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  • Celignis Pitch for CBE 2024 Topic
    HORIZON-JU-CBE-2024-IA-01

HORIZON-JU-CBE-2024-IA-01 – Bio-based materials and products for biodegradable in-soil applications

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Background

This is a topic in the 2024 work programme of the Circular Bio-based Europe Joint Undertaking (CBE-JU) which was published on December 19th 2023, with the call for proposals opening on April 24th 2024. The deadline for submitting proposals to this call is September 18th 2023, with the results expected by February 2025 and the projects expected to start later in 2025.

Celignis is an SME that was spun-out from an EU research project (the FP7 advanced biofuels project DIBANET) that was written and coordinated by Celignis's founder Daniel Hayes. It has now been over ten years since the end of that project and over that time Celignis has grown in size and reputation and now occupies a valuable niche as being the premier analytical and bioprocess development provider to clients in the biomass sector. We provide a wide range of compositional analysis services and bioprocessing expertise to a diverse array of customers (including SMEs, multinationals, and universities) looking to utilise biomass feedstocks, residues and wastes for the production of biobased products, biofuels, and energy.



But we have not lost sight of the importance of science and in advancing the start of the art. We were born from pioneering research and we are still passionately committed to playing our part in advancing the bioeconomy. As a result we continue to be highly active in European research projects and are particularly excited by the calls presented in the 2024 CBE-JU work programme.

In April 2023 Celignis joined the Bio-based Industries Consortium (BIC) as a Full Industry SME Member, meaning that we can contribute to the strategic direction and future calls of the CBE-JU and that Celignis is an eligible partner for all CBE-JU actions. The CBE requires that any Large Industry or SME partner in Innovation Action (end TRL 6/7) or Flagship (end TRL 8) projects is a BIC member.



"Celignis had successful proposals in over 40% of the CBE-JU Innovation Action topics in 2023. Our Full-Industry BIC membership and extensive scaled-up bioprocessing capabilities make us particularly suited to participation in IA proposals"


Celignis is a partner in 1 ongoing CBE project, with a further 3 (successful awardees of CBE-JU funding in the 2023 call) starting between May and Sept 2024. The ongoing project, PERFECOAT is a RIA (Research and Innovation Action) project, whilst the 3 upcoming projects (BIONEER, PROMOFER, and MANUREFINERY) are Innovation Action (TRL 6/7) projects. The extensive developments in processing capacity (up to 1m3) by Celignis Bioprocess over the last few years make us particularly suited to participation in such higher-TRL topics.

Celignis's Ongoing CBE Projects

Celignis's Completed BBI/CBE Projects
Celignis's Other Ongoing Horizon Europe Projects

Contributions Celignis Can Make to HORIZON-JU-CBE-2024-IA-01

  • Production of liquid and solid mulch films from polysaccharide and protein-rich waste streams, agriculture and forest residues and aquatic plants - Celignis has mastered the extraction of proteins, polysaccharides, lipids and bioactive small molecules from various types of residues. Celignis will use its unique expertise in extraction of the polysaccharides and proteins, enzymatic cross-linking to reduce the hydrophilicity and to encapsulate the bioactives and specific structural modifications to modify the hydrophobicity of the polysaccharides. The finished product has the potential to be used as liquid mulch. With the use of film forming agents and incorporation of plasticisers, a solid flexible bio-degradable film is produced. Celignis has the reactor capacity of 1m3 temperature-controlled mixing vessels and downstream processing equipment to extract and convert the bio-polymers to liquid mulch films. Celignis will design and test the solid mulch film production and produce the prototypes of few square meters and the technology can be transferred to large scale mulch film producers.


  • Germination and plant growth promotion tests - Celignis has experience in performing germination inhibition/promotion tests and plant-growth trials for a variety of materials such as bioactives, biochar, microbes etc. The same expertise will be used for liquid or solid mulch film analysis for their impact on seed germination and plant growth. As plant growth depends on the soil characteristics, Celignis will analyse the soils for improvement or decrease in water holding capacity, drainage capacity, agglomeration and other relevant properties depending on the mulch type.
  • Techno-economics, process modelling & optimisations - Celignis's process engineering and modelling team has years of experience in the analysis of biological and chemical processes for technical and economic feasibility (TEA). The Celignis team can identify the possible high costing nodes of the process through modelling in the early stages of the project and provide suggestions of improving the feasibility of the process. The techno-economic analysis will be done iteratively during the course of the project by performing all the necessary sensitivity analyses on key operational inputs and parameters, including the side streams valorisation or treatment.

    Celignis’s Chief chemical engineer and Bioprocess head Oscar Bedzo has a PhD in chemical engineering with a focus on biomass fractionations and enzyme transformations. He has experience in working with large industry clients through public and private projects and leads the projects very smoothly. Currently, he is doing TEA work for a number of Celignis's private projects and also for the ongoing Horizon-Europe project EnXylaScope which is developing and demonstrating the production of 6 consumer products (personal care, feed/food) from three different feedstocks.

    Celignis is also the partner for full TEA analysis for a successful CBE-JU 2023 proposal. That project (MANUREFINERY), which comprises 23 partners and 11 different technologies being proven at demonstration scale, will start in September 2024.

    Celignis’s team of biomass valorisation and bioprocess experts support the TEA analysis and perform process optimisations based on their years of experience in biomass processing technology development. We are a world-renowned bioprocess development service provider and consultant for the bioeconomy. Having Celignis as a TEA and process optimisation partner in a consortium will bring this extensive expertise to the project.


  • Rapid analysis and process optimisations - As part of our Bioprocess Development Services that we provide to a range of clients, we are able to effectively optimise conditions for a wide range of processes, including biomass fractionations, and enzymatic and chemical conversions of polysaccharides. This is done by improving upstream and downstream process conditions following design of experiments and statistical data analysis. We can effectively apply these approaches to the objectives of this project.

    In addition to this, Celignis’s near infra-red models development expertise for custom feedstocks or products (>20,000 samples used for generating Celignis's global models) will help in use of this analysis for process control especially when feedstock variability can be substantial (waste streams). Our NIR expertise was effectively demonstrated in the recently-completed CBE-JU Innovation Action project VAMOS. It concerned the demonstration (TRL7) of a technology for producing lactic acid from biomass. Celignis's role in the project was as an at-scale rapid analysis developer. Work involved the development of custom rapid NIR models developed for the streams in the VAMOS project. This including us installing an NIR-device at the demo biorefinery and customising the user-side software experience (proprietary Celignis software "CelDeep") so that routine plant operators can get quick actionable data regarding the composition of feedstocks and process outputs. This allowed for much more responsive decision making and process optimisation.

    CelDeep results

  • Biodegradability and preliminary toxicity evaluation - Celignis, with its analytical expertise, can undertake aerobic and anaerobic biodegradability tests. Biodegradation and mineralisation of the product in the soil, aerobic treatment, and anaerobic digestion conditions. Biodegradability assessments will be carried out in lab-controlled conditions and in outdoor soils. In addition to biodegradability Celignis can undertake eco-toxicity assays with the assay of toxicity to bacteria, algae and earthworms. Celignis is equipped with a range of aerobic and anaerobic equipment, chemical and physical analysis devices, microbiology and microscopy equipment to undertake the analysis in a multi-level approach to understand the true biodegradability and eco-toxicity of the developed films.
  • Proposal Evaluation - In 2020 Celignis was the primary writing partner in EnXylaScope, a project specifically focused on the extraction of xylan and on its subsequent modification to be suitable as a component in a range of consumer products. This proposal was successful, and the project started in May 2021. In 2023 Celignis actively took part in writing a CBE-JU Innovation Action project (BIONEER), together with the co-ordinator, and was successful in securing funding.We were also in two other successful CBE-JU proposals in the 2023 call. Additionally, Celignis's Lalitha and Dan have worked for several years as EU Expert Evaluators reviewing CBE-JU proposals and so understand the differences between good proposals and the great ones that end up getting funded.

    As a result of these experiences, plus our Full-Industry membership of the Biobased Industry Consortium (BIC), and due to our experience in offering research and technology development services related to industrial biotech processes, we have a good understanding of the current art in this topic and how an impactful proposal with strong Excellence and Impact can be developed. As a result, we will be happy, as part of our partner constributions towards a proposal, to put forward suggestions as to how a competitive proposal can be drafted.


Related Celignis Projects



Expected Outcomes of CBE-2024-IA-01

In line with the objectives of the Circular Economy and Zero Pollution Action Plan, and the EU Plastics Strategy and the recommendation in the Communication – EU policy framework on bio-based, biodegradable and compostable plastics, the successful proposals will facilitate the deployment of sustainable bio-based biodegradable materials and products for applications in soil.

Successful proposals will also contribute to the implementation of the EU Bioeconomy Strategy and the updated EU Industrial Strategy. Moreover, successful proposals will deliver significant contribution to the objectives of the R&I Missions ‘A Soil Deal for Europe’, in particular objectives ‘Reduce soil pollution and enhance restoration’ and ‘Prevent erosion’, as well as Mission ‘Restore our Oceans and Waters by 2030’ in particular ‘Make the blue economy carbon-neutral and circular’ and ‘Prevent and eliminate pollution of our oceans, seas and waters’.

Project results should contribute to the following expected outcomes:
  • Availability of safe and sustainable by design bio-based solutions aiming at zero waste and zero pollution, with decreased environmental on soil, biodiversity and climate.
  • Contribution to industrial competitiveness and resource independence of bio-based value chains in EU/EEA/EFTA countries and ACs.
  • Improved circularity and resource efficiency via practical application of circular bioeconomy.
  • Social acceptance of circular bio-based solutions and products.
  • Innovative manufacturing processes to enable the safe biodegradation of bio-based materials and products according with the environmental conditions and time frame for specific applications.

Scope of
CBE-2024-IA-01

Some plastics applications such as those in agriculture, infrastructure or landscaping are intended to be used in the open environment. Plastic mulch films, for example, are used extensively within a range of arable and horticultural cropping settings to prevent evaporation of water from the soil, avoid fluctuations in soil temperature, protect the crops and increase their yield. Geotextiles and geomembranes find widespread application in landscaping, construction and roadworks to stabilise and improve mechanical properties of soil, collect and transport groundwater and prevent contamination between different kinds of soil.

Additional plastics applications in agriculture include greenhouses, pheromones dispensers, clips, pots, etc.

The improper or unintentional disposal of plastic products and their degradation may result in soil pollution and environmental contamination.

While in some cases recovery from the environment for reuse or recycling would be feasible, for some applications it is either impossible or disproportionally expensive and biodegradable (in soil) alternatives may be preferable, provided that the products are able to meet technical performance requirements throughout their use.

Proposals Under CBE-2024-IA-01 Should:

  • Demonstrate and deploy innovative production processes for SSbD bio-based products for biodegradable-in-soil applications, addressing the problem of (micro)plastics release in soil and their further dispersion in runoff water. This topic focuses on products used in soil, for example mulch films, tarpaulins, geonets, geotextiles, geomembranes, etc. and plastics applications in agriculture, for example, greenhouses, pheromones dispensers, clips, pots etc; select one or more product categories, providing a justification of the selection based on the relevance of products in the actual market and/or on environmental considerations (e.g., the threats posed by the conventional non-biodegradable solutions for the same applications).
  • The topic does not cover marine and aquatic applications as a main focus. However, spill over of the developed product streams towards other replication sectors (including marine/aquatic) can be considered, in order to widen market applications.
  • Design the products for biodegradation in soil according to the environmental conditions and application timeframe, while ensuring technical performances meeting market requirements throughout the useful life of the product. Moreover, the topic also addresses eco-design and testing of reusability and/or recyclability depending on the final application(s) and use conditions.
  • Demonstrate safe biodegradability of bio-based products designed for specific applications in open environments (soil) under ranges of physical/chemical environmental conditions, including extreme conditions (e.g., temperature, pH) where applicable. Safe biodegradability entails avoiding eco-toxicity, microplastic dispersion and any environmental impacts - from bio-based products including their additives and other components- on natural ecosystems and their services, including on the soil fertility, during and after degradation. All these aspects should be monitored and assessed, also in the phase of dispersion in runoff water.
  • Perform validation trials of the developed bio-based products with the involvement of end users (for example, in case of applications for agriculture are selected, primary sector should be involved).
  • Develop a proposal for appropriate labelling of products when applicable and provide clear instructions on their use and on disposal options after use. This task should include the consultation of targeted stakeholders, e.g., end users. Training of end users should also be envisaged.
  • Contribute with recommendations related to standards for biodegradability in soil.
  • Include a task for projects funded under this topic to collaborate and align the proposals for appropriate labelling, and the recommendations related to standards.
  • Include a task to integrate assessment of the demonstrated bio-based products based on the safe-and-sustainable-by-design (SSbD) framework, developed by the European Commission, for assessing the safety and sustainability of chemicals and materials. Under this context, projects are expected to contribute with and develop recommendations that can advance further the application of the SSbD framework.
Proposals should seek for links and complementarities and avoid overlaps with past, ongoing and upcoming EU funded projects, including those funded under H2020, HEU, the BBI JU and CBE JU, and the Missions ‘A Soil Deal for Europe’ and ’Restore our oceans and water’. Collaboration among projects from the same topic are encouraged.

Proposals should also describe their contribution to the Specific CBE JU requirements, presented in section 2.2.3.1.

Additional Information on CBE-2024-IA-01:

   
Type of Action Innovation Action.
Indicative Budget The total indicative budget for the topic is EUR 15 million.
Expected EU Contribution per Project It is estimated that a contribution of EUR 7.5 million would allow these outcomes to be addressed appropriately. Nonetheless, this does not preclude submission and selection of a proposal requesting different amounts.
TRL TRL 7-8 at the end of the project.
Link to CBE JU Specific Objectives 2.1: Reinforcing the integration of bio-based research and innovation throughout industrial bio-based systems and innovation throughout industrial bio-based systems and increase the involvement of R&I actors including feedstock providers in the bio-based value chains.
3.1: Ensuring the integration of circularity and environmental sustainability requirements, contribution to climate neutrality and zero pollution ambition in the development and implementation of biobased research and innovation and facilitate societal acceptance.
Link to CBE JU SRIA 2.1.2: Deploy innovative production technologies.
2.1.3: Scale up production and market uptake of innovative biobased products.
3.1.2: Incorporate the environmental sustainability and circularity criteria in bio-based systems.
CBE JU KPIs 1.1: Number of primary producers, involved as project beneficiaries and/or engaged in value chains at project level.
4.3: Number of projects developing innovative & sustainable processes enabling to address zero pollution.
4.5: Number of products with improved life cycle environmental performance.
5.1: Number of innovative products that are biodegradable, compostable, recyclable, reused or upcycled (circular by design).
6: Increase innovative bio-based outputs and products.
7: Improve the market uptake of bio-based products.





Other Topics in the CBE 2024 Work Programme

Click here to see a list of the other CBE topics and how Celignis could be a valuable project partner for them.

Pitches for Specific Topics in the 2024 CBE Call


Below we list a number of the topics in the CBE 2024 work programme in which we think we can play a valuable role. These topics cover: Research and Innovation Actions (RIA), Innovation Actions (IA), Flagships (IAFlag), and Coordinating and Supporting Actions (CAS).

Please click on the link for each topic to see more details on it and on the contributions that Celignis can make.

Innovation Actions (IAs)

Below are listed our pitches for IA topics in the CBE-JU 2024 Work Programme. For other topics click to jump to our lists for Research and Innovation Actions (RIA), Flagships (IAFlag), and Coordinating and Supporting Actions (CAS).

HORIZON-JU-CBE-2024-IA-01 – Bio-based materials and products for biodegradable in-soil applications
This topic concerns implementing bio-based, biodegradable products aimed at reducing soil pollution and microplastic issues, aligning with EU environmental strategies. The focus is on enhancing soil-used products, like mulch films, through innovative methods that ensure their safety and biodegradability. Proposals must demonstrate the effectiveness of these products, propose standards for biodegradability, and ensure alignment with EU's sustainable design principles.

Celignis can make important contributions in a number of areas to this topic, including:
  1. Producing bio-degradable mulch films from organic waste and residues, leveraging our expertise in bio-polymer extraction and modification to create both liquid and solid mulch films suitable for large-scale applications;
  2. Conducting tests to determine the effects of bio-degradable mulch films on seed germination and plant growth, assessing improvements in soil properties;
  3. Leveraging our process engineering and economic analysis skills to identify cost-effective production methods, so enhancing the economic viability of bio-based mulch film manufacturing;
  4. Performing comprehensive biodegradability and eco-toxicity evaluations of the products in order to ensure environmental safety and compliance with biodegradation standards;
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Innovation Action projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IA-01




HORIZON-JU-CBE-2024-IA-02 – Sustainable micro-algae as feedstock for innovative, added-value applications
Here the focus is on the demonstration of sustainable industrial systems using micro-algae and cyanobacteria. Such processes are expected to produce a wide array of microalgae-based products that are economically viable and socially accepted. Proposals should focus on optimizing production, harvesting, and extraction techniques that are cost-effective and sustainable, and align with the safe-and-sustainable-by-design (SSbD) framework.

The contributions that Celignis can make towards this topic are outlined in detail here and summarised below:
  1. Enhance the economic viability of algal biorefineries by developing a sequential extraction process for multiple products from residual biomass, leveraging our expertise from the ALGALVANISE project;
  2. Use enzyme cocktails for efficient and less energy-intensive extraction of compounds from algal biomass, leveraging our microbial culture collection for enzyme production;
  3. Provide detailed compositional data for microalgal feedstocks and products, enhancing process efficiencies and product quality;
  4. Reduce costs and enhance efficiencies in algal biorefinery operations, though technoeconomic analysis (TEA) backed-up by our extensive experience in bioprocess development.
  5. Employ rapid analysis NIR technologies to enhance process control and efficiency in algal biorefineries;
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Innovation Action projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IA-02




HORIZON-JU-CBE-2024-IA-03 – Enlarging the portfolio of commercially produced bio-based SSbD solvents
This topic concerns the demonstration of bio-based solvents that align with the EU's Bioeconomy Strategy, aiming for zero pollution and enhanced sustainability within the chemical industry. The target is the production of safer, more environmentally-friendly solvents that meet market needs and increase the EU's strategic autonomy by reducing reliance on fossil fuels and imported biomass. Proposals should innovate with regards to the production, application, and recycling of bio-based solvents, with an emphasis on safety, sustainability, and societal acceptance.

Click here to read in detail regarding the contributions that Celignis can make towards this topic, which are summarised below:
  1. Demonstrate a cost-effective method for producing bio-based solvents through integrated fermentation and enzyme catalysis, targeting the production of polar and moderately-polar solvents for diverse industrial applications;
  2. Utilise second-generation sugars more cost-effectively for bio-based solvent production by applying a Xylan-first approach in our biomass fractionation process, allowing for a lowering in production costs;
  3. Based on our expertise in anaerobic fermentation, we can optimize the production of bio-based solvents by focusing on process enhancements to direct carbon flux towards desired solvent production, without genetic modifications;
  4. Enhance the economic feasibility and efficiency of bio-based solvent production processes through techno-economic analysis and process optimisation;
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Innovation Action projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IA-03




HORIZON-JU-CBE-2024-IA-04 – Circular and SSbD bio-based construction & building materials with functional properties
The CBE-2024-IA-04 call seeks proposals that will lead to the widespread adoption of circular bio-based solutions in construction and potentially in other sectors like transport and furniture. These solutions should not only meet current market and regulatory standards but also improve environmental and health safety profiles, contribute to better air quality, and enhance consumer and end-user acceptance of bio-based materials. Projects should demonstrate these materials' functionality and sustainability through field trials and by ensuring they align with safe-and-sustainable-by-design principles.

Some of the ways in which Celignis can contribute to this topic are detailed here and summarised below:
  1. Evaluate biochar and biopolymers for use in construction materials, leveraging our analytical expertise to test suitability and standardise product consistency for construction applications;
  2. Developing engineered polysaccharides as polymer additives for cement, building on our polysaccharide modification work in the PERFECOAT and EnXylaScope projects;
  3. Developing alginate and cellulose-based foams for biodegaradable insulation materials, with potential for customisation in physical properties through enzymatic and chemical modifications;
  4. Providing techno-economic analysis and process optimization support, facilitating the development of cost-effective and efficient bio-based construction material production processes.
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Innovation Action projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IA-04




HORIZON-JU-CBE-2024-IA-05 – Selective and sustainable (co)-production of lignin-derived aromatics
The topic concerns the up-scaled production of lignin-derived aromatics with a focus on enhancing the atom economy and improving the resilience of the European chemical industry. It is of key importance that the products are safe, sustainable, demonstrate market competitiveness, and achieve societal acceptance.

Celignis is a partner in BIONEER, a CBE-JU Innovation Action project that was successful in the 2023 call for TRL 6/7 production of (non-aromatic) platform chemicals. We see CBE-2024-IA-05 as highly compatible with that project as we can also demonstrate platform chemicals production from the lignin fraction of the BIONEER processes. Celignis can make several important contributions to this topic, detailed here and summarised below:
  1. Produce aromatics using partially depolymerized lignin from our EnXylaScope/BIONEER process, which we believe to be an ideal feedstock for aromatic production due to its clean, unique form;
  2. Developing the microbial production of lignin-derived aromatics, like vanillin from ferulic acid, through collaborating with genetic engineering partners in the project;
  3. Demonstrating an enzyme-assisted process to extract and fractionate high-value aromatics from lignin, offering a novel, low-energy route for lignin valorisation;
  4. Applying rapid analysis and process optimisations to improve efficiencies, building on our successes in the CBE-JU project VAMOS.
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Innovation Action projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IA-05




HORIZON-JU-CBE-2024-IA-06 – Innovative bio-based adhesives and binders for circular products meeting market requirements
This topic focuses on developing sustainable bio-based adhesives and binders to address health, safety, and environmental concerns associated with conventional fossil-based products. Proposals are expected to contribute to the diversification and application range of bio-based adhesives, ensuring they are cost-effective, perform well, and meet market and regulatory standards.

Some of the ways in which Celignis can contribute to this topic are detailed here and summarised below:
  1. Utilise our unique, partially depolymerized, lignin, obtained through an enzymatic process, to develop high-functionality, low-molecular-weight epoxy resins for adhesive applications;
  2. Engineer chitosan from second-generation sugars for adhesives, applying chemical and enzymatic modifications that are-being/will-be used in other CBE-JU projects for products in the personal care and coatings sectors;
  3. Developing and demonstrating xylan-based adhesives by functionalising the xylan and adhesives based on functionalised xylans and lignins cross-linked through chemical agents. Xylan and lignin-based adhesives provide the required rheology and better flow properties compared with cellulose;
  4. Leveraging our process engineering and techno-economic analysis skills to improve the feasibility and to optimise the bio-based adhesive production processes;
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Innovation Action projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IA-06




HORIZON-JU-CBE-2024-IA-07 – Innovative conversion of biogenic gaseous carbon into bio-based chemicals, ingredients, materials
This topic is aimed at transforming biogenic gaseous carbon emissions from bio-based systems and biorefineries into sustainable chemicals, materials, and polymers. It aims to convert what is traditionally viewed as an environmental issue into an opportunity for the EU's socio-economic growth and strategic autonomy. Proposals should focus on capturing and converting these emissions efficiently, promoting industrial symbiosis in the bio-based sector to enhance environmental performance, resource efficiency, and carbon sequestration. Projects should demonstrate advanced carbon capture and utilization (CCU) technologies, assess their replication potential, and evaluate their contribution to EU climate and environmental objectives.

The strong fermentation expertise of the Celignis team allows us to contribute to projects in this topic in several areas, detailed here, with short summaries listed below:
  1. Transforming volatile fatty acids (VFAs) and CO2 into longer-chain fatty acids;
  2. Undertaking Clostridial gas fermentations to produce acids and solvents, involving process optimisations supported by constant analytical monitoring from lab-scale towards scaled-up experiments;
  3. Enriched CO2-utilising acetogens culture for the conversion of carbon-dioxide to acetic acid;
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Innovation Action projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IA-07




Research and Innovation Actions (RIAs)

Below are listed our pitches for RIA topics in the CBE-JU 2024 Work Programme. For other topics click to jump to our lists for Innovation Actions (IA), Flagships (IAFlag), and Coordinating and Supporting Actions (CAS).

HORIZON-JU-CBE-2024-RIA-01 – Valorisation of polluted/contaminated wood from industrial and post-consumer waste streams
This RIA topic targets the development of innovative solutions for the recovery and recycling of post-consumer and post-industrial wood waste, a challenge complicated by the presence of contaminants. The goal is to transform this waste into sustainable bio-based products through new sorting, cleaning, and valorization technologies. Proposals should aim to decrease wood waste disposal through landfill and incineration, promoting circular business models. Successful projects should also demonstrate the feasibility of decontaminated wood waste as feedstock for various sectors, ensuring the process's environmental sustainability and social acceptance.

Celignis can make important contributions in a number of areas to this topic, detailed here and listed below:
  1. Contaminated wood valorisation to produce biobased wood coatings, building on our EnXylaScope fractionation technology and our PERFECOAT process for the production of coatings;
  2. Developing enzyme-based solutions for detoxifying contaminated wood, making it suitable for biorefinery applications by mimicking natural microbial processes;
  3. Analyze contaminated wood to identify heavy metal contaminants and develop biobased solutions for decontamination, enhancing the wood's suitability for various valorisation routes;
  4. Utilise our NIR expertise for the rapid analysis of contaminated wood, developing feedstock-specific NIR models to improve process control and decision-making;
  5. With our strong background in techno-economics and process optimization, we can identify cost reduction opportunities and enhance the feasibility of converting contaminated wood into valuable biobased products.
Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-RIA-01




HORIZON-JU-CBE-2024-RIA-02 – Biotech routes to obtain bio-based chemicals/ materials replacing animal-derived ones
Here the focus is on replacing animal-derived raw materials used in industries like cosmetics, textiles, and material production with sustainable bio-based alternatives from plants, fungi, algae, or microbes. This shift aims to address sustainability concerns, animal welfare issues, and health-risks associated with pathogens in animal products. Proposals should develop novel biotech production routes that are scalable and meet end-user requirements, ensuring safety, sustainability, and positive socio-economic impacts throughout the value chain.

Some of the contributions that Celignis can make to this project are detailed here and listed below:
  1. Engineered polysaccharide composites for replacement of animal derived products in the clothing and comfort sectors;
  2. Microbial and/or engineered plant polysaccharides to replace animal-derived gelatin;
  3. Engineered polysaccharides with plant oils to mimic the texture and functionalities of animal fats in food and cosmetics, enhancing moisture-holding properties and providing a vegan option;
  4. Using techno-economic analysis to identify cost-effective and efficient production routes for bio-based alternatives to animal-derived products;
Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-RIA-02




HORIZON-JU-CBE-2024-RIA-03 – Sustainable, bio-based alternatives for crop protection
This topic addresses the significant challenge of crop loss due to plant pests and diseases, emphasizing the need for sustainable bio-based alternatives to chemical synthetic pesticides. The topic aligns with policy goals to halve the use and risk of chemical pesticides by 2030. Proposals should focus on developing safe, effective, and environmentally friendly biopesticides, considering logistics, processing, and the impact of climate change on pest behavior. The aim is to increase the availability of cost-efficient, low-risk plant protection solutions, enhancing crop productivity and food security while minimizing the health and environmental impacts of pesticides.

Click here to read in detail how Celignis can contribute to projects in this topic. These potential contributions are also summarised below:
  1. Use of agricultural and forestry residues for the production of crude extracts as plant protectants, isolating polyphenols/flavonoids and leveraging our existing biomass fractionation processes for more sustainable extractions;
  2. Use microbial and fungal extracts as biopesticides, with a focusing on isolating and purifying the active compounds from promising strains for effective plant protection;
  3. Optimising the extraction and purification of potent plant metabolites, like tri-terpenoids, for their anti-microbial properties, aiming to improve the sustainability of the purification process;
  4. Using xylan-derived hydrogels for the encapsulation and controlled release of plant protectants.
Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-RIA-03




HORIZON-JU-CBE-2024-RIA-04 – SSbD bio-based coating materials for applications under demanding and/or extreme conditions
This topic targets the development of sustainable bio-based coatings to replace fossil-based and mineral-origin coatings currently prevalent in various industries like transport, construction, and textiles. The goal is to create safer, more environmentally friendly alternatives that meet market performance requirements and show potential for cost-effectiveness at scale. Proposals should diversify the portfolio of bio-based coatings, increase their application range, and improve sustainability, circularity, and health and safety profiles. They should also assess the feasibility of scaling up the developed solutions.

Click here for detailed descriptions on how Celignis can contribute to projects in this topic. These potential contributions are also listed below:
  1. Develop hydrophobic xylan- and xylose-based polymers for furniture coatings, aiming to extend their application to textiles for enhanced hydrophobicity and stain resistance.;
  2. Synthesize biobased polymers with anti-microbial and anti-fouling properties using zwitterionic molecules, targeting a variety of surfaces;
  3. Modifying lignins for water-based coatings, focusing on high-performance applications in construction and anti-fouling;
Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-RIA-04




HORIZON-JU-CBE-2024-RIA-05 – Innovative bio-based food/feed ingredients
CBE-2024-RIA-05 seeks to develop sustainable and healthy bio-based ingredients for human and animal nutrition. With the global push towards healthier and more sustainable food chains, this initiative focuses on pilot-scale development and validation of innovative food and feed ingredients like prebiotics, vitamins, and fats that enhance nutrition and health. Proposals are encouraged to explore breakthrough processes for known ingredients or novel ingredients, ensuring environmental, social, and economic sustainability, and involving end users early to assess market acceptance.

Our potential contributions are outlined in detail here and summarised below:
  1. Extracting and purifying RuBisCo for its nutritional properties, aiming to develop a cost-effective purification strategy to enhance its digestibility and functional benefits;
  2. Using xylan hydrogels for the efficient storage and delivery of pre- and post-biotics, aiming to overcome the limitations of current delivery systems and enhance the viability of probiotics;
  3. Using native and enzymatically-modified xylans as food and feed ingredients, particularly for their water-holding capacity and synergy with other food formulations;
  4. With our extensive expertise in techno-economic analysis and process optimisation, Celignis can help to make the production of bio-based food and feed ingredients more sustainable and economically viable.
Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-RIA-05








Flagships (IA-Flagship)

Below are listed our pitches for IA-Flagship topics in the CBE-JU 2024 Work Programme. For other topics click to jump to our lists for Research and Innovation Actions (RIA), Innovation Actions (IA), and Coordinating and Supporting Actions (CAS).

HORIZON-JU-CBE-2024-IAFlag-01 – Bio-based value chains for valorisation of sustainable oil crops
This topic focuses on the TRL-8 cultivation and use of oil crops for biorefining applications in Europe, emphasizing compatibility with biodiversity protection. It aims to enhance the bio-based industry's sustainability, strategic autonomy, and competitiveness without compromising food value chains. Proposals should demonstrate large-scale cultivation of oil crops that ensure environmental benefits, meet biorefinery requirements, and do not negatively impact the environment. The initiative seeks to develop bio-based products from these crops, revitalizing rural areas through green job creation and local business opportunities.

Listed below are some contributions that Celignis can make to this topic, click here to read about these in more detail.
  1. Detailed characterisation of oil crop feedstocks, processing outputs, and residues;
  2. Perform TEA and optimization studies to identify cost drivers and propose solutions to enhance the feasibility and sustainability of using oil crops in biorefineries;
  3. Provide rapid, on-the-go analytical data for process control, enhancing responsiveness and optimisation in processing oil crops for bio-based applications.
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Flagship projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IAFlag-01




HORIZON-JU-CBE-2024-IAFlag-02 – Bio-based dedicated platform chemicals via cost-effective, sustainable and resource-efficient conversion of biomass
The focus of this Flagship topic is on overcoming the challenges of cost competitiveness and sustainability in the production of bio-based dedicated platform chemicals, which are currently at a medium/high technology readiness level but face hurdles in scaling up. Proposals should demonstrate cost-effective, large-scale production processes that enhance process efficiency and sustainability while reducing dependence on fossil feedstocks and minimizing waste. The project seeks to validate these bio-based chemicals in market-relevant applications.

Click here to read in detail on Celignis's potential contributions to this topic, which are summarised in the list below:
  1. Process Optimization Support - Combining bioprocess development expertise with compositional analysis capabilities, we can contribute towards improvements in products yields and qualities, also focusing on the valorization of side streams for a more sustainable production process;
  2. Techno-Economic Analysis and Process Modelling: To identify cost-reduction opportunities and enhance the sustainability and efficiency of the bio-based chemical production process;
  3. Compositional Analysis: Leveraging extensive experience, Celignis can provide in-depth compositional analyses aiding in understanding feedstocks, process streams, and product characteristics crucial for optimising bio-based chemical production;
  4. Rapid Analysis Methods: Utilizing advanced NIR models and expertise, Celignis can offer rapid analysis for real-time process control, enhancing efficiency and decision-making in the production of bio-based chemicals.
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Flagship projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IAFlag-02




HORIZON-JU-CBE-2024-IAFlag-03 – Bio-based value chains for valorisation of sustainable natural fibre feedstock
This Flagship targets the sustainable development and large-scale deployment of natural fibre feedstock, encompassing both non-woody and wood-based fibres. It emphasizes sustainable agricultural and forestry practices to produce fibres that meet industrial requirements while ensuring biodiversity protection, soil health, and sustainability. Proposals should demonstrate sustainable cultivation, innovative biorefinery processes for fibre conversion, and the development of bio-based products meeting market demands.

Below are listed some of our potential contributions to projects under this topic, click here to read about these in more detail.
  1. Compositional Analysis: Celignis's extensive experience in compositional analyses of diverse biomass types will ensure accurate characterisation of feedstocks and by-products, crucial for optimizing fibre yield, quality, and sustainability within the bio-based value chains;
  2. Rapid Analysis Methods: Leveraging Celignis’s NIR expertise for real-time process control will enhance feedstock variability management, critical for the efficient production of sustainable fibres and ensuring their consistent quality for bio-based applications;
  3. Process Optimisation Support: Combining Celignis's bioprocess development services with our compositional analysis expertise, we can help to optimise biorefinery processes, enhancing yield, and quality while focusing on the sustainability and valorization of side-streams for fibre production.
  4. Techno-Economic Analysis: Our involvement in TEA will help to advance the project's commercial viability, focusing on reducing costs and enhancing the sustainability of fibre production.
As a Full Industry Member of the Biobased Industries Consortium (BIC), Celignis is eligible to participate as a partner in CBE Flagship projects such as this one.

Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-IAFlag-03




Coordinating and Supporting Actions (CSAs)

Below are listed our pitches for CSA topics in the CBE-JU 2024 Work Programme. For other topics click to jump to our lists for Research and Innovation Actions (RIA), Innovation Actions (IA), and Flagships (IAFlag).

HORIZON-JU-CBE-2024-CSA-01 – New forms of cooperation in agriculture and the forest-based sector
This CSA topic is concerned with enhancing cooperation among primary producers and integrating them into bio-based value chains through innovative business models. This aims to distribute economic benefits more equitably, increase competitiveness, and provide access to markets and innovation. Proposals should explore cooperative models to optimize biomass processing for high-value bio-based products, improving sustainability, resilience, and job creation in rural areas. They should address the feasibility of new cooperation forms, develop wider value networks, and overcome barriers to using underutilized biomass.

Our experience in the CSA project ENABLING puts us in good stead for participation in this topic. Click here to read in detail about some of our potential contributions, which are listed below:
  1. Feedstock Composition and Availability Survey: We can provide detailed characterisation and availability data for underutilised biomass, leveraging its extensive database and experience from the ENABLING project to enhance biomass supply chain knowledge and support bio-based product development;
  2. Biomass Process Flows: Utilizing mathematical models developed for the ENABLING project, we can estimate the potential production capacities for biochemicals and biopolymers from various feedstocks, aiding in the optimization of bio-based value chains;
  3. Policy Development: Drawing on our involvement in the EnXylaScope project, we are equipped to review and recommend policy changes that encourage the use of bio-based alternatives, supporting the objectives of fostering a more sustainable and circular bioeconomy.
Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-CSA-01




HORIZON-JU-CBE-2024-CSA-02 – Mobilize inclusive participation in bio-based systems and supporting the CBE JU widening strategy and its action plan
This topic focuses on enhancing participation and innovation capacity in the bio-based sector among countries and regions within the EU that have not yet fully tapped into their potential in this area. It aims to implement the CBE JU Widening Participation strategy by fostering stakeholder engagement, capacity building, and collaboration across underrepresented regions to boost their involvement in the European bio-based economy. Proposals should support knowledge transfer, raise awareness of the CBE JU program, and encourage synergies with other funding programs and initiatives. The ultimate goal is to increase innovation, create green jobs, and promote a sustainable, circular bio-economy, particularly in areas that could benefit significantly from bio-based systems but have yet to do so.

Celignis has experience in participating in CSA projects with similar targets to this topic. We believe we can make important contributions in a number of areas, including those listed below.
  1. Knowledge Exchange and Start-up Experience - Celignis, originating from an EU-funded project and growing into a global bioeconomy service provider, can share valuable insights on transitioning research to commercial success. This experience, though from Ireland (outside the CBE-JU widening strategy countries), offers valuable knowledge exchange and guidance to newcomers, particularly from industries in underrepresented countries;
  2. Horizon Europe Participation Advice: Celignis's active involvement in numerous EU-funded projects, including successful participation in recent CBE-JU calls, positions us as a valuable resource for sharing best practices on EU proposal participation. We can facilitate the creation of an online platform for exchanging best practices and providing training, significantly benefiting stakeholders from underrepresented countries and regions looking to engage more effectively in the CBE-JU program and Horizon Europe calls.
Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-CSA-02




HORIZON-JU-CBE-2024-CSA-03 – Supporting the CBE JU Deployment Group on Primary Producers
This CSA topic concerns how to better integrate primary producers (farmers, foresters, fishers, etc.) into the circular bioeconomy, helping them benefit from sustainable practices. Proposals should support the CBE JU Deployment Group on Primary Producers in developing and updating an action plan to meet its objectives, while taking into consideration the particularities and specificities of each one of the identified primary sectors.

Below are listed some of our potential contributions to this topic, which are discussed in more detail here.
  1. Access to Celignis's network of primary producers and biobased industries - Our established connections with primary producers and bio-based industries across Europe can aid action plan development;
  2. Technology expertise - We can bring to the consortium the benefits of a Full-Industry Biobased Industries Consortium (BIC) member that understands the commercial considerations related to matching the right technologies and logistical structures with primary producers and the biobased industry players in Europe;
  3. Training and Support - Provide on-site training, educational materials, and coaching to enhance stakeholder knowledge of bio-based value chains and support primary producer understanding of alternative revenue streams.
Click here to read more about the contributions we can make to this topic as well as to get some more information about the call.

Full Pitch...CBE2024-CSA-03




The Value Celignis Can Bring to a CBE Project


We believe that we can make valuable contributions to projects covering a large number of the topics in the 2024 CBE work programme, based on our expertise in:

Extraction of Hemicellulose Polysaccharides

To date much of the innovations related to the valorisation of lignocellulosic feedstocks has focused on the cellulose and lignin fractions. In most technologies hemicellulose is broken down in the process to either monomeric sugars (e.g. xylose) or their derivatives (e.g. furfural). However, hemicelluloses, when retained in the polymeric form, can have outstanding physical and chemical properties which make them suitable for incorporation in an array of consumer products, replacing less-sustainable product components and so allowing for greener market options for the consumer.

Celignis is the technical lead in the €6m Horizon Europe project EnXylaScope which focuses on the efficient extraction of xylan, the most abundant hemicellulose polysaccharide, and its subsequent modification to confer properties that make it suitable as an ingredient in a scope of consumer products. In the CBE/BBI project PERFECOAT Celignis is also working on extraction of xylan, from different feedstocks, so that it can ultimately be used as a binder in paints and coatings. In the CBE-JU Innovation Action project BIONEER, due to start in June 2024, we will be scaling-up to TRL7 (1.5m3 reactor-scale) the xylan extraction process developed in these projects. We consider that integrating efficient methods for extracting hemicellulose polymers within the wider biorefinery process scheme will allow for higher-value products and a more sustainable and profitable process.

Our expertise in hemicellulose extraction is therefore relevant to a large number of topics within the CBE-JU 2024 Work Programme, in particular:
Related Projects


Modification of Polysaccharides

An efficient extraction process is only one component in developing value-added products from polysaccharides. In many cases further treatment of the polymer is required in order to confer the physical and chemical properties that are required for the desired application/market. Such properties that can be influences with these modifications include the the rheology and water-resistance of the polymers.

At Celignis we also have extensive experience in such modifications using both enzymatic and chemical approaches. For example, in the Horizon Europe project EnXylaScope we are active in the discovery and application of enzymes for the debranching of xylan and for its subsequent modification for additional functionalities. In the CBE/BBI project PERFECOAT the focus is on the chemical modification of xylan in order to enhance its properties for application as a binder in paints and coatings. We consider that integrating efficient methods for extracting hemicellulose polymers within the wider biorefinery process scheme will allow for higher-value products and a more sustainable and profitable process.

In PERFECOAT we are also working on the extraction and modification of chitosan, from prawn shells, whilst we have also internally worked on processes focused on the extraction and modification of pectin. Additionally, as outlined in the video below, we have developed processes for the modification of seaweed-derived alginate to confer the desired physicochemical properties.

In the CBE-JU Innovation Action project BIONEER, due to start in June 2024, we will be scaling-up to TRL7 (1.5m3 reactor-scale) many of the polysaccharide modification approaches described above.

The ability to selectively and cost-effectively modify polymers is a key component of many topics in the CBE-JU 2024 Work Programme, in particular:
Related Projects


Identification, Extraction, and Purification of High Value Chemicals in Biomass

The CBE-JU recognises that biomass valorisation can involve much more than the processing of cellulose, hemicellulose, and lignin. Non-structural components of the plant can also be of value, in some cases being worth thousands of Euros per kilogramme. There are numerous examples of such high value constituents, with the most prominent recent example being the extraction, isolation, and purification of cannabinoids (in particular CBD and CBG) from hemp, which has developed into a multi-billion Euro industry.

At Celignis, we can play important roles at all stages in the valorisation of such compounds, starting from their identification and ending in their purification and the testing and modification of their functional and chemical properties. For identification, we firstly get a crude extract from the feedstock, obtained via various approaches, including pressurised liquid extraction. This extract is then profiled using our top-range QTOF-LC/MS system (Agilent iFunnel 6550), which can identify constituents to the femtogram-level, and the spectra and chromatograms reviewed by Sajna, our Bioanalysis Developer. If necessary, we can collect the relevant fractions from the LC system and confirm the identification using a number of different chemical and spectroscopic techniques. We then determine which constituents warrant extraction and then work on optimising a targeted extraction method. This method considers not only the yield of the target compound(s) but also the chemical and energy costs of the process and the implications for the downstream processing and valorisation of the solid residue, evaluated by Oscar, our technoeconomics analysis (TEA) expert. We subsequently work on the isolation and purification of the targeted compound(s) from this extract, again considering the commercial and scale-up implications.

Celignis undertook such an approach in the CBE/BBI project UNRAVEL where the extractives of 25 feedstocks were profiled using QTOF-LC/MS. We identified betulin in birch bark as the most attractive compound and subsequently worked on developing an optimised extraction protocol and an isolation/purification process scheme that offered several advantages, in terms of sustainability and safety, over the current art. Click here for a news article on this work. We are also using employing our compositional analysis and purification expertise in the Horizon Europe project SteamBioAfrica where we evaluate and process the liquid condensate obtained from the steam torrefaction process and consider market applications for its constituents, fractions, and derivatives.

Our high-value-chemicals expertise is of particular value for improving the competitiveness of a biorefinery process, through employing the principle of the cascading use of biomass. For example, a relatively minor component of biomass can substantially improve the financial viability of a technology if it can be sold at a high price. As a result, such an approach can make important contributions to a number of the 2024 topics, such as:
Related Projects


Real-Time Analysis of Feedstocks and Process Outputs

We have extensive expertise in the development of algorithms and models for rapidly predicting the composition of samples using their near infrared spectra. This allows the time for analysis to be reduced from weeks to seconds. To date we have tens of thousands of biomass samples in our proprietary models for lignocellulosic composition and we have also developed custom models for feedstocks and pretreatment/bioprocess outputs in the CBE-JU/BBI-JU RIA projects BIOrescue and UNRAVEL. In BIOrescue we developed custom software, employing a browser interface for the user, that allowed us to tailor the model-generation and composition-prediction experience to the requirements of our lab personnel and in-house chemometricians. This software also employed advanced chemometric techniques that we proved, in project deliverables, to deliver improved accuracies in prediction over the conventional PLS approaches.

Our NIR and software development expertise was demonstrated at-scale in the recently-completed CBE-JU Innovation Action project VAMOS. At the demo-scale facility in Swansea, UK, we installed NIR equipment and deployed our latest software, "CelDeep", for at-line analysis by biorefinery operators. The VAMOS project allowed us to extend the reach of our predictive models beyond our own laboratories and into the global biorefinery landscape.

CelDeep results


We see many opportunities, within the 2024 CBE-JU topics, to apply and refine this at-line analysis system to other IA projects as well as for Flagship projects. In addition, we also plan for the deployment of in-line analyses, using Celignis-developed models, using the latest state-of-the-art and cost-effective hardware on the market.

While there are numerous options currently on the market for NIR hardware, there is no robust solution currently available for the at-line/in-line analysis of lignocellulosic feedstocks and process outputs/residues. This is due to the complexity of such analysis, the difficulties often faced in getting precise and representative data, and the widely varying outputs of different biomass processing technologies. At Celignis, however, we have years of expertise in getting precise lignocellulosic data and in using these data as inputs to our chemometric tools. As a result Celignis provides full vertical integration regarding advancing the art in rapid biomass analysis and the utilisation of biorefinery data.

Our abilities to develop on-site rapid analysis solutions are applicable to many of the Innovation Action and Flagship topics of the 2024 CBE-JU Work Programme, including:
Related Projects




Compositional Analysis

As detailed throughout this website, the Celignis team are highly experienced in a wide array of methods for the compositional analysis of biomass and process intermediates and outputs/residues for lignocellulosic and thermal properties. Our expertise also extends to seaweed, algae, and a large variety of functional molecules many of which have large future potential in substituting for the use of fossil fuels in the production of consumer and industrial products.

We have an wide array of equipment that allow us to obtain the required compositional data, including an extensive chromatography laboratory that includes state-of-the-art equipment, such as our QTOF-LC/MS system.

Our in depth understanding of the steps involved in the processing of biomass also allow us to bring forward suggestions to other partners in the consortium, based on the analytical data we obtain, on how the project's technologies can be improved.

Our expertise in compositional analysis, and in the understanding and process implications of compositional data, is relevant to all of the RIA, IA, and IAFlag topics of the 2024 CBE-JU Work Programme.

Related Projects


members of the Celignis Analytical team

Fermentation Optimisation

Microbial conversion of sugars to chemicals and fuels is considered advantageous over chemical processes, but is a challenging area due to the high number of variables involved in the process. Fermentation process development involves: selection of microbes to produce the desired product, screening of microbes, media engineering, process optimisation, scale-up, downstream designing, etc. Screening and optimisation involve hundreds of runs which is labour and time intensive. Know-how in the area of microbiology, bioprocess engineering and design of experiments (DOE) can significantly reduce the number of experimental runs and time involved in the preliminary screening and optimisation process.

With our CIO Lalitha and our Bioanalysis Developer Sajna we have the expertise and knowledge to optimise fermentation processes for high yield and productivity in short-time. Our personnel have proven scientific records in producing enzymes, biofuels, biosurfactants, exopolysaccharides and prebiotics through aerobic and anaerobic fermentation processes.

Celignis also has numerous bioreactors, ranging from 1 litre to 1.5m3 litres capacity, that allow us to undertake an extensive DoE approach in optimising fermentations.

Our expertise in fermentation is particularly relevant to the following topics of the 2024 CBE-JU Work Programme:
Related Projects


Discovery and Use of Enzymes

Our team has years of experience in discovery and use of enzymes for deconstruction of lignocellulosic biomass and, with Celignis participation in EU projects like EnXylaScope, this experience is expanded to enzymes useful for modification of the xylan fraction of lignocellulosic biomass.

The discovery of enzymes needs rapid analysis methods and, by understanding the action of enzymes and the changes that occur in the substrate, the Celignis team can develop simple high-throughput screening methods for the discovery of enzymes. This is currently being undertaking in EnXylaScope for xylan side-chain acting enzymes.

Celignis is also discovering enzymes and designing enzyme cocktails for lignocellulose deconstruction aiming at production of monomeric and oligomeric sugars and for generating clean lignin for lignin valorisation purposes. We are undertaking the scaled-up (1.5 m3 reactor-scale) deconstruction of lignocellulosic biomass to sugars as part of the CBE-JU Innovation Action project PROMOFER, which will start in July 2024.

As part of our STEAME project we are also isolating the microbes that have the ability to produce a cocktail of enzymes for increasing the productivity and yields of biogas from complex recalcitrant streams such as late cut grass, wheat straw and garden waste.

Celignis follows traditional methods in enzyme screening allowing the isolation of natural enzyme producers which means that enzyme cocktails developed by Celignis are non-recombinant in nature. The enzymes discovered are studied for various characteristics such as nature of protein (Molecular weight, hydrophobicity); kinetics (reaction and inhibition); optimum reaction conditions etc. Celignis has a collection of around 200 strains capable of producing a range of enzymes that act on a variety of substrates.

Our expertise in enzymes is particularly relevant to the following topics of the 2024 CBE-JU Work Programme:


Related Projects


Anaerobic Digestion and Fermentation

We have years of experience in various types of anaerobic fermentation and anaerobic digestion for the production of chemicals and fuels. The team has knowledge and experience in isolation and handling of Clostridial strains and clostridial fermentations for the production of hydrogen, organic acids and solvents. Celignis's CIO Lalitha Gottumukkala has published several articles in the area of Clostridial fermentation, especially for biobutanol. Lalitha also, during her time in Stellenbosch University, South Africa, optimised a process for the sequential production of bioethanol and biogas from paper sludge.

Celignis is using this expertise in the development of an advanced anaerobic digestion process design (STEAME) that allows high volumetric productivity and yields. This is being done as part of a nationally-funded project. In this process, the thermophilic nature of archaea is taken advantage of together with the ability of Clostridia to digest complex feedstocks. In STEAME Celignis is using expertise in biomass pretreatment together with microbial and enzyme expertise to enhance the anaerobic digestion of late-cut grass, wheat straw and other complex-recalcitrant agricultural residues.

Celignis also provides services for biomethane potential (BMP) determination; anaerobic toxicity assays; specific hydrolytic, acidogenic and methanogenic potential using its 90 1L anaerobic digestion reactors. Celignis has also the reactor set-up for continuous anaerobic digestion and sequential continuous anaerobic digestion that allows two stage and multi-stage digestion. Additionally, the Celignis team also has strong expertise in the valorisation and treatment of food industry effluent streams and is providing consultancy for three years for the operation of high-rate digesters that process 60 m3/h of dairy industry waste streams. This expertise is of particular value in EU projects where zero-pollution is the process target.

Our AD experience is particularly relevant to the following topics of the 2024 CBE-JU Work Programme:
Related Projects




Biomass Pretreatment and Fractionation

Based on our bioprocessing and compositional expertise, we have a very good understanding of how to optimise biomass pretreatment processes. For our clients we have analysed hundreds of samples of outputs from biomass pretreatment processes. We have a very strong understanding of the chemistry of biomass and how to evaluate the conversion and valorisation of the main constituents of lignocellulosic biomass (cellulose, hemicellulose, and lignin). We target mass-closure in our analysis so that the full mechanisms of conversion can be understood and we have a suite of analytical methods to characterise process liquids for monomers, oligomers, sugar degradation products, and fermentability. Our CBE-JU project UNRAVEL concerned the development of a pretreatment process and Celignis played a key role in the project regarding the analysis of the products of pre-treatment and by investigating the influence of extractives in biomass pretreatment. In our completed BBI project BIOrescue we also analysed the solid and liquid outputs of biomass pretreatment and developed rapid analysis models for them using near infrared spectroscopy.

Additionally, in July 2024 the CBE-JU Innovation Action project PROMOFER will start. In that project Celignis is resposible for the at-scale (1.5m3 reactor-scale, equivalent to TRL7) pretreatment and hydrolysis of lignocellulosic biomass in order to provide second-generation sugars to other partners in the consortium. We will also be involved in optimising downstream stages of the process so that the sugars delivered to the project partners will be suitable for fermentation.

Our pre-treatment/fractionation expertise is particularly relevant to the following topics of the 2024 CBE-JU Work Programme:
Related Projects




Process Flow Diagrams and Techno-Economic Analysis of the Process

Bioprocesses are complicated, with several upstream and downstream process unit operations to achieve the final product. Celignis's process engineering team has several years of expertise in performing techno-economic analyses (TEA) for the conversion of biomass to biofuels and chemicals. Celignis performs techno-economic analysis from the process concept design and uses it for economic optimisation of the process together with the yield optimisation. This process is done iteratively during the course of the project to achieve the process optimised for conversion efficiencies and economics. Our process engineers develop TEAs for multiple scenarios of the same process and perform sensitivity analyses to identify the major contributors of the operation's cost to allow development of economically-viable processes without sacrificing the process yields.

Celignis is developing PFDs and performing TEA for the Horizon Europe project EnXylaScope, where the analysis is being performed for enzyme production, extraction of xylans, and use of enzymes for the modification of xylans.

Additionally, Celignis is the key TEA partner for the CBE-JU Innovation Action project MANUREFINERY, which will start in September 2024.

Our TEA expertise is relevant to all RIA, Innovation Action, and Flagship topics in the 2024 CBE-JU Work Programme.

Related Projects


PFD of a biogas process

Successful Proposal Writing and Proposal Evaluation

Dan Hayes wrote the €3.7m, 14 partner, EU project DIBANET from which Celignis spun-out of whilst, more recently, Lalitha Gottumukkala wrote the €6m, 13 partner, Horizon Europe project EnXylaScope, which started in 2021. Celignis personnel have also been successful as the primary authors of proposals for the EU's INNOSUP and Marie-Curie programmes, as well as for a number of nationally funded projects (e.g. the STEAME project).

In 2023 Celignis was invited to large number of consortia for CBE-JU proposals and we actively contibuted towards the writing process for these projects. As a result, we celebrated a number of successes when the results were announced in January 2024.

In addition, both Lalitha and Dan have, for a number of years, been Expert Evaluators for proposals submitted to the BBI-JU (the precursor to the CBE-JU). As a result we have a good understanding of what makes a good proposal and what will improve the chances of a project being funded, hence we can give valued advice to proposal coordinators regarding the direction and focus of a proposal.

Successful EU Proposals Primarily Written By Celignis Personnel



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See our pitches for the 2024 topics.


Special Offer
Mar 30th 2024
CBE-JU 2024 Call Opens - See our Pitches for Proposals

Click here to view our pitches for involvement in proposals for the 2024 research topics of the Circular Bioeconomy Europe Joint Undertaking (CBE-JU).

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Analysis Packages

P3 : Ash Content
P4 : Ethanol Extractives
P5 : Water Extractives
P6 : Full Extractives
P7 : Lignocellulosic Sugars
Total Sugars, Glucose, Xylose, Mannose, Arabinose, Galactose, Rhamnose,
P8 : Lignin Content
Lignin (Klason), Lignin (Acid Soluble), Acid Insoluble Residue, Ash (Acid Insoluble),
P270 : Protein-Corrected Klason Lignin
P9 : Lignocellulosic Sugars and Lignin
P10 : Sugars, Lignin, Extractives, and Ash
P19 : Deluxe Lignocellulose Package
As P10 plus protein-corrected lignin, water-soluble sugars, uronic acids, acetyl content and starch.
P11 : NIR Prediction Package
Ligno. Sugars, Lignin, Ethanol-Soluble Extractives, Ash
P14 : Starch Content
P15 : Uronic Acids
Glucuronic Acid, Galacturonic Acid, Mannuronic Acid, Guluronic Acid, 4-O-Methyl-D-Glucuronic Acid, Iduronic Acid,
P16 : Acetyl Content
P17 : Biomass Amino Acids
Alanine, Arginine, Aspartic Acid, Cystine, Glutamic Acid, Glycine, Histidine, Isoleucine, Leucine, Lysine, Methionine, Phenylalanine, Proline, Serine, Threonine, Tyrosine, Valine,
P18 : Biomass Lipids as Fatty Acids
P20 : Lignin S/G Ratio
Ratio of syringyl (S) and guaiacyl (G) lignin units

P121 : Evaluation of Biomass for Enzymatic Digestibility
Total Sugars in Enzyme Hydrolysate, Glucose in Enzyme Hydrolysate, Xylose in Enzyme Hydrolysate, Arabinose in Enzyme Hydrolysate, Mannose in Enzyme Hydrolysate, Galactose in Enzyme Hydrolysate, Rhamnose in Enzyme Hydrolysate, Cellobiose in Enzyme Hydrolysate, Enzymatic Hydrolysis Kinetics, Cellulose Conversion Yield, Xylan Conversion Yield, Combined Sugar Yield, Cellulose Conversion Rate, Xylan Conversion Rate,
P122 : Evaluation of Pre-Treatment on Enzymatic Digestibility
As P121 plus comparisons with data from the non-pretreated original sample, including: Increase in Cellulose Accessibility after Pre-Treatment, Percent Increase in Cellulose Conversion Efficiency, Percent Increase in Cellulose Conversion Rate.
P123 : Composition of Residue from Enzymatic Hydrolysis
As P9 but on the solid residue after enzymatic hydrolysis.
P124 : Fermentation Inhibitors in Enzymatic Hydrolysate
Formic Acid, Acetic Acid, Levulinic Acid, Furfural, Hydroxymethylfurfural,
P125 : Cellulase Saccharification Efficiency
Includes all hydrolysate sugars and kinetics in P121 and: Cellulose Conversion Yield, Cellulose Conversion Rate
P126 : Xylanase Saccharification Efficiency
Includes all hydrolysate sugars and kinetics in P121 and: Xylan Conversion Yield, Xylan Conversion Rate
P127 : Amylase Saccharification Efficiency
Total Sugars in Enzyme Hydrolysate, Glucose in Enzyme Hydrolysate, Maltose in Enzyme Hydrolysate, a-Amylase Hydrolysis Kinetics, Glucoamylase Hydrolysis Kinetics,
P128 : Cellulase Activity
P129 : Cellulolytic Enzymes Activity
Cellulase Activity, Endoglucanase Activity, b-Glucosidase Activity, Xylanase Activity,
P130 : Amylolytic Enzymes Activity
a-Amylase Activity, Glucoamylase Activity,

P12 : Sugars in Solvent Extract
Glucose, Xylose, Fructose, Sucrose, Mannose, Arabinose, Galactose, Rhamnose, Xylitol, Sorbitol, Trehalose, Mannitol, Arabinitol, Glycerol, Raffinose,
P21 : Sugars in Solution
As P12 plus Cellobiose
P13 : Sugars and Oligosaccharides in Solution
As P21 plus Oligomeric Sugars
P22 : Organic Acids and Furans
Levulinic Acid, Formic Acid, Hydroxymethylfurfural, Furfural, Acetic Acid, gamma-Valerolactone,
P23 : Dimers and Trimers from Cellulose Hydrolysis
Cellobiose, Cellotriose,
P24 : Dimers and Trimers from Hemicellulose Hydrolysis
Xylobiose, Xylotriose, Arabinobiose, Arabinotriose,
P25 : Dimers and Trimers from Cellulose and Hemicellulose Hydrolysis
P29 : Oligomers from Starch Hydrolysis
Maltose, Maltotriose, Maltotetraose, Maltopentaose, Maltohexaose, Maltoheptaose, Maltooctaose,
P15 : Uronic Acids
Glucuronic Acid, Galacturonic Acid, Mannuronic Acid, Guluronic Acid, 4-O-Methyl-D-Glucuronic Acid, Iduronic Acid,
P75 : Seaweed Phytohormones
Gibberellic Acid, Indole-3-acetic acid, Indole-2-acetic acid, Indole-3-propionic acid, Indole-3-butyric acid, 6-Benzylaminopurine, Kinetin riboside, Abscisic acid, Salicylic acid,
P76 : Seaweed Vitamins (Fat-Soluble)
beta-Carotene, Ergocalciferol (Vitamin D2), Alpha-tocopherol (vitamin E), Phylloquinone (Vitamin K1),
P77 : Seaweed Vitamins (Water-Soluble)
Thiamine (Vitamin B1), Riboflavin (Vitamin B2), Niacin (Vitamin B3), Niacinamide (vitamin B3), Pantothenic Acid (Vitamin B5), Pyridoxine (Vitamin B6), Folate (Vitamin B9), Cobalamin (Vitamin B12), Ascorbic Acid (Vitamin C),
P78 : Seaweed Total Phenolics
P79 : Seaweed Phenolics Profiling
Gallic acid, Vanillic acid, Protocatechuic acid, Caffeic acid, Chlorogenic Acid, Ferulic acid, Coumaric acid, Catechin, Quercetin, Phloroglucinol,
P170 : Seaweed Total Tannins
P171 : Alginate Molecular Weight Analysis
P172 : Total Phlorotannins Estimation
P173 : Seaweed Bromoform Content
P271 : Aflatoxins
Aflatoxin B1, Aflatoxin B2, Aflatoxin G1, Aflatoxin G2,
P281 : Molecular Weight Analysis
P282 : Degree of Esterification
P283 : Degree of Acetylation
P284 : Chitin
P285 : Beta and Alpha Glucan

P71 : Seaweed Carbohydrates
Fucose, Mannitol, Glucose, Xylose, Mannose, Arabinose, Galactose, Rhamnose, Total Sugars, Glucuronic Acid, Galacturonic Acid, Mannuronic Acid, Guluronic Acid, Iduronic Acid,
P72 : Seaweed Amino Acids
Alanine, Arginine, Aspartic Acid, Cystine, Glutamic Acid, Glycine, Histidine, Isoleucine, Leucine, Lysine, Methionine, Phenylalanine, Proline, Serine, Threonine, Tyrosine, Valine,
P33 : Ultimate (Elemental) Analysis
Carbon, Hydrogen, Nitrogen, Sulphur, Oxygen, Ash,
P36 : Major Elements
Aluminium, Calcium, Iron, Magnesium, Phosphorus, Potassium, Silicon, Sodium, Titanium,
P38 : Major and Minor Elements
P73 : Seaweed Lipids as Fatty Acids
Arachidic Acid, Behenic Acid, Decanoic Acid, Erucic Acid, Lauric Acid, Linoleic Acid, Linolenic Acid, Myristic Acid, Caprylic Acid, Oleic Acid, Palmitic Acid, Palmitoleic Acid, Stearic Acid, Lignoceric Acid,
P74 : Pigments in Seaweed
Fucoxanthin, Astaxanthin, Chlorophyll-c, Chlorophyll-a, Chlorophyll-b, Lutein, beta-Carotene, Neoxanthin, Antheraxanthin, Violaxanthin,
P75 : Seaweed Phytohormones
Gibberellic Acid, Indole-3-acetic acid, Indole-2-acetic acid, Indole-3-propionic acid, Indole-3-butyric acid, 6-Benzylaminopurine, Kinetin riboside, Abscisic acid, Salicylic acid,
P76 : Seaweed Vitamins (Fat-Soluble)
beta-Carotene, Ergocalciferol (Vitamin D2), Alpha-tocopherol (vitamin E), Phylloquinone (Vitamin K1),
P77 : Seaweed Vitamins (Water-Soluble)
Thiamine (Vitamin B1), Riboflavin (Vitamin B2), Niacin (Vitamin B3), Niacinamide (vitamin B3), Pantothenic Acid (Vitamin B5), Pyridoxine (Vitamin B6), Folate (Vitamin B9), Cobalamin (Vitamin B12), Ascorbic Acid (Vitamin C),
P78 : Seaweed Total Phenolics
P79 : Seaweed Phenolics Profiling
Gallic acid, Vanillic acid, Protocatechuic acid, Caffeic acid, Chlorogenic Acid, Ferulic acid, Coumaric acid, Catechin, Quercetin, Phloroglucinol,
P170 : Seaweed Total Tannins
P171 : Alginate Molecular Weight Analysis
P172 : Total Phlorotannins Estimation
P173 : Seaweed Bromoform Content

P200 : Algae Carbohydrates
Total Sugars, Glucose, Xylose, Galactose, Arabinose, Mannose, Rhamnose,
P201 : Algal Lipids as Fatty Acids
Arachidic Acid, Behenic Acid, Decanoic Acid, Erucic Acid, Lauric Acid, Linoleic Acid, Linolenic Acid, Myristic Acid, Caprylic Acid, Oleic Acid, Palmitic Acid, Palmitoleic Acid, Stearic Acid, Lignoceric Acid,
P202 : Free Sterols in Microalgae
Cholesterol, Ergosterol, Stigmasterol,

P150 : Plant Pigments
Chlorophyll-a, Chlorophyll-b, Lutein, beta-Carotene, Neoxanthin, Astaxanthin, Zeaxanthin, Antheraxanthin, Violaxanthin,
P300 : Plant Cell Wall Analysis
As P10 plus Pectin, Starch, and Uronic Acids
P301 : Plant Micro and Macro Elements
P302 : Plant Vitamins (Water-Soluble)
Thiamine (Vitamin B1), Ascorbic Acid (Vitamin C), Pyridoxine (Vitamin B6), Niacin (Vitamin B3), Pantothenic Acid (Vitamin B5), Cobalamin (Vitamin B12), Folate (Vitamin B9), Riboflavin (Vitamin B2),
P303 : Plant Vitamins (Fat-Soluble)
Retinol (Vitamin A), Retinol Acetate (Vitamin A Acetate), Cholecalciferol (Vitamin D3), Ergocalciferol (Vitamin D2), Tocopheryl Acetate (Vitamin E Acetate), Phylloquinone (Vitamin K1), beta-Carotene,

P80 : Biomass Content
P81 : Biomethane Potential - 14 Days
Biomethane Potential (BMP), Total Biogas Volume, Total Solids, Volatile Solids, pH, Biogas Methane Content, Biogas Carbon Dioxide Content, Biogas Oxygen Content, Biogas Hydrogen Sulphide Content, Biogas Ammonia Content,
P82 : Biomethane Potential - 14 Days - Deluxe Package
Includes P81, P93, and P94
P84 : Biomethane Potential - 21 Days
As P81 but for 21 days
P85 : Biomethane Potential - 21 Days - Deluxe Package
Includes P84, P93, and P94
P87 : Biomethane Potential - 28 Days
As P81 but for 28 days
P88 : Biomethane Potential - 28 Days - Deluxe Package
Includes P87, P93, and P94
P90 : Biomethane Potential - 40 Days
As P81 but for 40 days
P91 : Biomethane Potential - 40 Days - Deluxe Package
Includes P90, P93, and P94
P93 : Feedstock Chemical and Biological Analysis
Total Solids, Volatile Solids, pH, Chemical Oxygen Demand (COD), Biological Oxygen Demand (BOD), Phosphorus, Potassium, Ammonia, Carbon, Hydrogen, Nitrogen, Sulphur,
P94 : Digestate Chemical and Biological Analysis
As P93 but on the digestate
P95 : Residual Biogas Potential - 14 Days
Residual Biogas Potential (RBP), Total Biogas Volume, Total Solids, Volatile Solids, pH, Biogas Methane Content, Biogas Carbon Dioxide Content, Biogas Oxygen Content, Biogas Hydrogen Sulphide Content, Biogas Ammonia Content,
P96 : Residual Biogas Potential - 14 Days - Deluxe Package
Includes P93 and P95
P98 : Residual Biogas Potential - 21 Days
As P95 but for 21 days
P99 : Residual Biogas Potential - 21 Days - Deluxe Package
Includes P93 and P98
P101 : Residual Biogas Potential - 28 Days
As P98 but for 28 days
P220 : Chemical Oxygen Demand (COD)
P221 : Biological Oxygen Demand (BOD)
P222 : Volatile Fatty Acids (VFAs) Speciation
Acetic Acid, Lactic Acid, Propionic Acid, Butyric Acid, Isobutyric Acid, Valeric Acid, Isovaleric Acid,
P223 : Carbon Dioxide Evolution Rate
P224 : Specific Oxygen Uptake Rate
P225 : Digestate Impurity Content
Glass & Metals & Plastics Over 2mm, Gravel & Stones Over 5mm, Sharps Over 2mm,
P226 : Ammoniacal Nitrogen
P227 : Nitrates
P228 : Viable Weed Seeds
P229 : Organic Matter
P240 : Specific Hydrolytic Potential (SHP)
P241 : Specific Acidogenic Potential (SAP)
P242 : Specific Methanogenic Potential (SMP)
P243 : SHP; SAP; and SMP
P244 : FOS/TAC and Alkalinity
P245 : Sludge Granule Size Analysis
P246 : Sludge Activity Test
P247 : Anaerobic Toxicity Assay
P250 : Continuous Anaerobic Digestion

P61 : Sugars in Bio-Oil Water Extract
Levoglucosan, Cellobiosan, Mannosan, Galactosan, Glucose, Xylose, Mannose, Arabinose, Galactose, Rhamnose, Fucose, Sucrose, Cellobiose, Total Sugars,
P62 : Sugars and Oligosaccharides in Bio-oil Water Extract
As P61 plus Oligomeric Sugars
P63 : Semi-Volatile Oxygenated Components in Bio-Oil
31 constituents including Phenol, Furfural, Syringol, and Vanillin

P350 : Biochar Production
At various temperatures and residence times

P51 : Particle Size
P53 : Bulk Density
P360 : Specific Surface Area (5-Point BET)
Specific Surface Area (Nitrogen Gas Adsorption), BET Isotherm (5 Point Using Nitrogen),
P364 : Pore-Size Distribution
Specific Surface Area (Nitrogen Gas Adsorption), BET Isotherm (20 Point Using Nitrogen), Pore Volume (Using Nitrogen), Pore Size Distribution (Using Nitrogen), Average Pore Width (Using Nitrogen),
P366 : Pore Size Distribution Deluxe
Specific Surface Area (Nitrogen Gas Adsorption), BET Isotherm (40 Point Using Nitrogen), Pore Volume (Using Nitrogen), Pore Size Distribution (Using Nitrogen), Average Pore Width (Using Nitrogen),
P368 : Pore Size Distribution Ultimate
Using nitrogen and carbon dioxide
P390 : Biochar Physical Properties Deluxe
Particle Size, Bulk Density, Specific Surface Area (Nitrogen Gas Adsorption), BET Isotherm (40 Point Using Nitrogen), Pore Volume (Using Nitrogen), Pore Size Distribution (Using Nitrogen), Average Pore Width (Using Nitrogen),
P391 : Biochar Physical Properties Ultimate

P2 : Moisture Content
P33 : Ultimate (Elemental) Analysis
Carbon, Hydrogen, Nitrogen, Sulphur, Oxygen, Ash,
P34 : Calorific Value and Elements
Gross Calorific Value, Net Calorific Value, Ash, Carbon, Hydrogen, Nitrogen, Sulphur, Oxygen,
P36 : Major Elements
Aluminium, Calcium, Iron, Magnesium, Phosphorus, Potassium, Silicon, Sodium, Titanium,
P37 : Minor Elements
Antimony, Arsenic, Cadmium, Chromium, Cobalt, Copper, Lead, Manganese, Mercury, Molybdenum, Nickel, Vanadium, Zinc,
P38 : Major and Minor Elements
P42 : Ash Melting Behaviour (Reducing Conditions)
Ash Shrinkage Starting Temperature (Reducing), Ash Deformation Temperature (Reducing), Ash Hemisphere Temperature (Reducing), Ash Flow Temperature (Reducing),
P370 : Inherent Moisture
P371 : Ash Content (815C)
P372 : Inorganic Carbon
P373 : Thermogravimetric Analysis (TGA) - Under Nitrogen
P374 : Thermogravimetric Analysis (TGA) - Under Air
P393 : Biochar Thermal Properties Deluxe
Moisture, Ash Content (815C), Carbon, Hydrogen, Nitrogen, Sulphur, Oxygen, Chlorine, Volatile Matter, Fixed Carbon, Aluminium, Calcium, Iron, Magnesium, Phosphorus, Potassium, Silicon, Sodium, Titanium, Gross Calorific Value, Net Calorific Value, Ash Shrinkage Starting Temperature (Reducing), Ash Deformation Temperature (Reducing), Ash Hemisphere Temperature (Reducing), Ash Flow Temperature (Reducing),
P394 : Biochar Thermal Properties Ultimate
As P393 plus inorganic carbon, organic carbon, TGA (under nitrogen and air), and inherent moisture

P36 : Major Elements
Aluminium, Calcium, Iron, Magnesium, Phosphorus, Potassium, Silicon, Sodium, Titanium,
P37 : Minor Elements
Antimony, Arsenic, Cadmium, Chromium, Cobalt, Copper, Lead, Manganese, Mercury, Molybdenum, Nickel, Vanadium, Zinc,
P38 : Major and Minor Elements
P381 : Electrical Conductivity
P382 : Water Holding Capacity
P383 : Cation Exchange Capacity
P384 : Biochar Polycyclic Aromatic Hydrocarbons (PAH)
Acenaphthene, Acenaphthylene, Anthracene, Benz[a]anthracene, Benzo[b]fluoranthene, Benzo[k]fluoranthene, Benzo[ghi]perylene, Benzo[a]pyrene, Chrysene, Dibenz[a,h]anthracene, Fluoranthene, Fluorene, Indeno[1,2,3-cd]pyrene, 1-Methylnaphthalene, 2-Methylnaphthalene, Naphthalene, Phenanthrene, Pyrene,
P385 : Liming
P386 : Germination Inhibition
P387 : Scanning Electron Microscopy (SEM)
P388 : Biochar Plant Growth Trials
Time to Germination, Mean Shoot Length (Week 1), Mean Shoot Length (Week 2), Mean Shoot Length (Week 3), Mean Shoot Length (Week 4), Shoot Weight (Week 4), Mean Root Length (Week 4), Root Weight (Week 4),
P396 : Biochar Soil Amendment Deluxe
Includes P381, P382, P384, P385 and P386
P397 : Biochar Soil Amendment Ultimate
As Deluxe package plus P383, SEM Imaging (P387) and Plant Growth Trials (P388)

P399 : Biochar Complete Evaluation Package
Includes everything from P391 (Physical Properties Ultimate), P394 (Thermal Properties Ultimate), and P397 (Soil Amendment Ultimate)

P2 : Moisture Content
P3 : Ash Content
P80 : Biomass Content
P31 : Volatile Matter
P32 : Proximate Analysis
Moisture, Ash, Volatile Matter, Fixed Carbon,
P33 : Ultimate (Elemental) Analysis
Carbon, Hydrogen, Nitrogen, Sulphur, Oxygen, Ash,
P34 : Calorific Value and Elements
Gross Calorific Value, Net Calorific Value, Ash, Carbon, Hydrogen, Nitrogen, Sulphur, Oxygen,
P35 : Chlorine and Sulphur
Chlorine, Sulphur,
P36 : Major Elements
Aluminium, Calcium, Iron, Magnesium, Phosphorus, Potassium, Silicon, Sodium, Titanium,
P37 : Minor Elements
Antimony, Arsenic, Cadmium, Chromium, Cobalt, Copper, Lead, Manganese, Mercury, Molybdenum, Nickel, Vanadium, Zinc,
P38 : Major and Minor Elements
P40 : Combustion Package
Volatile Matter, Fixed Carbon, Moisture, Ash, Carbon, Hydrogen, Nitrogen, Sulphur, Oxygen, Gross Calorific Value, Net Calorific Value, Chlorine,
P41 : Ash Melting Behaviour (Oxidising Conditions)
Ash Shrinkage Starting Temperature (Oxidising), Ash Deformation Temperature (Oxidising), Ash Hemisphere Temperature (Oxidising), Ash Flow Temperature (Oxidising),
P42 : Ash Melting Behaviour (Reducing Conditions)
Ash Shrinkage Starting Temperature (Reducing), Ash Deformation Temperature (Reducing), Ash Hemisphere Temperature (Reducing), Ash Flow Temperature (Reducing),
P50 : Ultimate Combustion Package
Includes P36, P40 and P42
P373 : Thermogravimetric Analysis (TGA) - Under Nitrogen
P374 : Thermogravimetric Analysis (TGA) - Under Air

P51 : Particle Size
P52 : Pellet Length and Diameter
P53 : Bulk Density
P54 : Basic Density

P150 : Plant Pigments
Chlorophyll-a, Chlorophyll-b, Lutein, beta-Carotene, Neoxanthin, Astaxanthin, Zeaxanthin, Antheraxanthin, Violaxanthin,
P155 : Polyamines
Dopamine, Histamine, Serotonin, Phenylethylamine, Putrescine, Cadaverine, Norspermidine, Spermidine, Spermine, Tyramine, Agmatine,
P160 : Polyphenols
Chlorogenic Acid, Caffeic Acid, Rutin, Scopoletin, Scopolin,
P165 : Terpenes
a-Pinene, b-Pinene, beta-Myrcene, Limonene, Linalool, a-Terpineol, beta-Caryophyllene, alpha-Humulene,

P281 : Molecular Weight Analysis
P282 : Degree of Esterification
P283 : Degree of Acetylation
P284 : Chitin
P285 : Beta and Alpha Glucan

P210 : Crude Fibre

P271 : Aflatoxins
Aflatoxin B1, Aflatoxin B2, Aflatoxin G1, Aflatoxin G2,

P251 : Apiose
P252 : Xylulose
P253 : Xylonic Acid

Contact us to know more about this analysis.

Contact us to know more about this analysis.

News
Jan 24th 2024
€1.5m Funding Success in CBE-JU
Celignis is a Partner in 3 Successful Proposals for EU Funding

We are pleased to announce that three of the proposals involving Celignis, submitted to the CBE-JU programme for funding collaborative biomass research in Europe, were successful. These projects will provide an additional funding of €1.5m to Celignis and build on our achievements in other CBE and EU projects. In particular, the projects are all at enhanced TRLs (6/7) and will use our existing Celignis Bioprocess infrastructure and will also fund further development of our bioprocessing capacities and the Bioprocess Development Services we offer our clients.

Details on the funded projects are provided below:

BIONEER - This project was funded under CBE-JU topic IA-06 and focuses on the TRL 6/7 production of biobased platform chemicals. Celignis's activities in the project focus on scaling up the work undertaken in our ongoing

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Jan 23rd 2024
Celignis to Exhibit and Present at Major Biochar Event
The 2024 North American Biochar Conference will take place in Sacramento, California, on Feb 12-15

On Feb 12-15 we'll be exhibiting at the 2024 North American Biochar Conference, taking place at the SAFE Credit Union Convention Centre in Sacramento, California.

We're looking forward to interacting with the 1000+ expected attendees, outlining our extensive range of analytical and application testing services for biochar.

Celignis CIO Lalitha Gottumukkala will also be a member of the expert panel focused on developing improved laboratory methods for biochar characterisation.

Click here to register for the event.

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Jan 22nd 2024
Celignis Attending BIC Event on Feb 8
This Networking Event Will Involve Discussions on Collaborations for Proposals to the 2024 CBE-JU Topics

The Circular Bioeconomy Europe Joint Undertaking (CBE-JU) is an organisation that funds biomass research in Europe at various Technology Readiness Levels (TRLs). Since 2016 Celignis has been an active participant in a number of projects funded by the CBE-JU.

The Biobased Industries Consortium (BIC) is the steering committee that helps to steer the focus of research for the CBE-JU programme. In 2023 Celignis joined the BIC as a Full Industry Member and participated in several proposals submitted for different research topics in the CBE-JU's 2023 Work Programme.

On Feb 8th Celignis's Dan Hayes, Lalitha Gottumukkala, and Oscar Bedzo will be attending a BIC networking event in Brussels where we will discuss potential collaborations in the research programme topics recently announced for 2024.

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Jan 19th 2024
We're Hiring - Business Administration & Client Relationship Manager
This position will involve working closely with senior management, fostering existing and new client relationships.

Situated in Limerick, Ireland, Celignis currently operates at two centres, Celignis Analytical and Celignis Bioprocess, actively engaging in a variety of private and public bioeconomy projects. As we continue to expand, we're looking to strengthen our team of 14 with a Business Administration and Client Relationship Manager who can bring a blend of enthusiasm and expertise.

This position will involve working closely with senior management, fostering existing and new client relationships, and ensuring successful delivery of our services, playing a key role in our ongoing growth and success.

Click here for more details about the position.

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Apr 30th 2023
Celignis to Sponsor and Present at Major Biochar Event
The event takes place on May 3rd at Carrick-on-Shannon

We are pleased to announce that, on May 3rd, Celignis will be presenting and exhibiting at the National Biochar and Carbon Products Conference 2023, which is taking place in Carrick-on-Shannon in County Leitrm, Ireland.

This conference is being organised under the auspices of the Interreg Northwest Europe-funded THREE C Project, entitled 'Creating and sustaining Charcoal value chains to promote a Circular Carbon economy in NWE Europe'.

The conference will highlight both Irish stakeholders who are currently working in the biochar and carbon products sector, but also partners from the THREE C project (covering Netherlands, Luxembourg, Germany, Belgium, France and Wales, as well as Ireland) who have interesting stories and products to share.

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