Advanced encapsulation technology for sustainable detergency (CAP-IT)
An EU FP7 Funded Project - 2010 - 2014
Partners: Procter & Gamble Eurocor N V, Belgium; Procter & Gamble Technical Centres Limited, United Kingdom; Consorzio Interuniversitario Per Lo Sviluppo Dei Sistemi A Grande Interfase, Italy; Universitat Rovira I Virgili, Spain; The University of Birmingham, United Kingdom; Granutec Granulaton GMBH, Germany

The CAP-IT! project aimed for developing a deep mechanistic understanding of coating and encapsulation processes to stabilise actives in fluid compacted consumer goods. Six partners from two companies, three universities, and five European countries have exchanged knowledge and personnel to achieve breakthroughs in the field of sustainable detergency. The research programme involved screening and proof of concept of active wall materials combinations, process development for particle production, characterisation of particles, and creating an overall holistic model. Innovative aspects of the project include using microfluidic devices, new high throughput screening approaches, new materials to allow the encapsulation of actives for fluid matrices, and novel modelling techniques.

POSTER 1: CAP-IT! Advanced encapsulation technology for sustainable detergency
The CAP-IT Project Team

POSTER 2: inprotec AG: Contract Manufacturing
Jessica Banidol and Olga Iwanow - inprotec AG, Germany

POSTER 3: Coating of Actives: From coating-centered to actives-centered processes
Jessica Banidol, Olga Iwanow - inprotec AG, Zhibing Zhang - University of Birmingham and Antonio Quintieri - Procter & Gamble

POSTER 4: Microcapsules for confining fluids: prediction of shell stability from advanced SAXS investigations
Moira Ambrosi, Emiliano Fratini, Piero Baglioni - Department of Chemistry & CSGI - University of Florence, Susana Fernández Prieto and Johan Smets - Procter & Gamble Services NV/SA

POSTER 5: Microencapsulation: how to select your materials for a successful core-shell encapsulation
Alberto V. Puga, Albert Gasull Morales and Ricard Garcia Valls - METEOR group - Chemistry Technology Centre of Catalonia (CTQC), Mario Benassi Neto, Raúl Rodrigo Gómez, Susana Fernández Prieto and Johan Smets - Brussels Innovation Center - Procter and Gamble

POSTER 6: Modelling tools for microencapsulation
Diego G. Oliva,  Albert Gasull Morales and Laureano Jimenez Esteller - Departament d'Enginyeria Química - Escola Tècnica Superior d’Enginyeria Química - Universitat Rovira i Virgili, Raúl Rodrigo Gómez, Susana Fernández Prieto, Johan Smets - Procter & Gamble Services NV/SA, David Smith - Newcastle Innovation Center, Procter and Gamble

POSTER 7: Microencapsulation of water soluble particles using wet chemistry
Sorin Sauca and Zhibing Zhang - University of Birmingham, Susana Fernandez Prieto and Johan Smets - Procter & Gamble Services NV/SA

POSTER 1: CAP-IT! Advanced encapsulation technology for sustainable detergency

Carlos Amador⁶, Moira Ambrosi³, Piero Baglioni³, Jessica Banidol⁴, Mario Benassi¹, Walter Broeckx¹, Vivek Davda², Susana Fernández Prieto¹, Emiliano Fratini³, Diego Gabriel Oliva⁵, Ricard Garcia Valls⁵, Albert Gasull Morales⁵, Olga Iwanow⁴, Laureano Jiménez Esteller⁵, Norbert Lambert⁴, Jennifer Efua Kwansima Quansah³, Antonio Quintieri¹, Xuemiao Pam², Raúl Rodrigo Gómez¹, Sorin Sauca², Pierre Schwerdtfeger⁴, Alberto Simoncelli¹, Johan Smets¹, David Smith⁶, Alberto V. Puga⁵, Chiara Vannucci³, Dave York⁶, and Zhibing Zhang²

¹ Procter & Gamble, Temselaan 100, 1853 Strombeek-Bever, Belgium &

² School of Chemical Engineering, University of Birmingham, Edgbaston, Birmingham B15 2TT, UK

³Department of Chemistry & CSGI, University of Florence, Via della Lastruccia 3, 50019 Sesto Fiorentino, Florence, Italy.

⁴ inprotec AG, Germany

⁵Departament d'Enginyeria Química, Escola Tècnica Superior d’Enginyeria Química, Universitat Rovira i Virgili, Av. Països Catalans, 26, 43007, Tarragona, Spain

⁶Newcastle Innovation Center, Procter and Gamble, Whitley Road, Longbenton, Newcastle-upon-Tyne, NE12 9TS, UK

Abstract:

CAP-IT! is a team formed by academic and industrial partners which has taken the challenge of developing advanced encapsulation technologies for sustainable detergency. The CAP-IT! project aimed to develop a deep mechanistic understanding of coating and encapsulation processes to stabilise actives in fluid compacted consumer goods in order to enable compaction and, therefore, reduction in transport of detergency materials, thus fewer CO₂ emissions; reduction in packaging material; energy reduction, meaning more active chemistries will allow for the use of lower temperature cycles; and water reduction whereby more active chemistries will allow for shorter washing cycles. In addition, it set out to overcome the disadvantages of traditional encapsulation processes, such as: universal techniques for a broad set of actives with diverse properties, different release profiles required for the same application, interactions of active materials and wall chemistries and the requirement of perfect capsule.

POSTER 2: inprotec AG: Contract Manufacturing

Jessica Banidol and Olga Iwanow

inprotec AG, Germany

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Abstract:

inprotec AG is a contract manufacturer in the field of fluidized bed technology and classical spray drying. Fluidised-bed and spray-drying technologies are the foundations of inprotec services.

Today fluidised-bed technology is a thermal drying technology that complements classical spray drying in several industrial sectors. These two technologies serve as the basis for our versatile contract services.

The basic principle of the technology is that a fluid medium flows through a container filled with solid particles. The flow causes the solid particles to mix with the flowing medium and become fluidised. The result is a free-flowing, loosened mass of fine-grained particles. The main feature of a fluidised bed is that it provides continuous drying, so that a defined residual moisture can be achieved. Further advantages are excellent heat and mass transfer, and the elimination of the risk of overheating.

Fluidised bed technology can be employed for various processes intended to modify the physical properties of the substances being treated. The excellent drying characteristics of this technology smooth the path for the development of further processes, such as agglomeration, coating and spray granulation.

POSTER 3: Coating of Actives: From coating-centered to actives-centered processes

Jessica Banidol¹, Olga Iwanow¹, Zhibing Zhang² and Antonio Quintieri³

¹inprotec AG, Germany; ²University of Birmingham, UK; ³Procter & Gamble, Belgium

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Abstract:

This paper will present an amazing journey from ‘What is Coating’ to ‘Why do we need Coating’, highlight the importance of understanding the characteristics of the core materials, coating materials, and customer needs, and describe how coating materials should be customised to fit the characteristics of active ingredients, the application and processes, including critical process variables and their impact on controlled and sustained release of the active ingredients.

POSTER 4: Microcapsules for confining fluids: prediction of shell stability from advanced SAXS investigations.

Moira Ambrosi¹, Emiliano Fratini¹, Piero Baglioni¹, Susana Fernández Prieto² and Johan Smets²

¹Department of Chemistry & CSGI, University of Florence, Via della Lastruccia 3, 50019 Sesto Fiorentino, Florence, Italy.

² Procter & Gamble Services NV/SA, Temselaan 100, 1853 Strombeek-Bever, Belgium

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Abstract:

            Microencapsulation is a powerful technique to shield an active product from the surrounding environment. The functional ingredient is enclosed by a suitable barrier, which can either confine the active material within the capsule walls and that can regulate its release behaviour for example by triggering responsive shells. Polymeric microcapsules represent an effective tool to confine a broad range of materials for diverse applications. Capsule stability is certainly related to morphological characteristics. Small Angle X-ray Scattering (SAXS) is a suitable technique to investigate the structure of capsule shell at the nanometer scale. In fact, SAXS allows determining structure of materials whose dimension ranges between 1 to about 100 nm and the shell of polymeric microcapsules is generally in this dimension range. In the present study, SAXS was employed to disclose the wall nanostructure in order to quantitatively link capsules’ structural features to their leakage properties. Shell thickness and polydispersity were first determined. Afterwards, a model-independent parameter, the so-called “bump descriptor”, was defined to quantitatively estimate capsule stability, so attaining the aforementioned quantitative correlation. To the best of our knowledge, such quantitative correlation between leakage profiles and structural features has never been attempted before.

POSTER 5: Microencapsulation: how to select your materials for a successful core-shell encapsulation

Alberto V. Puga¹, Albert Gasull Morales^1,2, Mario Benassi Neto², Raúl Rodrigo Gómez², Susana Fernández Prieto², Johan Smets², Ricard Garcia Valls¹

1 METEOR group, Chemistry Technology Centre of Catalonia (CTQC), Marcel·lí Domingo, s/n, 43007 Tarragona, Spain

2 Brussels Innovation Center, Procter and Gamble, Temselaan 100, B-1853 Strombeek-Bever, Belgium

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Abstract:

The process of microencapsulation involves the coating of high-value substances in order to maximise their performance. Therefore, microcapsules have two main functions and that is 1) to protect the capsule loading from the environment and 2) deliver it at the intended timeframe. Hence, the selection of a suitable and high performing wall material is vital for the development of capsules. Nevertheless, the selection of wall material as capsule wall is of multi-vectorial challenge for an encapsulator. Once, the capsule wall material is selected, an encapsulation process has to be developed to produce a high performing and cost effective microcapsule. It has been proven that core-shell morphology is desirable since there is an optimization of the wall material surrounding the active substance, avoiding inappropriate release of the active. This communication encompasses a holistic approach for microencapsulation processes from the development of methodologies for the selection of wall materials to the manufacturing of core/shell morphologies with the selected wall materials.

POSTER 6: Modelling tools for microencapsulation

Diego G. Oliva¹, Albert Gasull Morales^1,2, Raúl Rodrigo Gómez², Susana Fernández Prieto², Johan Smets², David Smith³, Laureano Jimenez Esteller¹

¹Departament d'Enginyeria Química, Escola Tècnica Superior d’Enginyeria Química, Universitat Rovira i Virgili, Av. Països Catalans, 26, 43007, Tarragona, Spain

² Procter & Gamble Services NV/SA, Temselaan 100, 1853 Strombeek-Bever, Belgium

³Newcastle Innovation Center, Procter and Gamble, Whitley Road, Longbenton, Newcastle-upon-Tyne, NE12 9TS, UK

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Abstract:

Modelling has proved to be a vital instrument for the decision making process within the industrial sector. The models developed for microencapsulation may range from the economical assessment of a developing process technology to the environmental impact of a process modification. Thus, the right balance of modelling and experimental effort aids to speed up the learning curve of a developing process identifying its weaknesses as well as its optimised conditions for success. Thus, this communication is focused on the dissemination of modelling tools implemented to assist the assessment of the scale up of microencapsulation processes, in terms of operational parameters and cost effective solutions, and the understanding of the environmental impact of different substances and processes used to manufacture microcapsules.

POSTER 7: Microencapsulation of water soluble particles using wet chemistry

Sorin Sauca¹, Susana Fernandez Prieto², Johan Smets² and Zhibing Zhang^1*

¹ School of Chemical Engineering, University of Birmingham, Edgbaston, Birmingham B15 2TT

² Procter & Gamble Services NV/SA, Temselaan 100, 1853 Strombeek-Bever, Belgium

Abstract:

Peroxycarboxilic acid (PAP) in powder form as a model bleach was encapsulated using different formulation and processing conditions. The first example is based on emulsification of aqueous sodium alginate with PAP in mineral oil followed by gelation of sodium alginate with calcium chloride. The 2^nd example is encapsulation of PAP in silica resulting from emulsification of mineral oil with PAP in aqueous silica pre-condensate followed by reaction between the pre-condensate and hydrochloric acid.

It has been found that PAP encapsulated in calcium alginate showed a sustained release over a week in a commercial detergent, whist PAP in silica was stable for 1 month at 35°C in the detergent. The details of the formulation and processing conditions, and the properties of the formed microcapsules will be presented.