution and continue aspirating until the substrates are dry. Possible protein solutions include: PLL (poly-L-lysine) (100 µg/ mL), laminin (25 µg/ mL) or fibronectin (50 µg/ mL). If PLL is used, substrates should be rinsed in sterile water and dried twice following the initial coating.

6. Obtain E15 Rat Embryos3

*All experiments were done in accordance with the NIH Guide for Care and Use of Laboratory Animals as approved by the University of Michigan Committee on Use and Care of Animals.

  1. Preparation: Check if the animal is pregnant. Thaw 3 mL trypsin, 3 mL FBS and warm a bottle of L15. Fire polish a Pasteur pipette. Disinfect all surgical instruments in 70% ethanol for 30 min.
  2. Prepare and warm plating media (see Table 1).
  3. Euthanasia: Perform an IP injection of ketamine/xylazine. Wait 10-15 minutes and check for lack of corneal and pedal withdrawal reflexes. Once reflexes are absent, perform an IC injection of pentobarbital (FatalPlus).
  4. Tent the skin of the abdomen. Cut through the skin and muscle layers to expose the abdominal cavity. Locate the uterus and detach it at the cervix and ovaries.
  5. Remove the embryos from the uterus with scissors and place them immediately into warm L15. (All the following procedures are completed under a dissecting microscope and embryos and dissected cords should be submerged in warm L15 at all times.) Decapitate the embryos by closing forceps around the chin and below the occipital bone of the skull.

7. Dissection3

  1. Place the embryo on one side. Protect the spinal cord with one set of forceps while using the other set to strip away limbs and abdominal organs.
  2. Turn the embryo and hold it steady with one set of forceps. Snip along the length of the embryo, from the neck to the tail, until the entire cord is exposed.
  3. Grasp the end of the cord carefully and pull it over itself towards the tail to remove. The cord will pull free with membrane and dorsal root ganglia (DRG) attached.
  4. If DRG explant or dissociated sensory neuron culture is to be performed, snip the DRG off the cord and transfer them to a fresh dish of warm L15.
    1. For DRG explant culture, skip to step 10.2
    2. For dissociated sensory neuron culture, skip to step 9
    3. For motor neuron culture, the DRG will be removed with the membrane in step 7.5
  5. Remove the membrane from the spinal cord by grasping it at the top end of the cord and peeling it down, similar to removing a long sock. Repeat for all embryos and then chop the cords into small (2-3 mm) pieces.

8. Motor Neuron (MN) Processing5,6,7

  1. Pour the chopped cords and L15 into a conical and spin at 1000 RPM for 2-3 min to pellet the pieces.
  2. Pour off the supernatant and add 3 mL of trypsin to the pelleted cords. Incubate in a 37°C water bath for 20 min.
  3. Add 3 mL FBS to conical and spin at 1000 RPM for 2-3 min to re-pellet.
  4. Pour off the supernatant and coat a fire polished Pasteur pipette with FBS.
  5. Add one Pasteur pipette-full of L15 to the conical and then triturate gently until the solution is homogenous with no visible clumps. Avoid bubbles.
  6. Prepare a 9% solution of Optiprep in L15. Prepare one tube with 3 mL of the Optiprep solution for every two embryos (if there is an odd number of embryos, round up).
  7. Drop the homogenized solution onto the Optiprep solution, dividing it evenly among all the tubes. Spin the tubes at 2000 RPM for 15 min.
  8. Carefully collect the top 2 mL from each tube and pool in a 50 mL conical. Fill the conical with L15 and spin at 1000 RPM for 5 min to rinse the cells of Optiprep.
  9. Pour off the supernatant and resuspend the cells in a small amount of plating media (250-500 µl). Count the cells using trypan blue exclusion to identify live cells. Skip to step 10.1

9. Sensory Neuron (SN) Processing7

  1. Pour the DRG removed from the spinal cords and L15 into a conical tube and spin at 1000 RPM for 2-3 min to pellet the pieces.
  2. Pour off the supernatant and add 3 mL of trypsin to the pelleted DRG. Incubate in a 37°C water bath for 10 min.
  3. Add 3 mL FBS to conical and spin at 1000 RPM for 2-3 min to re-pellet.
  4. Pour off the supernatant and coat a fire polished Pasteur pipette with FBS.
  5. Add one Pasteur pipette-full of L15 to the conical and then triturate gently until the solution is homogenous with no visible clumps. Avoid bubbles.
  6. Spin the homogenate at 1000 RPM for 5 min. Pour off the supernatant and resuspend the cells in a small amount of SN plating media (250-500 µl). Count the cells using trypan blue exclusion to identify live cells. Continue to step 10.1

10. Plating and Culture

  1. For dissociated SN or MN culture:
    1. Cover the substrates with a few drops of media then add an appropriate volume of cell suspension. Dissociated cells should be plated at a low density (25-50 cells/mm2). Allow the cells to adhere for at least one hour before flooding the wells with media.
  2. For DRG explant culture:
    1. Cover the substrates with a few drops of media then add DRG to the media. Arrange the DRG so they are evenly distributed across the substrate (approximately 4 DRG will fit on a 22×22 mm cover slip). Allow the DRG to adhere for at least 4 hrs before flooding the wells with media.
  3. Cultures can be maintained for up to 4 days without media change. For longer cultures, half media changes should be done with feed media. Feed media is the same composition as plating media minus the L-glutamine.

11. Immunocytochemistry1,5,8

  1. Fixing cells: Aspirate media and replace with warm 4% PFA (paraformaldehyde) for 30 min. Then perform 3X 5 min 1x PBS washes.
  2. Blocking/permeabilization: Prepare block/perm solution (1.25% bovine serum albumin in 1X PBS, 0.05% Triton X-100 and 2.0% normal goat serum). Aspirate PBS and apply block/perm solution to samples for 30 minutes. Then perform 1X 5 min 1x PBS washes.
  3. Primary antibody: Prepare primary antibody working solution (10% normal goat serum, 1.25% bovine serum albumin, 0.1% Na azide, 0.05% Triton X-100 and to 10 mL with 1x PBS). Add the appropriate amount of primary antibody (see Table 2). Line several dishes with parafilm. Place a 200µl bead of primary antibody solution on the parafilm for each substrate. Invert the substrates, floating them cell side down on the primary antibody working solution overnight (if the room is air conditioned or particularly dry, a piece of water saturated paper can be added to a corner of the dish to prevent evaporation of the working solution).
  4. Secondary antibody: Remove the substrates from the primary (the working solution can be collected, stored at 4°C and reused) and perform 2X 5 min 1x PBS washes. Apply 200 µl secondary antibody diluted 1:200 in PBS (also inverted on parafilm lined dish) for 4 hr.
  5. Remove from secondary then perform 2X 5 min 1x PBS washes. Mount substrates on slides with Prolong Gold containing DAPI or another suitable nuclear counter stain.

12. Representative Results:

The typical morphology of aligned and random electrospun fibers are shown in Figure 1. We typically obtain MN purity of >90% neurons7,8 with this protocol and we have maintained DRG cultures for as long as one week without any significant fibroblast growth. Figure 2 shows typical MN appearance on glass and fibers after 24 hrs of culture and immunostaining. Immunostained DRG cultured for three days on glass and fibers are depicted in Figure 3.

Figure 1
Figure 1. Fiber alignment is manipulated by choice of collector. A.) Aligned fibers spun onto a rotating wheel collector and B.) random fibers spun onto a stationary plate collector. Scale bars = 20 μm.

Figure 2
Figure 2. Representative motor neurons stained for TuJ1 (green) and DAPI (blue) after 24 hrs of culture on PLL coated A.) fibers and B.) glass. Scale bars = 20 μm.

Figure 3
Figure 3. Representative DRG stained for neurofilament (green) after 3 days of culture on PLL coated A.) glass and B.) fibers. Scale bars = 200 μm.

Stock solution: MN media: DRG/SN media:
10 mg mL-1 albumin 12.5 μl
10 mg mL-1 apo-transferrin 50 μl 40 μl
50 μg mL-1 β-estradiol 2.7 μl 2.2 μl
0.1 mg mL-1 biotin 50 μl
16 mg mL-1 catalase 8 μl
15 mg mL-1 D- galactose 50 μl
50 μg mL-1 hydrocortisone 3.7 μl 2.9 μl
0.63 mg mL-1 progesterone 0.5 μl
16 mg mL-1 putrescine 50 μl
50 μg mL-1 selenium 3.4 μl 4.1 μl
2.5 mg mL-1 superoxide dismutase 50 μl
* 500 ng mL-1 nerve growth factor 1 mL
* 100X PSN 0.5 mL 0.5 mL
* B27 1 mL 1 mL
* 2 mM L-glutamine 35 μl 35 μl
* Neurobasal to 50 mL to 50 mL

Table 1. Add starred (*) components to media just prior to use. The remaining components can be prepared as a stock solution and kept at -20°C until needed6,7.

Primary (concentration) Neurons: Glia: Fibroblasts:
anti-β-tubulin (TuJ1) (1:1000) X X
anti-neurofilament (1:1000) X X
anti-S-100 (1:250) X
anti-NGFR p75 (1:500) X

Table 2. The selection of primary antibody is dependent on the goals of the investigator. The above are several antibodies and the concentrations we have used with success in our laboratory. S-100 is particularly useful to identify Schwann cells and/or check for contaminating fibroblasts, but note that it must be used in combination with NGFR p75 to distinguish between glia and fibroblasts4. We have also noticed that NGFR p75 stains neurites very lightly while neurofilament or TuJ1 are excellent choices if the goal is to visualize individual neurites.

Discussion

This protocol has several critical steps. The first involves the proper production of the electrospun fiber substrates. In liquid media, the PLLA fibers, PLGA film and PLGA moat will separate from the glass cover slip as a single unit. If the PLGA is omitted, the PLLA fibers will not remain a flat sheet – they will curl up into an unusable tangle. Thus, the PLGA film is included as a suitable substrate to maintain fiber alignment during culture. The moat is added after spinning both to ensure that the fibers are securely fixed to the PLGA film and to add structural rigidity to the film. The moat also serves as a useful handle when the substrates are manipulated during fixing, staining and mounting. Trituration is the second critical step. Every effort should be made to avoid the formation of bubbles. Additionally, we have obtained much higher yields when a fire-polished pipette is used for this step. To fire polish, light a Bunsen burner and attach a bulb to the pipette. Pass the tip of the pipette quickly through the flame 2-3 times while continuously squeezing and releasing the bulb – air flow through the pipette will help prevent the tip from closing completely. Examine the tip of the pipette to ensure the hole is still open and that the edges appear slightly rounded before use.

Electrospinning is a very versatile process; the electrospinning parameters can be modified to produce fibers with a variety of morphologies. Tan et al. (2005) details a systematic study of parameters affecting the diameter of PLLA electrospun fibers. Wang et al. (2009) presents a detailed study of the parameters influencing the alignment of electrospun PLLA fibers.

Divulgations

The authors have nothing to disclose.

Acknowledgements

NIH K08 EB003996

Materials

Material Name Type Company Catalogue Number Comment
PLLA   Boehringer Ingelheim Resomer L210  
PLGA 85:15   Sigma 43471  
L15   Gibco 11415  
Albumin   Sigma A2289  
Apo-transferrin   Akron AK8227  
Biotin   Fisher AC 23009-0010  
Galactose   Sigma G0625  
Progesterone   Sigma P7556  
Putrescine   Sigma P5780  
Selenium   Sigma S9133  
β-estradiol   Sigma E 1132  
Hydrocortisone   Sigma H0396  
Catalase   Sigma C40  
Superoxide dismutase   Sigma S4636  
Neurobasal   Gibco 21103-049  
PSN   Gibco 15640  
L-glutamine   Nalgene 1680149  
Trypsin   Nalgene 1689149  
Fetal bovine serum   Gibco 26140  
Optiprep   Accurate 2011  
PLL   Sigma P4832  
Fibronectin   Sigma F 4759  
Laminin   Invitrogen 23017-015  
B27   Gibco 17504-044  
BSA   Sigma A7906  
Anti-TuJ1   BD Biosciences 556321  
Anti-neurofilament   Millipore AB1987  
Anti-S100   Sigma S2532  
Anti-NGFR p75   Sigma N3908  
Normal goat serum   Sigma G6767  
Triton X-100   Sigma T9284  
Sodium azide   Sigma S8032  
Carbon tape   Ted Pella 13073-1  
Prolong Gold +DAPI   Invitrogen P36931  

References

  1. Corey, J. M., Gertz, C. C., Wang, B. S., Birrell, L. K., Johnson, S. L., Martin, D. C., Feldman, E. L. The design of electrospun PLLA nanofiber scaffolds compatible with serum-free growth of primary motor and sensory neurons. Acta. Biomater. 4, 863-875 (2008).
  2. Lin, D. Y., Johnson, M. A., Vohden, R. A., Chen, D., Martin, D. C. Tailored nanofiber morphologies using modulated electrospinning for biomedical applications. Mat. Res. Soc. Symp. Proc. 736, D3.8.1-D3.8.6 (2003).
  3. Banker, G., Goslin, K. . Culturing Nerve Cells. , (1998).
  4. Kameda, Y. Expression of glial progenitor markers p75NTR and S100 protein in the developing mouse parathyroid gland. Cell Tissue Res. 327, 15-23 (2007).
  5. Corey, J. M., Lin, D. Y., Mycek, K. B., Chen, Q., Samuel, S., Feldman, E. L., Martin, D. C. Aligned electrospun nanofibers specify the direction of dorsal root ganglia neurite growth. J. Biomed. Mater. Res. A. 83, 636-645 (2007).
  6. Vincent, A. M., Mobley, B. C., Hiller, A., Feldman, E. L. IGF-I prevents glutamate-induced motor neuron programmed cell death. Neurobiol. Dis. 16, 407-416 (2004).
  7. Russell, J. W., Windebank, A. J., Schenone, A., Feldman, E. L. Insulin-like growth factor-I prevents apoptosis in neurons after nerve growth factor withdrawal. J. Neurobiol. 36, 455-467 (1998).
  8. Gertz, C. C., Leach, M. K., Birrel, L. K., Martin, D. C., Feldman, E. L., Corey, J. M. Accelerated neuritogenesis and maturation of primary spinal motor neurons in response to nanofibers. Dev. Neurobiol. 70, 589-603 (2010).
  9. Tan, S. -. H., Kotaki, M., Ramakrishna, S. Systematic parameter study for ultra-fine fiber fabrication via electrospinning process. Polymer. 46, 6128-6134 (2005).
  10. Wang, H. B., Mullins, M. E., Cregg, J. M., Hurtado, A., Oudega, M., Trombley, M. T., Gilbert, R. J. Creation of highly aligned electrospun poly-L-lactic acid fibers for nerve regeneration applications. J. Neural Eng. 6, (2009).

Play Video

Citer Cet Article
Leach, M. K., Feng, Z., Gertz, C. C., Tuck, S. J., Regan, T. M., Naim, Y., Vincent, A. M., Corey, J. M. The Culture of Primary Motor and Sensory Neurons in Defined Media on Electrospun Poly-L-lactide Nanofiber Scaffolds. J. Vis. Exp. (48), e2389, doi:10.3791/2389 (2011).

View Video