Summary

Dual Labeling of Neural Crest Cells and Blood Vessels Within Chicken Embryos Using ChickGFP Neural Tube Grafting and Carbocyanine Dye DiI Injection

Published: May 28, 2015
doi:

Summary

Here we report dual labeling of neural crest cells and blood vessels using chickGFP neural tube intraspecies grafting combined with intra-vascular DiI injection. This experimental technique allows us to simultaneously visualize and study development of the NCC-derived (enteric) nervous system and the vascular system, during organogenesis.

Abstract

All developing organs need to be connected to both the nervous system (for sensory and motor control) as well as the vascular system (for gas exchange, fluid and nutrient supply). Consequently both the nervous and vascular systems develop alongside each other and share striking similarities in their branching architecture. Here we report embryonic manipulations that allow us to study the simultaneous development of neural crest-derived nervous tissue (in this case the enteric nervous system), and the vascular system. This is achieved by generating chicken chimeras via transplantation of discrete segments of the neural tube, and associated neural crest, combined with vascular DiI injection in the same embryo. Our method uses transgenic chickGFP embryos for intraspecies grafting, making the transplant technique more powerful than the classical quail-chick interspecies grafting protocol used with great effect since the 1970s. ChickGFP-chick intraspecies grafting facilitates imaging of transplanted cells and their projections in intact tissues, and eliminates any potential bias in cell development linked to species differences. This method takes full advantage of the ease of access of the avian embryo (compared with other vertebrate embryos) to study the co-development of the enteric nervous system and the vascular system.

Introduction

The chicken embryo is an invaluable model organism in vertebrate developmental biology, not least because its development in ovo permits experimental manipulations that are otherwise impossible to perform in vertebrates that develop in utero. This accessibility and ease of manipulations has led to the chick embryo playing key roles in many seminal discoveries in the field of developmental biology. Amongst the most powerful techniques has been the use of quail-chick chimeric embryos to study cell fate, a method pioneered by Professor Nicole Le Douarin in the 1970’s1-3. In particular, quail-chick chimeras have been especially useful to genetically mark and follow highly migratory neural crest cell (NCC) populations during early development. NCC are a multipotent population of migratory cells, arising in the dorsal ectoderm at the margins of the neural tube, that give rise to a wide range of cell types throughout the vertebrate embryo. These include craniofacial structures (cartilage, bone, muscles), neurons and glia (in the sensory and autonomic nervous systems), melanocytes, and a subpopulation of cells of the endocrine system2,4,5. One of the most important factors influencing NCC fate is their initial location along the anterior-posterior axis of the neural tube. For example, enteric NCC, which give rise to the neurons and glia of the enteric nervous system (ENS), arise from two discrete sub-populations: the first located in the vagal (caudal hindbrain) region, and the second in the sacral region of the neural tube6-13. Inter or intra-species grafting of the corresponding regions of the neural tube have been the techniques of choice to permanently label these cells and subsequently allow tracking, from their birth on the margins of the neural tube, to their final destinations within the digestive tract6,7,10.

Another embryonic manipulation easier to perform in chick, compared to other animal models, is the vital labeling of the vascular system. Indeed, as the chick embryo develops, it lays on top of an extra-embryonic vascular network that circulates oxygen and nutrients from the yolk. This accessible vascular network, located on the surface of the yolk, can be used as a gateway to label the embryo’s developing vascular system during organogenesis12,14-17. Intravascular injection of various dyes, such as the lipophilic dye DiI, makes it possible to delineate/stain all the luminised vessels of the nascent vascular network.

Because developing organs need to be connected to both the nervous system (for sensory and motor control) as well as the vascular system (for gas exchange, fluid and nutrient supply), the two networks develop alongside each other and share striking similarities in their branching architecture18-20. Here we report embryonic manipulations that allow us to study the simultaneous development of the NCC-derived ENS, along with the vascular system, during organogenesis. This is achieved by generating chicken chimeras via transplantation of discrete segments of the neural tube, including the neural crest, combined with vascular DiI injection. As an advance from quail-chicken chimeras, our method uses transgenic GFP chick embryos for intraspecies grafting, making the transplant technique more powerful, in terms of imaging cells and their projections, and eliminating any potential bias linked to species differences.

Protocol

1. Preparation of Micro-scalpel for Neural Tube Ablations

  1. Shape a micro-scalpel from a commercially available steel sewing needle.
    1. First flatten the needle on both sides using a grinding wheel mounted on a powered bench grinder.
    2. Start shaping the scalpel, first on a coarse grade Arkansas stone using a controlled circular motion, in alternate directions, on both sides of the needle.
    3. Carry on the same sharpening movements on an extra fine grade Arkansas stone to shape an ultra fine micro-scalpel, with a well defined cutting edge (Figure 1A, B).
      NOTE: Alternatives to the micro-scalpel could be electrolitically sharpened needles, commercially available tungsten needles, or pulled glass needles.

2. Incubate Wild Type and GFP Eggs to the Desired Stage

  1. Store fertilized chicken eggs and transgenic GFP chicken eggs in a cooled incubator at 14 – 15 °C prior to incubation as development is halted at this temperature. Store eggs for a few days, up to one week.
  2. To commence development, place wild type and GFP eggs on a tray horizontally and incubate simultaneously in a humidified (58 – 60%) incubator at 37.5 ºC, so that embryos are at matching stages for neural tube grafting.
  3. To obtain embryos at the 10 – 12 somite stage of development for carrying out vagal neural tube grafting, incubate eggs for 1.5 days (33 – 38 hrs) and stage embryos according to the development tables of Hamburger and Hamilton21.

3. Prepare Eggs for Windowing and Grafting

  1. Move one egg at a time to a custom-made egg holder for windowing. Make a small hole in the egg shell by repeatedly tapping, with straight scissors, on the upper surface of the pointed end of the egg.
  2. Remove 2 – 3 ml of albumin from the egg with an 18½ G hypodermic needle and 5 ml syringe. Removing the albumin lowers the yolk within the egg and facilitates subsequent windowing without causing any damage to the embryo.
    1. Discard the albumin. Seal the hole with a small strip of clear tape cut to size with fine scissors.
  3. Using curved scissors, tap another hole in the upper surface of the egg shell. Insert the tip of the scissors into the hole and, keeping the scissors parallel to the bench, work in a circular motion to cut a ~2 cm diameter window on top of the shell.
    1. Keep the scissors in a stationary position and rotate the egg. Discard the removed disk of egg shell. At E1.5, the embryo is recognizable as a darker yellow disk on top of the yolk.
    2. Remove any shell debris that has fallen within the egg using tweezers. Discard any unfertilized eggs (identified by a small white spot on top on the otherwise light yellow yolk).

4. Prepare the Host Embryo to Receive Grafted Tissue

  1. Adjust the stereo-microscope to eye level and optimize the orientation of gooseneck light source to adequately illuminate the embryo without causing reflections.
  2. To visualize the embryo proper, inject a small amount of Indian ink under the center of the darker yellow disk, using a mouth tube and a pulled glass micro-pipette (Figure 1C, Oii).
    1. Prepare the ink 50:50 with PBS containing Penicillin/Streptomycin at 100 μg/ml final concentration. Insert the micro-pipette through the yolk membrane outside the perimeter of the blastoderm then carefully angle its tip directly beneath the embryo.
    2. Deliver ink underneath the embryo by blowing on the mouth tube. If mouth pipetting is not permitted, use a 1 ml syringe instead. Be careful not to introduce any air bubbles underneath the embryo, which can lead to contamination, then carefully remove the glass micro-pipette. This is a delicate step that can lead to the death of the embryo if not done with precision.
  3. Stage the embryo by reference to Hamburger and Hamilton21 and record the stage in a lab book.
  4. Using a custom made micro-scalpel (or a fine tungsten needle) mounted on a needle holder, make a very small gash in the vitelline membrane, next to the area where the micro-surgery will be performed.
    1. Carefully apply 2 – 3 drops of PBS over the membrane tear (using a glass micro-pipette and the mouth tube) to create space between the embryo and the membrane. Cut a larger window in the membrane to expose the entire region where the micro-surgery will take place.
  5. Remove the neural tube region of interest using the micro-scalpel, starting with rostral and caudal transverse incisions across the entire dorsal neural tube (at the level of somite 1 to 7 in the video).
    1. Cut bilaterally between the neural tube and the somites to separate the neural tube from surrounding tissues, without damaging the somites.
    2. Very gently separate the neural tube from the underlying notochord, which should remain intact. Note that successful neural tube excision will leave all surrounding tissues perfectly intact (Figure 2).
    3. Remove the excised neural tube by aspirating it into a glass micro-pipette, then discard.
  6. Record the level of neural tube ablation in a lab book. The host embryo is now ready to receive the donor neural tube.

5. Prepare the Donor Graft Tissue

  1. Select a windowed, stage-matched GFP embryo by viewing under a fluorescent stereo-microscope with FITC filter. The GFP fluorescence makes it very easy to visualize the somites and stage the embryo.
  2. Once a stage-matched embryo has been identified, remove the embryo from the egg by making 4 incisions, with Pascheff-Wolff spring scissors (Figure 1C, l) in a rectangle shape around the embryo then gently pick it up with an embryo spoon.
  3. Place the embryo in a square watch glass with a sylgard polymer base. Gently shake the embryo with Dumont #5 tweezers to remove any attached yolk. Remove the vitelline membrane and pin the embryo onto the polymer base using stainless minutien pins (Figure 1C).
  4. Using the Spring Scissors, make 4 incisions in a rectangular shape around the neural tube and surrounding somites, in the same region that has been removed from the host embryo.
  5. Using a plastic transfer pipette, transfer the neural tube and somite tissues from the donor GFP embryo into a watch glass containing 0.2% pancreatin in Pen/Strep PBS.
  6. Allow enzymatic digestion to proceed for 10 min at RT to help separate the tissues. After incubation in enzyme, use stainless minutien pins mounted on a handle to manually separate the neural tube from all adjacent tissues.
  7. Using a glass micro-pipette, transfer the dissociated neural tube to another watch glass containing DMEM + 10% serum (e.g., goat, horse or fetal calf) on ice, to rinse the excess pancreatin and stop enzymatic digestion. After 5 min, the dissected neural tube is ready to be grafted orthotopically into the chick host (Figure 2 and S1).

6. Graft the Tissue

  1. Using a glass micro-pipette, carefully transfer the dissected neural tube from the watch glass to the host embryo. Position the neural tube in the correct anterior-posterior orientation and gently push the explant adjacent to the excised region of the chick host using the micro-scalpel. Leave a small fragment of ectoderm attached to, or by cutting a small nick in, the dorsal surface to identify the orientation of the neural tube.
    1. If necessary, use the micro-scalpel to trim the explant to the exact size of the excised region.
  2. Gently guide the neural tube into the ablated region and position it such that the dorsal side is correctly orientated. Use a glass micro-pipette, mounted to a mouth tube, to remove PBS and/or fluid surrounding the graft. This helps the donor and host tissues to adhere and the graft to become established.
  3. Seal the entire window with 24 mm wide clear tape to prevent dehydration and contamination.
  4. Label the chimeric embryo by marking with a pencil on the eggshell and record its number in the lab book. Return the egg to the incubator for further development.

7. Inject DiI into Blood Vessels of Host Embryo

  1. At the desired experimental time point (here, 3 – 10 days later), retrieve the chimeric embryo from the incubator and remove the clear tape using straight scissors to gain access to the embryo within the egg.
  2. If necessary, enlarge the window in the shell using the scissors. Be careful not to damage the chorioallantoic membrane if it is attached to the shell, which would result in hemorrhage and jeopardize the blood vessel labeling.
  3. Choose an accessible vein on the yolk making sure the blood flow is directed towards the embryo. Choose a branching point of one of the vitelline veins (Figure 3B, C).
    NOTE: At E6.5 – E7.5, the chorioallantoic membrane may need to be gently moved aside with tweezers to access the yolk veins. After E8.5, the only option is to inject into one of the chorioallantoic membrane veins since, by this stage, the chorioallantoic membrane fully covers the embryo.
  4. Remove the vitelline membrane above the chosen injection point using two Dumont #5 tweezers by tearing in opposite directions.
  5. Break a pulled glass needle using a Dumont #5 and adjust its diameter to the approximate size of the vein prior to loading with CellTracker CM-DiI. Make the DiI stock solution at 40 µg/µl in DMSO and store at -20 °C. Prepare the working solution in 0.3 M sucrose/PBS at a concentration of 4 µg/µl.
    1. Aspirate between 5 – 10 µl of DiI in 0.3 M sucrose/PBS into the needle using suction with a mouth tube. Older embryos might require up to 25 µl or more. From E8.5, embryos have larger, more muscular veins, which may need to be held in position with a Dumont #5 before stabbing with the DiI-loaded glass needle.
  6. Swiftly insert the needle into the vein and blow steadily with the mouth tube to allow the DiI to join the blood flow slowly without forming a clot. Alternatively, use a pressure injector for DiI delivery.

8. Harvest Embryos for Sectioning or Wholemount Examination

  1. To retain as much DiI within the embryo as possible, harvest the embryo immediately after the injection by scooping it onto a perforated spoon and cutting the blood vessels and connective tissues with a pair of straight scissors, to free the embryo from the yolk.
  2. Remove any loose membranes and dissect out the organs of interest (i.e., the lungs and digestive tract in this tutorial), taking great care not to compress the tissue, which creates diffusion of the DiI. Immediately fix the tissues by immersion in 4% PFA for 1 – 2 hrs at RT.
  3. Rinse the tissue for 5 min in PBS, then 15 min in PBS containing 5 μg/ml DAPI. Mount the samples on a bridged microscope slide for whole mount examination or embed them for cryo-sectioning.

Representative Results

Figure 1 shows typical instruments required to carry out microsurgical isolation and transplantation of the neural tube. Figure 2 shows the transplant procedure. Following transplantation embryos are screened for transplant success. This involves examining the embryo under a stereo fluorescence microscope, typically the morning after microsurgery, for the presence of graft-derived (GFP+) NCC. If transplantation has been a success, then GFP+ NCC can be observed in the vicinity of the neural tube and in early migration pathways leading toward the foregut. If the procedure has not been successful, GFP+ NCC will not be observed outside the neural tube, or if they are present in the host they may be in smaller numbers. These unsuccessful embryos are discarded. Typically, 5-8 neural tube transplants are performed in one day, and of these 80% are successful. Reasons for unsuccessful neural tube transplantation include death of the embryo due to tissue damage incurred during microsurgery, or failure of the neural tube to integrate into the host embryo. The latter can result from poor placement of the neural tube within the host or from a poor quality neural tube due to poor dissection technique or from excessive exposure to dissociation enzyme. The initial screening step, as well as similar later examinations for GFP+ cells, is useful as it means that time and resources are not wasted by performing experiments on embryos that do not have GFP-labelled NCC within the gut.

Figure 3 shows the procedure for DiI injection of the blood vessels. The efficiency/success of the DiI injection technique depends on: first, cutting the injection needle to the optimum diameter for the targeted vein, second a precise gesture when inserting the needle in the vein (so not to pierce through the other side), and third avoiding the needle getting plugged during the injection by blowing at a constant rate. If any of these three parameters is done incorrectly, the embryo will bleed out or will need several hours to recover before a second attempt is made as the hemorrhage makes it almost impossible to re-inject immediately. Successful embryos should be selected immediately by viewing under a stereofluorescence microscope and must be dissected rapidly. In successful embryos, DiI labeled blood vessels are present throughout the embryo (Figure 3C,D) including capillary beds (Figure 3D).

Upon harvesting of embryos and examination of tissue sections or wholemount gastrointestinal tracts, typical results reveal GFP+ NCC within the primitive ENS and the fine structure of the DiI-labeled gut blood vessel networks (Figure 4) Wholemount preparations can be examined using confocal microscopy whereby image stacks produce three dimensional (3D) reconstructions showing the interrelationships between the fine projections of GFP+ ENS cells and the DiI stained vascular system (Figure 4 A-C; G-I; Videos 1 and 2).

Figure 1
Figure 1. Recommended microsurgery instruments. (A) micro-scalpel shaped from a sewing needle. (B) fine Arkansas stone for shaping a micro-scalpel. (C) a) straight scissors, b) curved scissors, c) 5 ml syringe with 181/2 G hypodermic needle, d) plastic pipette, e) custom made egg holder, f) black ink, g) square watch glass, h) square watch glass with black sylgard base, i) micro-scalpel on needle holder, j) minutien pins, k) minutien or tungsten needle on needle holder, l) Pascheff-Wolff spring scissors, m) Dumont #5 tweezers, n) perforated spoon, oi) short fire-pulled transfer needle, oii) long fire-pulled inking needle, p) mouth tube. Please click here to view a larger version of this figure.

Figure 2
Figure 2. Intraspecies neural tube transplant. Chick embryo/GFP neural tube images have been modified from Delalande et al.12. Vascularization is not necessary for gut colonization by enteric neural crest cells. Please click here to view a larger version of this figure.

Figure 3
Figure 3. Intravenous DiI injection. (A) Recommended instruments: a) CellTracker CM-DiI drop on parafilm, b) pulled glass injection needle, c) mouth tube. (B) Schematic diagram of intravenous DiI injection into E4 chimeric chick embryo. (C) in ovo DiI intravenous injection showing fine glass needle containing DiI inserted into vein (arrow). (D) E4 chimeric embryo post DiI injection (red) with GFP+ neural tube (arrow). (E) DiI stained fine blood vessel network in a live embryo, 24 hr post-injection. Br: brain; H: heart; LB: limb bud; A: allantois. Images in (C) and (D) have been modified from Delalande et al.12 Vascularization is not necessary for gut colonization by enteric neural crest cells. Please click here to view a larger version of this figure.

Figure 4
Figure 4: Representative results in the stomach and caecum of an E5.5 chick embryo. (A-C) 3 dimensional (3D) reconstruction of a confocal image stack in the region of the stomach showing (D) the GFP+ enteric neural crest cells (ENCC) (E) the DiI stained vascular system and (F) a merged image of both networks D-F Histological sections at the level of the stomach showing (G) the GFP+ ENCC (H) the DiI stained vascular system and (I) a merged image of both networks. Nuclei are stained with DAPI (cyan).(G-H) 3D reconstruction of a confocal image stack in the caecum region showing (A) the GFP+ ENCC migration front in green, (B) the DiI stained vascular system in red, and (C) a merged image of both networks. Images (A-F) have been modified from Delalande et al.12 Vascularization is not necessary for gut colonization by enteric neural crest cells. Please click here to view a larger version of this figure.

Figure S1
Figure S1. Isolation of a donor GFP+ neural tube from the surrounding tissues by enzymatic digestion and micro-dissection. (A) GFP+ neural tube and adjacent somites dissected from the donor embryo. (B) Isolated neural tube after pancreatin digestion and micro-dissection using stainless minutien pins. So: somites; NT: neural tube; Nc: Notochord.

video 1
Video 1. 3-dimensional 360° rotation of the image in Figure 4C, showing the vascular system and the ENCC in the stomach at E5.5 (HH27-28). Please click here to view this video.

Video 2
Video 2. 3-dimensional 360° rotation of the image in Figure 4I, showing the vascular system and the ENCC migration front in the region of the caecum at E5.5 (HH27-28). Please click here to view this video.

Discussion

The method of intraspecies neural tube grafting, combined with blood vessel labeling described here, takes full advantage of the ease of access of the avian embryo within the egg (compared with other vertebrate embryos) to study the co-development of an element of the autonomic nervous system (the ENS) and the vascular system.

For labeling NCC derivatives, the chickGFP-chick intraspecies grafting method we describe has a number of advantages over the classical quail-chick chimera method that was established over 40 years ago1-3. First, under FITC light, GFP fluorescence is extremely bright, to the extent that GFP+ cells are easily discernable in live chimeric embryos. This allows the success of the graft to be checked in ovo, whereas quail-chick grafting requires the embryo to be killed, processed and immunostained using QCPN, before the success of the graft can be ascertained2. Second, GFP expression in the transgenic chickGFP is cytoplasmic, therefore it not only labels cell bodies, but also allows the projections of the transplanted cells to be visualized22. This permits intricate neuronal networks to be observed at high resolution (note that fine projections are best visualized when the sample is immunostained with anti-GFP antibody). As QCPN labeling is restricted to the quail cell nucleus, such networks are not revealed using quail-chick chimeras. Third, intraspecies grafting eliminates any potential species differences between cells within the chimeric embryo. Since quail embryos have a shorter incubation period than chick (19 days versus 21 days) it has been suggested that quail cells have a higher proliferation rate than chick cells, which could potentially affect the development of the chimeric tissues23. Interestingly also, it has been shown in plants that interspecies grafting could produce extensive alterations in DNA methylation patterns in the host 24. Fourth, chickGFP facilitates back-transplant experiments to address topics such as NCC fate and cell commitment25. Fifth, the transgenic chickGFP is also useful for many other techniques including FACS sorting of GFP+ cell subpopulations, organotypic culture of organs containing GFP+ cells, genetic manipulation of GFP+ grafted tissue via electroporation of expression plasmids26, and other imaging technologies such as optical projection tomography27.

The neural tube transplantation approach can be modified by microsurgically replacing shorter amounts of neural tube. By using smaller segments of neural tube the microsurgery is potentially less damaging to the embryo and survival can be improved. However, the downside of transplanting less neural tube is that the numbers of GFP+ NCC in the host will be reduced. Users could try and achieve a balance between the amount of neural tube transplanted to give optimum survival of embryos, and the numbers of GFP+ NCC within host intestine sufficient to give informative results.

For vessel painting, DiI has the advantage that its fluorescence is very bright and robust. Also, it has the capacity to diffuse during fixation assuring staining of the finest opened capillaries. Since it is a vital dye, embryos can survive the injection procedure and carry on developing with a stained vascular system (up to 24 hr in our hands, although the staining becomes more punctate over time, see Figure 3E). The combination of chickGFP grafting with DiI vascular painting is therefore compatible with live imaging. Besides all these advantages, it is important to note that vascular injection only labels luminised vessels and therefore does not identify unopened capillaries, endothelial tip cells or isolated endothelial cells. However, further progress in avian transgenesis could provide new ways to circumvent such issues, as exemplified by experiments using Tg(tie1:H2B-eYFP) quail embryos to study vascular morphogenesis28. Another limitation of this technique is that, for effective vessel labeling in embryos at E7.5 and beyond, larger amounts of dye need to be injected, which can make experiments expensive. However, a modification of the technique could include low cost blood vessel labelingusing highlighter ink14, although this approach has not been tried in our hands.

Critical steps of the procedures include the process of visualizing the embryo by injecting ink underneath the blastodisc. If the membrane covering the yolk is torn by the ink-filled needle at this stage then embryo survival is severely compromised. Also, it is important, when preparing a donor neural tube, that the tissue is not left for an excessively long time in pancreatin (consider approximately 10 min as a maximum). Prolonged exposure to pancreatin damages the tissue and the neural tube is then difficult to handle and it will not incorporate well into the host. Gaining experience of the DiI injection technique on wild type embryos is essential before injecting chimeric embryos, as only one attempt at injecting is generally possible for each embryo. DiI volume and needle diameter are critical parameters for each embryo and should be assessed on wild type, stage matched controls.  

In conclusion, our dual labeling method of neural tube transplantation and DiI vessel painting in live chick embryos can be used to investigate the inter-relationships between NCC and blood vessel networks during organogenesis. Considering the mechanisms responsible for establishing correct target innervation and vascularization during organ development are still largely unknown, this methodology holds potential for future discoveries in this field.

Disclosures

The authors have nothing to disclose.

Acknowledgements

Fertilised GFP chicken eggs were supplied by Prof. Helen Sang, The Roslin Institute, and University of Edinburgh, UK. The Roslin Transgenic Chicken Facility is funded by the Wellcome Trust and by the Biotechnology and Biological Sciences Research Council (BBSRC). The work was partly funded, and NT supported, by Great Ormond Street Hospital Children’s Charity, London, UK. The authors thank Ben Jevans, UCL Institute of Child Health, for help with preparing embryos for grafting.

Materials

Name of the Material/Equipment  Company  Catalog Number 
Fertilised chick eggs Henry Stewart and Co, Louth, UK
Fertilised GFP chick eggs The Transgenic Chicken Facility, The Roslin Institute, The University of Edinburgh
Egg incubator (Profi-H Hatcher) Lyon Technologies, CA, USA 910-033
14C Incubator Precision Cooled Incubator, Leec Ltd., Nottingham, UK Model LT2
Stereo-microscope  LEICA Model MZ 12.5
Digital Camera LEICA DC500
Image acquisition software LEICA IM50
Goose neck halogen cold light source Advanced Imaging Concepts, Inc KL 1500 LCD 
181⁄2 G hypodermic needle  SIGMA – ALDRICH HSWNH181
Pancreatin SIGMA – ALDRICH P3292
DMEM SIGMA – ALDRICH D5030
Goat serum SIGMA – ALDRICH G6767
5ml syringe SIGMA – ALDRICH Z248010
Mouth tube SIGMA – ALDRICH A5177
Sigma Pasteur pipettes non-plugged, L 5 3/4 in. SIGMA – ALDRICH S6018
Transfer pipettes, polyethylene SIGMA – ALDRICH Z350796 
Borosillicate glass capillaries, thin wall without filament Harvard apparatus PY8 30-0035
Iris Scissors – ToughCut Fine Science Tools 14058-09
Curved Iris Scissors – ToughCut Fine Science Tools 14059-09
Needle holders (Nickel-plated pin holder)  Fine Science Tools 26018-17 
Pascheff-Wolff Spring Scissors  Fine Science Tools  15371-92
Dumont #5 forceps  Fine Science Tools  11251-30 
Minutien pins  Fine Science Tools 26002-15
Dumont AA forceps, Inox Epoxy- coated  Fine Science Tools 11210-10 
Perforated spoon Fine Science Tools 10370-18
Tungsten needles (0.125mm diameter) Fine Science Tools 10130-05
Sellotape (clear, 24mm width) Any Supplier
Pen/Strep (Penicillin, Streptomycin) Solution VWR international 101447-068 
Sylgard 184 silicone elastomer kit Dow Corning S09 512 516
Pelikan black ink Pelikan 211-169
CellTracker CM-DiI  Molecular Probes C-7001
DAPI (4',6-Diamidino-2-Phenylindole, Dihydrochloride) Molecular Probes D1306
Settings for glass needle puller  Sutter Instruments Flaming/Brown micropipette puller model P-86
Heat 950; Pull 150; Velocity 100; Time 200; Pressure 500

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Delalande, J., Thapar, N., Burns, A. J. Dual Labeling of Neural Crest Cells and Blood Vessels Within Chicken Embryos Using ChickGFP Neural Tube Grafting and Carbocyanine Dye DiI Injection. J. Vis. Exp. (99), e52514, doi:10.3791/52514 (2015).

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