Philippines team add hypergravity for stronger bone cells

A team of four researchers from two Catholic educational institutions located on neighbouring islands in the Philippines – the University of San Carlos in Cebu City and Holy Name University in Tagbilaran City – form the latest research group to take their experiments for a spin in ESTEC’s hypergravity-generating Large Diameter Centrifuge.

The researchers are testing how bioprinted bone cells respond to increased gravity. Their cell cultures are grown on 3D-printed scaffolds made from carrageenan, a carbohydrate extracted from red seaweed farmed in the tropics. The material is already widely used as a food additive, because of its thickening and stabilising properties. The team believes that carrageenan also has potential to make stronger scaffolds for bioprinted bone generation – and that hypergravity might be an added ingredient to stimulate growth in bone cells.

Based at ESA’s ESTEC technical centre in the Netherlands, the LDC is a four-arm centrifuge of 8 m in diameter that gives researchers access to a range of hypergravity levels up to 20 times Earth gravity for weeks or months at a time.

At its fastest, the centrifuge rotates at up to 67 revs per minute, with its six gondolas placed at different points along its arms weighing in at 130 kg, and each capable of accommodating 80 kg of payload.

LDC access was arranged through HyperGES, part of the Access to Space for All initiative sponsored by ESA and the United Nations Office of Outer Space Affairs, UNOOSA.

Team leader Dr. Rommel Bacabac from the University of San Carlos explains: “We developed a ‘bio-ink’ from red seaweed for the 3D printing of artificial bone tissues. Using this material, we 3D printed a scaffold for bone cells to grow on – this scaffold recreates a collagen structure which serves as the foundation of a bone in nature. We are simulating this structure with carrageenan, which can be tuned to mimic similar mechanical properties.

“We are directly inspired by a group of researchers which tested the growth of bone cells on glass slides in hypergravity – their results suggested that hypergravity serves as a source of stress to activate genes that make the cells grow faster. Our experiment is similar, but with the addition of the 3D-printed scaffolds.

“With the large centrifuge, we can subject our cell samples to a much more uniform field of acceleration than we could with conventional centrifuges that are much smaller in diameter.”

The team subjected their bone cell samples to three different conditions: 24 hours at 15 G (15 times Earth gravity), three days at 7.5 G, and ended with a quick one-hour spin at the same g levels.

Their experiment will generate two sets of data, one containing the levels of gene expression – meaning which genes were switched on or off in the cells during the experiment – and one with images of the cells made using a special microscope.

“Back in the Philippines, we will analyse the imaging data to examine the size and shape of the cells. The gene expression data will be analysed by our collaborators at the Vrije Universiteit Amsterdam and the University of Amsterdam,” says Rommel. “If hypergravity proves to be stimulating for the growth of cells on scaffolds, we could apply this technique to other bio-inks we are developing, for example for muscle, skin or pancreatic tissue.”

By using seaweed as the main ingredient of their bio-ink, the team are developing functional material from their local marine resources. Rommel comments: “Red seaweed grows only in tropical areas and it is one of the major exports of our country. We are collaborating with a local producer of carrageenan extracted from seaweed. Today they mainly export it as a food additive, but are interested in expanding its use to tissue engineering and other medical applications.”

Team member Dr. Hyacinth Suarez, marine biologist at Holy Name University, adds: “The red seaweed we use is sourced locally by farmers in the Philippines. This means that if we could make bone implants using carrageenan, it would not only have the potential to improve tissue implant technology, but it would also support local communities that rely on seaweed farming.”

Mami Sasamura of UNOOSA’s Space Applications Section comments: “I was impressed by how the Philippines team has been progressing with their experiment, cooperating with local partners and handling unforeseen situations as they arise. I also appreciate ESA’s flexibility in accommodating some changes on-site. It’s a team with great teamwork, and I’m looking forward to the experiment results.

“Past teams of the programme have conducted biological experiments – such as investigating the effect of hypergravity on plants, small organisms, or red blood cells – intended to support space exploration missions and life on Earth.

“The teams selected through this programme do not only get access to one of the most unique facilities in the world to conduct their experiments, but also to an opportunity to build capacity and gain experience and knowledge. We hope that the participants will use their experience gained in the programme to lead the scientific community of the future.”