Tag Archives: Susmita Bose

Bone regeneration with a mix of 21st century techniques and an age-old natural cure

Curry was how I was introduced to turmeric. My father who came from Mauritius loved curry and we had it at least once a week. Nobody mentioned healing properties, which I was to discover them only after I started this blog. Usually, turmeric is mentioned in cancer cures but not this time.

Turmeric Courtesy: Washington State University

From a May 2, 2018 Washington State University news release by Tina Hilding (also on EurekAlert but dated May 3, 2018),

A WSU research team is bringing together natural medical cures with modern biomedical devices in hopes of bringing about better health outcomes for people with bone diseases.

In this first-ever effort, the team improved bone-growing capabilities on 3D-printed, ceramic bone scaffolds by 30-45 percent when coated with curcumin, a compound found in the spice, turmeric. They have published their work in the journal, Materials Today Chemistry.

The work could be important for the millions of Americans who suffer from injuries or bone diseases like osteoporosis.

Human bone includes bone forming and resorbing cells that constantly remodel throughout our lives. As people age, the bone cell cycling process often doesn’t work as well. Bones become weaker and likely to fracture. Many of the medicines used for osteoporosis work by slowing down or stopping the destruction of old bone or by forming new bone. While they may increase bone density, they also create an imbalance in the natural bone remodeling cycle and may create poorer quality bone.

Turmeric has been used as medicine for centuries in Asian countries, and curcumin has been shown to have antioxidant, anti-inflammatory and bone-building capabilities. It can also prevent various forms of cancers. However, when taken orally as medicine, the compound can’t be absorbed well in the body. It is metabolized and eliminated too quickly.

Led by Susmita Bose, Herman and Brita Lindholm Endowed Chair Professor in the School of Mechanical and Materials Engineering, the researchers encased the curcumin within a water-loving polymer, a large molecule, so that it could be gradually released from their ceramic scaffolds. The curcumin increased the viability and proliferation of new bone cells and blood vessels in surrounding tissue as well as accelerated the healing process.

Bose hopes that the work will lead to medicines that naturally create healthier bone without affecting the bone remodeling cycle.

“In the end, it’s the bone quality that matters,” she said.

The researchers are continuing the studies, looking at the protein and cellular level to gain better understanding of exactly how the natural compound works. They are also working to improve the process’ efficiency and control. The challenge with the natural compounds, said Bose, is that they are often large organic molecules.

“You have to use the right vehicle for delivery,” she said. “We need to load and get it released in a controlled and sustained way. The chemistry of vehicle delivery is very important.”

In addition to curcumin, the researchers are studying other natural remedies, including compounds from aloe vera, saffron, Vitamin D, garlic, oregano and ginger. Bose is focused on compounds that might help with bone disorders, including those that encourage bone growth or that have anti-inflammatory, infection control, or anti-cancer properties.

Starting with her own health issues, Bose has had a longtime interest in bridging natural medicinal compounds with modern medicine. That interest increased after she had her children.

“As a mother and having a chemistry background, I realized I didn’t want my children to be exposed to so many chemicals for every illness,” Bose said. “I started looking at home remedies.”

To her students, she always emphasizes healthy living as the best way to guarantee the best health outcomes, including healthy eating, proper sleep, interesting hobbies, and exercise.

Courtesy Washington State University

Here’s a link to and a citation for the paper,

Effects of PCL, PEG and PLGA polymers on curcumin release from calcium phosphate matrix for in vitro and in vivo bone regeneration by Susmita Bose, Naboneeta Sarkar, Dishary Banerjee. Materials Today Chemistry Vol. 8 June 2018, pp. 110-130 [Published online May 2, 2018] https://doi.org/10.1016/j.mtchem.2018.03.005

This paper is behind a paywall.

Printing bones

Apparently all you need is an inkjet printer and some researchers from Washington State University (WSU) at Pullman to create new bone. From the Nov. 29, 2011 news item (written by Eric Sorenson of WSU) on Nanowerk,

Washington State University researchers have used a 3D printer to create a bone-like material and structure that can be used in orthopedic procedures, dental work and to deliver medicine for treating osteoporosis. Paired with actual bone, it acts as a scaffold for new bone to grow on and ultimately dissolves with no apparent ill effects. [emphasis mine]

The authors report on successful in vitro tests in the journal Dental Materials (“Effects of silica and zinc oxide doping on mechanical and biological properties of 3D printed tricalcium phosphate tissue engineering scaffolds” [behind a paywall]) and say they’re already seeing promising results with in vivo tests on rats and rabbits. It’s possible that doctors will be able to custom order replacement bone tissue in a few years, said Susmita Bose, co-author and professor in WSU’s School of Mechanical and Materials Engineering.

The printer works by having an inkjet spray a plastic binder over a bed of powder in layers of 20 microns, about half the width of a human hair. Following a computer’s directions, it creates a channeled cylinder the size of a pencil eraser.

After just a week in a medium with immature human bone cells, the scaffold was supporting a network of new bone cells.

Here’s a video of Dr. Bose discussing the inkjet printer that produces bone-like material,

The Nov. 30, 2011 news item about the bone scaffolding work on BBC News adds more detail,

Prof Bose’s team have spent four years developing the bone-like substance.

Their breakthrough came when they discovered a way to double the strength of the main ceramic powder – calcium phosphate – by adding silica and zinc oxide.

To create the scaffold shapes they customised a printer which had originally been designed to make three-dimensional metal objects.

It sprayed a plastic binder over the loose powder in layers half as thick as the width of a human hair.

The process was repeated layer by layer until completed, at which point the scaffold was dried, cleaned and then baked for two hours at 1250C (2282F).

Earlier this year I highlighted a story about a trachea transplant where they used scaffolding to grow trachea cells in much the same way the WSU team is using a scaffolding to grow bone cells. Here are the posts about the trachea transplant and scaffolding from the first to the last,

Body parts nano style

Making nanotechnology-enabled body parts

More on synthetic windpipe; Swedes and Italians talk about nanoscience and medicine