To demonstrate how their 3-D-printable, cartilage-mimicking material might work, the researchers used a $300 3D printer to create custom menisci for a model of a knee. Photo credit: Feichen Yang.
Human knees come with a pair of built-in shock absorbers called the menisci. These ear-shaped hunks of cartilage, nestled between the thigh and shin bones, cushion every step we take. But a lifetime of wear-and-tear – or a single wrong step during a game of soccer or tennis – can permanently damage these key supports, leading to pain and an increased risk of developing arthritis.
The hydrogel-based material the researchers developed is the first to match human cartilage in strength and elasticity while also remaining 3-D-printable and stable inside the body. To demonstrate how it might work, the researchers used a $300 3-D printer to create custom menisci for a plastic model of a knee.
We’ve made it very easy now for anyone to print something that is pretty close in its mechanical properties to cartilage, in a relatively simple and inexpensive process,
said Benjamin Wiley, an associate professor of chemistry at Duke and author on the paper, which appears online in ACS Biomaterials Science and Engineering.
After we reach adulthood, the meniscus has limited ability to heal on its own. Surgeons can attempt to repair a torn or damaged meniscus, but often it must be partially or completely removed. Available implants either do not match the strength and elasticity of the original cartilage, or are not biocompatible, meaning they do not support the growth of cells to encourage healing around the site.
Recently, materials called hydrogels have been gaining traction as a replacement for lost cartilage. Hydrogels are biocompatible and share a very similar molecular structure to cartilage: if you zoom in on either, you’ll find a web of long string-like molecules with water molecules wedged into the gaps. But researchers have struggled to create recipes for synthetic hydrogels that are equal in strength to human cartilage or that are 3-D-printable.
Abstract of “3D Printing of a Double Network Hydrogel with a Compression Strength and Elastic Modulus Greater than those of Cartilage”. This article demonstrates a two-step method to 3D print double network hydrogels at room temperature with a low-cost ($300) 3D printer. A first network precursor solution was made 3D printable via extrusion from a nozzle by adding a layered silicate to make it shear-thinning. After printing and UV-curing, objects were soaked in a second network precursor solution and UV-cured again to create interpenetrating networks of poly(2-acrylamido-2-methylpropanesulfonate) and polyacrylamide. By varying the ratio of polyacrylamide to cross-linker, the trade-off between stiffness and maximum elongation of the gel can be tuned to yield a compression strength and elastic modulus of 61.9 and 0.44 MPa, respectively, values that are greater than those reported for bovine cartilage. The maximum compressive (93.5 MPa) and tensile (1.4 MPa) strengths of the gel are twice that of previous 3D printed gels, and the gel does not deform after it is soaked in water. By 3D printing a synthetic meniscus from an X-ray computed tomography image of an anatomical model, we demonstrate the potential to customize hydrogel implants based on 3D images of a patient’s anatomy.
The current gels that are available are really not as strong as human tissues, and generally, when they come out of a printer nozzle they don’t stay put – they will run all over the place, because they are mostly water, Wiley said.
The 3-D-printable hydrogel flows like water when placed under shear stress, such as when being squeezed through a small needle. But as soon as the stress is gone, the hydrogel immediately hardens into its printed shape. Feichen Yang, a graduate student in Wiley’s lab and author on the paper, experimented with mixing together two different types of hydrogels – one stiffer and stronger, and the other softer and stretchier – to create what is called a double-network hydrogel.
The two networks are woven into each other, Yang said. And that makes the whole material extremely strong.
By changing the relative amounts of the two hydrogels, Yang could adjust the strength and elasticity of the mixture to arrive at a formula that best matches that of human cartilage. He also mixed in a special ingredient, a nanoparticle clay, to make the mock-cartilage 3-D-printable. With the addition of the clay, the hydrogel flows like water when placed under shear stress, such as when being squeezed through a small needle. But as soon as the stress is gone, the hydrogel immediately hardens into its printed shape.
3-D printing of other custom-shaped implants, including hip replacements, cranial plates, and even spinal vertebrae, is already practiced in orthopedic surgery. These custom implants are based on virtual 3-D models of a patient’s anatomy, which can be obtained from computer tomography (CT) or magnetic resonance imaging (MRI) scans.
Meniscus implants could also benefit from 3-D printing’s ability to create customized and complex shapes, the researchers say.
Shape is a huge deal for the meniscus, Wiley said. This thing is under a lot of pressure, and if it doesn’t fit you perfectly it could potentially slide out, or be debilitating or painful.
A meniscus is not a homogenous material, Yang added. The middle is stiffer, and the outside is a bit softer. Multi-material 3-D printers let you print different materials in different layers, but with a traditional mold you can only use one material.
In a simple demonstration, Yang took a CT scan of a plastic model of a knee and used the information from the scan to 3-D print new menisci using his double network hydrogel. The whole process, from scan to finished meniscus, took only about a day, he says.
This is really a young field, just starting out, Wiley said. I hope that demonstrating the ease with which this can be done will help get a lot of other people interested in making more realistic printable hydrogels with mechanical properties that are even closer to human tissue.
Source: press release by Duke University .