29-Dec-2022: Indian Army inaugurates first ever two storey 3-D printed dwelling unit at Ahmedabad.

The Indian Army inaugurated its first 3-D Printed House Dwelling Unit (with Ground plus One configuration) for soldiers at Ahmedabad Cantt on 28 December 2022. The dwelling unit has been constructed by the Military Engineering Services (MES) in collaboration with MiCoB Pvt Ltd incorporating the latest 3D Rapid Construction Technology.

Construction work of the dwelling unit measuring 71 sqm with garage space was completed in just 12 weeks by utilising the 3D printed foundation, walls and slabs. The disaster-resilient structures comply with Zone-3 earthquake specifications and green building norms. The 3-D printed houses are symbolic of the modern-day rapid construction efforts to cater for growing accommodation requirements of the Armed Forces personnel. This structure also stands testament to the commitment of Indian Army in fostering the 'Atmanirbhar Bharat Abhiyan'.

The technique utilises a concrete 3D printer that accepts a computerised three-dimensional design and fabricates a 3-D structure in a layer-by-layer manner by extruding a specialised type of concrete specifically designed for the purpose.

Ahmedabad based Golden Katar Division of Indian Army has been instrumental in pursuing the project with manifold applications even in operations. Indian Army units have already dovetailed 3D printing technology in construction of pre-casted permanent defenses and overhead protection meant for operations. These structures are currently being validated over a period of one year and can be seen being incorporated in all terrains, the recent being in the UT of Ladakh.

29-May-2019: 3D-printed artificial corneas mimic human eyes

Scientists have 3D printed artificial corneas that mimic the human eye -- using the bio ink made of stem cells -- an advance that may help reduce the need for eye donations.

When a person has a severely damaged cornea, a corneal transplant is required. However, patients often have to wait for years to receive eye donations.

Many scientists have put their efforts in developing an artificial cornea. The existing artificial cornea uses recombinant collagen or is made of chemical substances such as synthetic polymer. Therefore, it does not incorporate well with the eye or is not transparent after the cornea implant.

Researchers at the Pohang University of Science and Technology and Kyungpook National University in South Korea 3D printed an artificial cornea using the bio ink which is made of decellularized corneal stroma and stem cells.

The cornea is made of corneal tissue-derived bio ink. It is biocompatible, and 3D cell printing technology recapitulates the corneal microenvironment, therefore, its transparency is similar to the human cornea.

The cornea is a thin outermost layer that covers the pupil and it protects the eye from the external environment. It is the first layer that admits light and therefore it needs to be transparent, move as the pupil moves, and have flexibility.

However, it has been limited to develop an artificial cornea using synthetic biocompatible materials because of different cornea-related properties. In addition, although many researchers have tried to repeat the corneal microenvironment to be transparent, the materials used in existing studies have limited microstructures to penetrate the light.

The human cornea is organised in a lattice pattern of collagen fibrils. The lattice pattern in the cornea is directly associated with the transparency of cornea, and many researches have tried to replicate the human cornea. However, there was a limitation in applying to corneal transplantation due to the use of cytotoxic substances in the body, their insufficient corneal features including low transparency, and so on.

To solve this problem, the research team used shear stress generated in the 3D printing to manufacture the corneal lattice pattern and demonstrated that the cornea by using a corneal stroma-derived decellularised extracellular matrix bio ink was biocompatible.

In the 3D printing process, when ink in the printer comes out through a nozzle and passes through the nozzle, frictional force which then produces shear stress occurs.

The team successfully produced transparent artificial cornea with the lattice pattern of human cornea by regulating the shear stress to control the pattern of collagen fibrils. They also observed that the collagen fibrils remodelled along with the printing path create a lattice pattern similar to the structure of native human cornea after 4 weeks in vivo.

19-Apr-2019:  3D-printed heart

Israeli researchers have created an entire 3D-printed heart made from human cells in what they say is a world first. The heart doesn't beat and is too small for use in people — it's only about the size of a rabbit's heart. But the little organ is considered a big advance in the ongoing effort to find new treatments for heart disease.

Heart transplantation is currently the only good option for people with severe heart failure. But donor organs are in such short supply. Being able to 3D-print a human heart when needed could conceivably help save many lives that are now lost.

Previously, scientists were able to 3D-print heart structures that lacked cells or blood vessels. But the new 3D-printed heart contains cells, blood vessels, chambers and other structures a heart needs to function normally. To make it, scientists took fatty tissue from patients and converted the fat cells into stem cells. These were added to a gel and then further processed until they turned into heart cells. The cell-containing "bioink" was added to a 3D printer and used to build the experimental organ layer by layer.

The next step for the scientists would be to explore ways to "teach" 3D-printed hearts to function normally and then transplant them into rats to see how well they work. The scientists will also explore the feasibility of 3D-printing larger hearts, with the ultimate goal of building functional human hearts. That might be even harder than it sounds.

1-May-2017: 3D printed cartilage to treat osteoarthritis

Researchers have successfully generated cartilage tissue using a 3D bioprinter, an advance that could lead to new treatments for osteoarthritis. The advance represents a giant step forward in the ability to generate new, endogenous cartilage tissue.

The team used cartilage cells harvested from patients who underwent knee surgery, and these cells were then manipulated in a laboratory, causing them to rejuvenate and revert into “pluripotent” stem cells — cells that have the potential to develop into many different types of cells. The stem cells were then expanded and encapsulated in a composition of Nano-fibrillated cellulose and printed into a structure using a 3D bioprinter. Following printing, the stem cells were treated with growth factors that caused them to differentiate correctly, so that they formed cartilage tissue. Each individual stem cell is encased in nanocellulose, which allows it to survive the process of being printed into a 3D structure. This bio-printed tissue can be used to repair cartilage damage, or to treat osteoarthritis, in which joint cartilage degenerates and breaks down.