Next Generation Hydrogel with Only Natural Ingredients

Glycolink offers a novel class of hydrogel, free from synthetic components, easy-to-prepare, containing just two natural ingredients from sustainable sources and with no need for any chemical modification.

Fully Bio-Based & Solvent-Free

Our hydrogel can be used in virtually any industrial application or R&D that needs a water-based matrix. The standard gel contains only two ingredients and can be engineered to contain functional bioactive compounds as needed. Using a proprietary approach to hydrogel formation developed at the KTH Royal Institute of Technology in Sweden, this new material is environmentally friendly and has an extremely small waste footprint.

What is unique about Glycolink??

Natural

The gel consists of bio-based components with no need for modification, making chemical cross-linkers and organic solvents redundant.

Tunable

The viscosity of the gel is tunable by simply changing the ratio of ingredients. Additional properties can also be added as desired, as other materials can be mixed into the gel.

Low cost

Bulk availability of ingredients and no need for expensive chemicals and temperature-specific production steps leads to a low cost manufacturing process.

Cruelty-Free

Ingredients derive from safe natural microorganisms, making our gel an ethical choice in contrast to formulations that use animal polysaccharides.

Easy to Prepare

The components simply mix in water at room temperature, and the gel forms spontaneously. The preparation is much easier than other gel forming processes.

Biodegradable

The ingredients are completely bio-based and found in nature. With no solvents or chemical modifications our hydrogel is also fully biodegradable.

Glycolink is committed to the well-being of animals and firmly believe that animal testing is unnecessary. Read more in our Animal Testing Policy.

What are hydrogels?

Hydrogels are a superabsorbent material created by long chains of molecules that form a network that can encapsulate huge amounts of water.

Their use is widespread in society. We see them in moisturizing creams, cosmetic face masks, contact lenses, as absorbents in diapers, in toothpaste, and in hair gels. Hydrogels are also able to be embedded with useful properties for medicinal needs, as additional ingredients can be blended into the gel for later release onto the skin or into the body. It is common to have severe wounds treated with antibiotic-carrying hydrogels as it gives a perfect moist environment for the wound to heal while keeping infections away. Similarly, hydrogels can be loaded with pharmaceuticals to give a slow-release drug delivery to the patient. Hydrogels can even be combined with electronic interfaces to precisely monitor drug delivery, or to create advanced test strips to analyze small amounts of liquids. In the future, the use of hydrogels will also increase in tissue engineering for healthcare, lab grown meat, and 3D cell printing, as the gel can create a structure similar to human and animal tissue. Despite these great benefits, there is huge room for improvement in the current state of the art for hydrogel manufacture. Many hydrogels are produced from fossil-derived ingredients. Attempts have been made to create a more natural formulation from cellulose, animal mucus, or other polysaccharides found in nature that can be formed into a hydrogel. However, these ingredients often need to be chemically modified to allow them to cross-link into a gel structure. This decreases their biocompatibility and can expose the end user to chemicals, as well as generating waste during production. It also increases the cost and carbon footprint of production, as chemicals need to be handled in specific temperatures and at certain conditions.

Their use is widespread in society. We see them in moisturizing creams, cosmetic face masks, contact lenses, as absorbents in diapers, in toothpaste, and in hair gels. Hydrogels are also able to be embedded with useful properties for medicinal needs, as additional ingredients can be blended into the gel for later release onto the skin or into the body. It is common to have severe wounds treated with antibiotic-carrying hydrogels as it gives a perfect moist environment for the wound to heal while keeping infections away. Similarly, hydrogels can be loaded with pharmaceuticals to give a slow-release drug delivery to the patient. Hydrogels can even be combined with electronic interfaces to precisely monitor drug delivery, or to create advanced test strips to analyze small amounts of liquids. In the future, the use of hydrogels will also increase in tissue engineering for healthcare, lab grown meat, and 3D cell printing, as the gel can create a structure similar to human and animal tissue.Despite these great benefits, there is huge room for improvement in the current state of the art for hydrogel manufacture. Many hydrogels are produced from fossil-derived ingredients. Attempts have been made to create a more natural formulation from cellulose, animal mucus, or other polysaccharides found in nature that can be formed into a hydrogel. However, these ingredients often need to be chemically modified to allow them to cross-link into a gel structure. This decreases their biocompatibility and can expose the end user to chemicals, as well as generating waste during production. It also increases the cost and carbon footprint of production, as chemicals need to be handled in specific temperatures and at certain conditions. 

Innovative and Amenable

Glycolink is offering an innovative hydrogel developed at the KTH Royal Institute of Technology. By combining a novel protein that acts as a crosslinker and binds to certain polysaccharides, Glycolink can bring a 100% biocompatible and biodegradable hydrogel from renewable resources to the market. Our gel is built from polysaccharides, a class of biomolecule already abundant in food, medicine, and cosmetic products. We use a recombinantly produced protein to cross-link our polysaccharide. The spontaneous binding of our proteins and polysaccharides, which takes place in a water solution at room temperature, means that no chemical modifications are needed, reducing the cost of production. Our novel biomaterial possesses the same versatility and tunability as other hydrogels and is equally amenable to agitation while being completely non-toxic.

Meet the team

Lauren McKee, PhD, CEO

Docent in Biotechnology and Researcher at KTH Division of Glycoscience. She focuses her research on many aspects of sustainable development, including environmental protection and efficient use of natural resources. Lauren holds a PhD in Biochemistry and is the founder of Glycolink.

Mengshu Hao, PhD, Co-Founder

Postdoctoral Research Scientist at KTH. Mengshu is an enzyme biochemist and molecular biologist with a passion and expertise in the study and analysis of novel enzymes, and experience in biomaterials characterization. She holds a PhD in Biology and is a co-founder of Glycolink.

Isak Edvardsson, Business Development Assistant

A business developer with experience from several early-stage startups. Loves the challenge of commercializing scientific discoveries in the area of sustainability. Holds a degree in Business Administration and Finance from Lund University.

Mohamad Takwa, PhD, Chairman of the Board

A serial biotech entrepreneur and strategist who has co-founded several successful start-ups such as Bioextrax, Epigenica, Thyrolytics, and Avsalt. Enjoys the transformation of early-stage technology from bench to market. Holds a PhD in Biotechnology and is a co-founder of Glycolink.


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Don’t hesitate to get in contact with any of our team members if you wish to reach us!


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Ridspogatan 13a
213 77 Malmö
Sweden

info@glycolink.se

Glycolink is offering an innovative hydrogel based on a technology platform developed at the KTH Royal Institute of Technology. By combining a novel protein that acts as a crosslinker by binding to certain polysaccharides, Glycolink is creating a 100% biocompatible and biodegradable hydrogel from renewable resources. The protein is recombinantly produced in our lab, while the polysaccharide is produced by fungi fed on low cost carbon sources. Polysaccharides are found in a range of products we encounter every day, including food and cosmetics. The protein-polysaccharide binding interaction, which occurs spontaneously at room temperature, means that no chemical modifications are needed, reducing the production cost and waste footprint of our process compared to conventional polysaccharide cross-linking techniques. The gel possesses the same versatility and tunability as other hydrogels and is equally amenable to agitation while being completely non-toxic.

Advanced Diagnostic Centers

We constantly upgrade and implement the latest technologies in our laboratory procedures to ensure delivery of perfect health care.

Awards & Honors

9dok Diagnostics is devoted to render exceptional services in terms of care and producing error-free results. Our accreditation with NABL validates our commitment and services.

NABL Accreditation

We render quality and high-standard services to our customers to ensure supremacy at every stage. We have been accredited by NABL, National Accreditation Board for Testing and Collaboration Laboratories.

Qualified Doctors

Our self motivated and dedicated team of doctors has a major role to play in our success and growth and has provided us with an opportunity to deliver outstanding services.

Trusted By 4 Million Patients

Our dedication and passion for rendering extraordinary services to our patients have made us gain the trust of 4 million.ns

Fully Automated Lab

Our pioneering, completely-automated laboratory is furnished with the latest infrastructure.