Biobased Colloids and Materials (BiCMat)

Department of Bioproducts and Biosystems

Biobased Colloids and Materials (BiCMat)

BiCMat group led by Prof. Orlando Rojas works toward supporting global sustainable development through research on the fundamental and utilization aspects of renewable resources, including lignocellulose, proteins and other biopolymers. Our research aims to discover competitive alternatives for fossil materials.

The BiCMat group is based in the Department of Bioproducts and Biosystems and we are an active member of the broader Materials and sustainable use of natural resources key research area at Aalto University. Our research group consists of scholars at various stages of their careers, from MSc. students to Post-doc researchers. In addition, we continually host visiting scholars from other academic/research institutions around the world.

Our research focus:

Our research focus is on finding competitive alternatives to fossil materials through research into bio-based materials at different size scales, mainly those displaying large interfacial areas such as fibers (micro/nano fibers), fiber networks, particles and colloidal systems. We are interested in:

Ligno-nanocellulose and bacterial cellulose:

We utilize novel cellulosic materials from various sources to develop high value-added applications.

Multiphase systems:

We study the fundamental and utilization aspects of multiphase systems, such as dispersions, emulsions, foams, membranes and gels.

Multiphase systems have a large variety of functionalities in the application of textile products, light-weight materials, water treatment, encapsulations, etc. Current environmental concerns have prompted an increasing demand for bio-material-based multiphase systems, such as foams, emulsions, aerogels. Our research interests involves revolving the colloidal-related mechanisms in fiber-based foams for papermaking. Also, we explore the roles and capabilities of (ligno-)cellulosic materials (e.g. (lingo-)cellulosic fibers, (lingo-)nano-cellulose, etc.) in a multiphase system.

Films, filaments and hybrid materials:

We employ the versatility of lignonanocellulose and cellulose derivatives in novel film, paper and filament structures in combination with other nano- and functional materials.

Bionanomaterials are often thought to be difficult to process and limited in functionality. To enable feasible processing, we work on paper, film and filament structures which can conveniently fit into existing industrial processes. Furthermore, we see papers, films and filaments as useful model structures for demonstrating novel functionalizations.

Even though biomaterials can natively have a limited functionality, they typically have a promising chemical versatility. We employ this versatility for new purposes, such as water-resistant, thermoformable, electrically conductive, luminescent or antibacterial cellulose. With this work, we target applications that will be important for tomorrow’s society, such as composite materials, packaging, energy harvesting and rapid diagnostics.

Lignin:

We search for new, more valuable application areas for lignin, for example nanoparticles or coatings.

Lignin is the second most abundant natural raw material and nature’s most abundant aromatic polymer, which can be found in plants. Lignin is generally obtained from black liquor as a waste from pulp industry in large quantities. Although much of the lignin produced by pulp industry is currently consumed as a fuel, there are other, higher value added applications, such as carbon material precursor, emulsifier, coating, filler or substitute for metal/inorganic nanoparticles. We study these new areas for lignin utilization, envisioning lignin’s transition from waste into a valuable raw material.

Proteins:

We research the interactions between proteins and polysaccharides and thus develop materials combining these components.

Proteins, natural and renewable biomolecules, perform a vast number of functions that show great potential in various challenging applications. We study the functional properties of proteins in molecular and surface interactions, crosslinking, foaming, adsorption and separation processes. Specific areas of interest include the interactions between proteins and polysaccharides and materials combining these components. Through this work, we are aiming to improve the formability of cellulose-based materials, create antibiofouling surfaces and other functional biointerfaces relevant to the medical, biotechnological and food fields.

Bioactive cellulose:

We capitalize on the biocompatibility of cellulose in medical applications through modifications with antibodies, enzymes and other bioactive molecules.

We have introduced conjugation of short peptides to nanocelluloses for low cost and disposable sensors as well as supports for detection or separation of bioactive molecules. We aim at developing sustainable bioactive materials that can be safely disposed or regenerated. Specific topics that have been developed in our group include

immunoglobulin G binding and detection
heparin, Avidin-Biotin and other complexes
affibodies and C-reactive proteins
role of ligand spacer on passivation, binding, kinetics, and mass transfer
rapid immunoassays and diagnostics

3d rendering of bioactive (nano)cellulose.

FinnCERES

FinnCERES, competence center for materials bioeconomy, is a Flagship for our sustainable future.

The LIBER Centre of Excellence

LIBER aims to create dynamic and soft hybrid materials with a capability to learn, adapt or response to the environment. LIBER combines eight research groups with expertise on molecular self-assembly, soft robotics, surfaces and interfaces, genetic engineering of proteins, biotechnological production of engineered biomolecules, and computational modelling.