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JoVE Journal Medicine

Medicine

Building Affordable, Durable, Medium-Fidelity Ballistic Gel Phantoms for Ultrasound-Guided Nerve Block Training

Published: February 9, 2024 doi: 10.3791/66194
*1, *1, 1, 2, 3
1University of California, San Diego School of Medicine, 2Department of Anesthesia, University of California, San Diego Health, 3Department of Emergency Medicine, University of California, San Diego Health
* These authors contributed equally

Abstract

Ultrasound phantoms - alternatives to live human tissue - give learners the opportunity to practice ultrasound-guided regional anesthesia without introducing undue risk to patients. Gelatin-based phantoms provide educators with durable and reusable task trainers; however, commercially available gel-based phantoms are expensive. Here, we investigate the production of durable, low-cost, ballistic gel-based ultrasound phantoms for median, femoral, suprainguinal fascia iliaca plane, and serratus anterior plane nerve blocks, as well as a methodology for producing a phantom for any ultrasound-guided nerve block procedure.

Computer-aided design (CAD) software was utilized to design four phantoms replicating the anatomy of median, femoral, suprainguinal fascia iliaca plane, and serratus anterior plane nerve blocks, including relevant landmarks and tissue planes. Plastic models of the desired tissue planes were 3D printed and used to create silicone molds. Ballistic gel was melted and mixed with flour and dye to create a liquid, echogenic ballistic gel, which was poured into the silicone molds. Vessels were simulated by creating negative space in the ballistic gel using metal rods. Nerves were simulated using yarn submerged in ultrasound gel. Simulated bones were designed using CAD and 3D printed.

Ballistic gel is a versatile, durable medium that can be used to simulate a variety of tissues and can be melted and molded into any shape. Under ultrasound, these phantoms provide realistic tissue planes that represent the borders between different layers of skin, muscle, and fascia. The echogenicity of the muscle tissue layers, nerves, vessels, and bones is realistic, and bones have significant posterior shadowing as would be observed in a human subject. These phantoms cost $200 each for the first phantom and $60 for each subsequent phantom. These phantoms require some technical skill to design, but they can be built for just 4% of the cost of their commercial counterparts.

Introduction

Ultrasound phantoms - alternatives to live human tissue - give learners the opportunity to practice medical procedures, including ultrasound-guided regional anesthesia (UGRA), without introducing undue risk to patients1. While most commonly manufactured via injection molding of liquid silicone rubber, custom phantoms can be homemade using versatile materials at lower cost. Organic tissues such as tofu, pork, and beef are inexpensive but spoil quickly and are challenging to craft2. Human cadaveric tissue is ideal for anatomic accuracy but is difficult and costly to obtain and preserve1. More recently, virtual reality has been used to provide UGRA training; however, haptic feedback is a key component of procedural learning and is rarely implemented. Even when a hardware-software hybrid model provides high visual fidelity and tactile feedback, the hardware and software required to carry out such training are frequently cost-prohibitive3. Gelatin-based phantoms strike a balance between cost, longevity, and fidelity2.

Ballistic gelatin models are available commercially but are expensive for a perishable resource that is highly utilized in medical simulation centers. Small, simple, gel-based ultrasound phantoms with homogeneous parenchyma and two or three simulated vessels retail for hundreds of dollars. For example, the CAE Blue Phantom basic ultrasound training block costs upwards of $8004. Higher-fidelity phantoms specific to individual nerve block procedures cost thousands of dollars. The CAE Blue Phantom femoral regional anesthesia ultrasound training model costs $5,000 (Table 1)5. To bring down costs, educators have experimented with custom-made phantoms using gelatin or other low-cost or reusable materials6,7,8. Additives such as flour, corn starch, graphite powder, and Metamucil can be used to opacify the gelatin and customize the echogenicity of the phantom, thus increasing its fidelity8,9,10,11,12,13,14.

Previous attempts at homemade gelatin-based nerve block trainers were either unable to adequately recreate the appearance of nerves under ultrasound or utilized perishable items, thus limiting shelf life15,16. Even without these drawbacks, previous iterations did not include relevant anatomical landmarks and fascial planes that would allow trainees to practice specific nerve block procedures. Here, we investigate the production of durable, low-cost, ballistic gel ultrasound phantoms for median, femoral, suprainguinal fascia iliaca plane, and serratus anterior plane nerve blocks, as well as a methodology for producing a phantom for any ultrasound-guided nerve block procedure.

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Protocol

For this project, authors JR and PS volunteered as ultrasound subjects, and verbal consent was obtained from both. For those following this protocol, obtain approval from an ethics committee or institutional review board (IRB) prior to using patients or human volunteers as study subjects.

1. Phantom design and silicone mold creation

  1. Creation of a reference ultrasound image
    1. For each ultrasound phantom, have a physician with ultrasound sub-specialization and familiarity with the nerve block procedure being simulated by the desired phantom create a reference ultrasound image from a volunteer human subject (Figure 1). Ensure that this ultrasound image has a view transverse to the applicable nerve or tissue plane into which the anesthetic would be injected.
  2. Design and 3D printing of tissue layer models
    1. Draw cross-sectional designs of each phantom (Figure 2) and utilize computer-aided design (CAD) to design plastic models of desired tissue layers and an outer container for the overall shape of the phantom (Figure 3A, Supplemental File 1, Supplemental File 2, Supplemental File 3, and Supplemental File 4).
      NOTE: From a design standpoint, fascial plane blocks can be thought of as a series of tightly fitted prisms enclosed within a hollow rectangular prism with 5 mm walls. Walls less than 5 mm were too fragile for reliable production. This rectangular prism serves as the outermost layer of the phantom into which the other tissue layers are assembled and placed. The median nerve model (shown in Figure 3 and Figure 4) uses an arched container rather than a rectangular prism to simulate the shape of a human arm.
      1. In CAD software, create a flat canvas from an ultrasound, CT, or other target image with known dimensions. Click on Solid | Insert | Canvas, select File, click on XY plane, drag into the +X +Y space, and drag to scale such that the picture length is accurate to known units.
      2. Create a rectangular prism over the region of the image that outlines the model by clicking on Solid | Create Sketch | XY plane | 2-Point Rectangle tool. Drag the rectangle over the area and refine within the length/width boxes when close; press Enter; click on Finish Sketch; click on rectangle | Solid | Extrude; drag the rectangle to the desired height and refine with the height box when close; and press Enter.
        NOTE: Each of our models has a different length and width based on the anatomy they represent but we typically found ~100 mm to be an effective model height.
      3. Create another sketch on top of the rectangular prism by clicking on the top of the rectangular prism | Create Sketch and draw out the desired anatomy as well as the inner edge of the encasing rectangular prism by clicking on Sketch | Create and Sketch | Modify toolboxes. Use the canvas visible behind the prism to guide the design; if the canvas is not seen through the rectangular prism, change this via Display Settings. Once the sketch that represents the cross section of the model is created, click on Finish Sketch.
        NOTE: There is no specific ideal tool to draw the desired anatomy and the inner edge of the encasing prism. The above step is what was used in this protocol.
      4. Next, create each internal prism from the sketch by clicking on the shape in the sketch | Solid | Extrude; drag the shape back into the rectangular prism at the desired length, typically 5 mm less than the full rectangle length; and click on Operation = New Body | Enter. To view this new object, turn off the visibility of all other objects by clicking on Bodies | the eye symbol next to the new body's name.
        NOTE: Vessels and should be represented by circular or elliptical prism-shaped holes designed into the edges or centers of fascial plane bodies. At this point, if you view the virtual model en-face to the initial canvas, the individual model pieces and how they fit together can be visualized.
      5. Export each body individually for 3D printing by clicking on Bodies | the eye symbol next to every body except the one being exported; click on File | Export | Type = .stl file | Enter.
        NOTE: You should now have multiple .stl files, each representing a unique fascial plane or bone, as well as one additional .stl file representing the rectangular bounding box the fascial plane pieces will fit into.
    2. Open the STL file in a slicer software compatible with the 3D printer that will be used to print the models.
      1. Use the Place on face button to lay the model on the bed such that the bottom of the model is touching the print bed.
      2. Under Printer, select the printer. Under Print settings, select 0.20mm SPEED, and under Filament, select Generic PLA. Select 15-20% for Infill, select Everywhere on the Supports menu, and add a brim if necessary for print stability. Click Slice now.
      3. Export the G-code file to an SD card, plug it into the 3D printer, and print the file using polylactic acid (PLA) filament.
  3. Creation of silicone molds
    1. Glue each 3D-printed model to the bottom of a topless plexiglass container before submerging it in rapid-curing silicone rubber per manufacturer guidelines17.
    2. Once the silicone is set, remove the hard-plastic model and plexiglass case, leaving a flexible, durable, and reusable silicone mold of each desired tissue layer and container into which ballistic gel is poured (Figure 3B).
      NOTE: At this point, the protocol may be paused and restarted later.

Figure 1
Figure 1: Representative ultrasound images obtained from a human subject. Representative images for the (A) median, (B) femoral, (C) suprainguinal fascia iliaca plane, and (D) serratus anterior plane nerve block models obtained from volunteer human subjects. Abbreviations: A = artery; V = vein; M = median nerve; F = femoral nerve; RAD = radius; U = ulna; AIIS = anterior inferior iliac spine; R =rib; SART = sartorius muscle; IL=Iliacus muscle; IO = internal oblique; SA = serratus anterior muscle; LD = latissimus dorsi muscle. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Cross-sectional schematics of nerve block ultrasound phantoms. (A) Median, (B) femoral, (C) suprainguinal fascia iliaca plane, and (D) serratus anterior plane nerve block ultrasound phantoms. Schematics were designed based on the representative human ultrasound images shown in Figure 1. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Creation of median nerve block phantom components. (A) Representative image of the computer-aided design file used to print plastic models of each tissue layer for the median nerve block phantom. (B) Silicone molds for each tissue layer of the median nerve block phantom, including metal rods inserted to create vessels within the ballistic gel. (C) Pouring hot, liquid, dyed ballistic gel into the silicone molds. (D) Sealing the open end of simulated vessels using liquid ballistic gel after vessels have been filled with simulated blood. Please click here to view a larger version of this figure.

2. Creation of other phantom landmarks

  1. Simulated bone design and creation
    1. If the region of the model designed in CAD represents bone instead of soft tissue, 3D print an imitation bone using the steps above, but use acrylonitrile butadiene styrene (ABS) filament instead.
      CAUTION: ABS filament fumes may contain volatile organic compounds (VOCs), which can cause physical discomfort, such as drowsiness, eye or respiratory tract irritation, nausea, and/or headaches18. ABS should be printed on an enclosed 3D printer or an unenclosed printer in a room with good ventilation and/or air filtration.
  2. Simulated nerve creation
    1. Submerge 80% acrylic, 20% wool yarn in a plastic cup filled with ultrasound gel. Place the cup is placed in a -1 atm pressure chamber.
    2. Use a single-stage vacuum pump to repeatedly build up and then release pressure in the chamber until all bubbles have been removed from the ultrasound gel, accomplished after approximately 4-6 cycles.
      ​NOTE: This step helps simulate nerves. At this point, the protocol may be paused and restarted later.

3. Ballistic gel melting and pouring

  1. Melting the ballistic gel
    1. Heat commercially available ballistic gel and dye at an approximate 20:1 volume ratio with intermittent stirring until the liquid reaches 132 °C in a commercial convection oven.
      CAUTION: Heated, liquid ballistic gel should be handled with caution due to the risk of burns associated with handling hot fluids. Use oven mitts when handling pans filled with liquid ballistic gel. Avoid direct contact between skin and liquid ballistic gel.
  2. Additives for echogenicity
    1. Stir approximately 4.5 g of finely granulated flour per kg of ballistic gel into the liquid ballistic gel. Leave the gel in the oven for at least 20 min with intermittent stirring to allow for even mixing and to allow any bubbles to escape.
    2. Add additional clear ballistic gel or dye as necessary to adjust the mixture's color to simulate human tissue.
  3. Ballistic gel pouring into silicone molds
    1. Insert solid steel rods of varying diameters into the designated locations on the reusable silicone molds, if appropriate for that specific nerve block model, to create channels in the final ultrasound phantoms, which will represent blood vessels (Figure 3C).
    2. Pour liquid ballistic gel, now colored by dye, with suspended flour particulates, and without retained air bubbles, into the silicone molds and allow it to cool.
    3. After cooling, remove the metal rods and the final ballistic gel tissue layers from the molds. When placed together with an ultrasound gel coating between them, adjacent tissue pieces align near-perfectly and together produce a simulated fascial plane on ultrasound.
      NOTE: Each ultrasound phantom requires approximately 0.7 kg of ballistic gel. Cooling time is dependent on the size of the tissue layer and varies from 20 min to 1.5 h.
  4. Addition of simulated blood and sealing of vessels
    1. For the tissue layers with simulated vessels, dip one side of the tissue layer into the liquid ballistic gel and allow it to cool, thus sealing off one side of the vessel channel.
    2. Hold these tissue layers upright and use a needle and syringe to introduce simulated blood into each vessel.
      NOTE: We used water with red or blue food coloring to represent arterial and venous blood, respectively.
    3. Use still-liquid ballistic gel to cover up the remaining vessel opening, thus sealing off each fluid-filled vessel completely (Figure 3D).
      ​NOTE: At this point, the protocol may be paused and restarted later; however, ballistic gel must be melted again to proceed to the following step.

4. Phantom assembly

  1. Assembly of tissue layers, nerves, and bones
    NOTE: Figure 4A depicts the individual components of the median nerve block phantom immediately prior to assembly, including the tissue layers, simulated nerves, and simulated bones.
    1. Assemble the phantoms by coating each component in ultrasound gel, assembling the components as shown by the cross-sections in Figure 2, and inserting them into their respective ballistic gel rectangular prisms (Figure 4B). Place any 3D-printed bones or yarn nerves properly at this step.
  2. Sealing the ends of the phantom
    1. Seal the models by dipping them on both sides into a pan filled with liquid ballistic gel (Figure 4C). Repeat the sealing process multiple times on each side.
    2. Finally, use a heat gun to smooth the edges of the phantom, removing bubbles and imperfections, as well as reinforcing the side seals.
  3. Addition of pseudo-skin (optional)
    NOTE: An augmentation to the fascial-plane models is the addition of pseudo-skin.
    1. Pour liquid ballistics gel over a sealed and cooled model, which has been covered loosely in ultrasound gel to prevent annealing between the newly poured skin layer and the existing model (Figure 4D and Supplemental Video S1).

Figure 4
Figure 4: Assembly of median nerve block ultrasound phantom. (A) Individual components of a disassembled median nerve block phantom, including ballistic gel tissue layers, 3D-printed radius and ulna, a yarn median nerve submerged in ultrasound gel, a bottle of ultrasound gel, and a pan filled with liquid ballistic gel. (B) Assembly of the median nerve block phantom, including insertion of tissue layers and simulated bones covered in ultrasound gel. (C) Sealing one end of the phantom by dipping into a pan of liquid ballistic gel. (D) Creating a layer of pseudo-skin by pouring liquid ballistic gel over a completed median nerve block phantom. Please click here to view a larger version of this figure.

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Representative Results

Four ultrasound phantoms were successfully designed and built using the methods described above. An ultrasound cross-section of each model aligned with an ultrasound of equivalent human anatomy is shown in Figure 5. Under ultrasound, these phantoms provide realistic tissue planes, which represent the borders between different layers of skin, muscle, and fascia. The muscle tissue is appropriately and homogeneously echogenic. This echogenicity can be adjusted based on the amount of flour added to the ballistic gel during melting. Fascial borders are hyperechoic compared to the background muscle tissue. The yarn appears irregularly hyperechoic, with well-defined borders, appropriately simulating the appearance of a nerve. The yarn is located in between tissue layers, and this part of the phantom can accommodate fluid injection to simulate injection of local anesthetic during a nerve block procedure. Furthermore, injection into a ballistic gel block encounters significant resistance when compared to injection into a simulated fascial plane, which may serve as a beneficial feedback mechanism for learners. The 3D-printed blocks made of ABS filament appropriately simulate the hyperechoic cortex and acoustic shadowing of human bone when visualized under ultrasound. Simulated vessels appear anechoic with well-defined borders, as also seen in their live human counterparts. Dyed water can be aspirated with a needle to confirm intravascular access when practicing relevant ultrasound-guided procedures.

Figure 5
Figure 5: Representative ultrasound images obtained from ultrasound phantoms compared with human subjects. (A) The median, (B) femoral, (C) suprainguinal fascia iliaca plane, and (D) serratus anterior plane nerve block ultrasound phantoms (left) and a human subject (right). For each ultrasound phantom (left), multiple still images obtained from scanning the ultrasound phantoms were stitched together to demonstrate the entire phantom under ultrasound. No other alterations were made to the images. The dashed yellow boxes represent the area of the ultrasound phantom that correlates with the human subject image immediately to the right. Abbreviations: A = artery; V = vein; M = median nerve; F = femoral nerve; RAD = radius; U = ulna; AIIS = anterior inferior iliac spine; R =rib; SART = sartorius muscle; IL=Iliacus muscle; IO = internal oblique; SA = serratus anterior muscle; LD = latissimus dorsi muscle. Please click here to view a larger version of this figure.

Supplemental File 1: Computer-aided design of plastic models representing each desired tissue layer for the median nerve block ultrasound phantom. Please click here to download this File.

Supplemental File 2: Computer-aided design of plastic models representing each desired tissue layer for the femoral nerve block ultrasound phantom. Please click here to download this File.

Supplemental File 3: Computer-aided design of plastic models representing each desired tissue layer for the suprainguinal fascia iliaca plane block ultrasound phantom. Please click here to download this File.

Supplemental File 4: Computer-aided design of plastic models representing each desired tissue layer for the serratus anterior plane block ultrasound phantom. Please click here to download this File.

Supplemental Video S1: Addition of pseudo-skin to median nerve block ultrasound phantom. Pouring liquid ballistic gel over a finished ultrasound phantom with a minimal layer of ultrasound gel on top creates a thin cover, which feels and moves like skin. This video demonstrates the ability of the pseudo-skin to mimic the movement of human skin when pressed against. Please click here to download this File.

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Discussion

These custom ballistic gel-based phantoms provide trainees with medium-fidelity median, femoral, suprainguinal fascia iliaca plane, and serratus anterior plane nerve block training for a fraction of the cost of commercially available nerve block phantoms (Table 1). Our first median and femoral nerve block trainers were made in-house for 12% and 9% of the price of the cheapest commercially available median and femoral nerve block trainers, respectively. None of the available femoral nerve block phantoms are capable of simulating the suprainguinal approach to the fascia iliaca block as our phantom does. We could find no commercially available serratus anterior plane ultrasound phantoms.

Table 1: Summary of commercially available ultrasound-guided regional anesthesia phantoms. Please click here to download this Table.

In the last decade, 3D printing technology has become more accessible and more affordable. For example, the Original Prusa i3 MK3S+ 3D printer used in this protocol, though not the latest edition, costs just $64919. Even the smaller Prusa MINI+, which is sufficient for making the models detailed herein, costs just $42920. Most replacement parts for these printers are 3D-printed themselves, further minimizing repair costs. Students and faculty can generally access 3D printers for free through their institution's makerspace or design lab. Designing objects to 3D print is more convenient than ever using computer-aided design (CAD) programs, some of which are available for free21.

The length of time required to design the 3D-printed models and simulated bones varies depending on the user's skill and familiarity with CAD software; however, this process can be done without cost using software such as FreeCAD or by utilizing CAD software licensed by the host institution21. Creating silicone molds of each tissue layer is not time-intensive. Silicone costs $28 per kg with each phantom requiring 4-6 kg of silicone ($140 total). Since the silicone molds are reusable, this is a one-time expense.

Our commercial ballistic gel costs $86 per kg, and each phantom required approximately 0.7 kg for a cost of $60 per phantom. 3D printing structures required for molding require negligible costs of PLA or ABS filament. Two of our phantoms required 100 mm of yarn at $10 per m or $0.01 per phantom. In total, each phantom cost ~$200 to make the first model and $60 to make each subsequent model. The production process required 1 man-hour and 3-4 h of gel heating and cooling. We have been able to build four models concurrently in the same timeframe.

Ballistic gel is an ideal medium due to its versatility. It can be used to simulate a variety of tissues and can be melted and molded into any shape. Once the gel is solidified, any imperfections or needle punctures are somewhat self-healing and can be further mended using a heat gun. If there is a mistake in the phantom, or if it becomes damaged or overused, the ballistic gel components can always be disassembled, cleaned, and melted back down to be reused with minimal material loss. Ballistic gel is also cost-effective. Despite being the most expensive component of these phantoms at $86 per kg, these phantoms are still far more affordable than commercially available ultrasound phantoms (Table 1). Phantoms made using homemade gelatin have been previously described and are presumably even more affordable, but these phantoms will develop mold within days to weeks, even when stored in a refrigerator16. We have stored the phantoms in a clean, dry environment at room temperature for months to years without spoiling or degradation.

Simulating nerves in gelatin for ultrasound-guided nerve block models has proven difficult for educators. Previous attempts have utilized animal tendons22,23,24, electrical wire25, wooden dowels25, shoelaces26, metal rods27, bundles of rubber bands15, foam28, peas29, spaghetti30, and even an Ethernet cable31. These options are unrealistic, perishable, or create significant posterior acoustic shadowing under ultrasound. We used a household item, yarn, to create high-fidelity simulated nerves with little-to-no posterior shadowing for just $0.10 per m, or $0.01 per phantom.

ABS filament was used for 3D printing of imitation bone due to its higher heat tolerance than PLA, which warped in subsequent steps during the development of this method. We maximized the bake temperature to minimize melt times and decrease viscosity and number of bubbles. This allows for smoother, more space-filling pours into the silicone molds while also maintaining the temperature below the burning temperature of the gel, thereby avoiding excess smoke production.

The primary drawback to these phantoms is the time and energy required to design and build them. Designing tissue planes using CAD requires technical skill, and 3D printing models of them requires a basic knowledge of 3D printers, slicing an STL file, choosing a filament, and which settings and temperatures to use. Creating silicone molds for each tissue plane adds expense, as silicone is the second-most expensive component of this protocol at $28 per kg. However, these silicone molds are durable and reusable, so once they are made, they can be reused to create numerous ultrasound phantoms. Other drawbacks include the learning curve associated with mixing and pouring ballistic gel, as well as the lack of technological integration of these phantoms when compared with high-fidelity commercial mannequins. That said, we consider the relative ease of construction, ease of material acquisition, customizability, low cost, and recyclability of this model design to far outweigh its drawbacks. We hope that the dissemination of their construction method will facilitate improved training of nerve block procedures in facilities that cannot afford frequent replacement of expensive commercial medical simulation devices. Future studies should explore custom phantoms for additional nerve block procedures and assess the satisfaction and clinical performance of trainees utilizing these phantoms compared to their peers.

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Disclosures

The authors of this paper do not have any conflicts of interest to disclose.

Acknowledgments

This project was funded by the Simulation Training Center (STC) at the University of California, San Diego School of Medicine in La Jolla, CA. We would like to thank Blake Freechtle for his contributions to Figure 5.

Materials

Name Company Catalog Number Comments
ABS Filament - 1.75 m+B+A2:A14 Hatchbox (Pomona, CA) https://www.hatchbox3d.com/collections/abs-1-75mm
Adobe Photoshop Adobe (San Jose, CA) https://www.adobe.com/products/photoshop.html
Amber Tone Dye Humimic Medical (Greenville, SC) 852844007925 Ballistic gel dye; https://humimic.com/product/amber-tone-dye/
Fusion 360 Autodesk (San Franciso, CA) Computer-assisted design (CAD) software; https://www.autodesk.com/products/fusion-360/overview?term=1-YEAR&tab=subscription&plc=F360
Gelatin #1 - Medical Gel by the Pound Humimic Medical (Greenville, SC) 852844007406 Ballistic gel; https://humimic.com/product/gelatin-1-medical-gelatin-by-the-pound/
Gluten-Free All-Purpose Flour Arrowhead Mills (Hereford, TX) Flour for echogenicity; https://arrowheadmills.com/products/gluten-free/organic-gluten-free-all-purpose-flour/
Microsoft PowerPoint Microsoft (Redmond, WA) https://www.microsoft.com/en-us/microsoft-365/powerpoint
Mold Star 16 FAST Pourable Silicone Rubber Smooth-On (Macungie, PA) Pourable silicone rubber; https://www.smooth-on.com/products/mold-star-16-fast/
Peach Tone Dye Humimic Medical (Greenville, SC) 852844007895 Ballistic gel dye; https://humimic.com/product/peach-tone-dye/
PLA Filament - 1.75 mm Hatchbox (Pomona, CA) https://www.hatchbox3d.com/collections/pla-1-75mm
Prusa Original i3 MK3S+ printer Prusa Research (Prague, Czech Republic) 3D printer; https://www.prusa3d.com/category/original-prusa-i3-mk3s/
Prusa Slicer 2.6.1 Prusa Research (Prague, Czech Republic) 3D printer slicer software; https://www.prusa3d.com/page/prusaslicer_424/
Wool-Ease Thick & Quick Yarn Lion Brand Yarn (Lyndhurst, NJ) 640-610B Yarn for simulated nerves; https://www.lionbrand.com/products/wool-ease-thick-and-quick-yarn?variant=32420963516509

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Marsh-Armstrong, B. P., Ryan, J. F., More

Marsh-Armstrong, B. P., Ryan, J. F., Mariano, D. J., Suresh, P. J., Supat, B. Building Affordable, Durable, Medium-Fidelity Ballistic Gel Phantoms for Ultrasound-Guided Nerve Block Training. J. Vis. Exp. (204), e66194, doi:10.3791/66194 (2024).

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