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Radiation of Biopolymers Jaejoon Han

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Page 1: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Radiation of Biopolymers

Jaejoon Han

Page 2: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

INTRODUCTIONINTRODUCTION

Polymers are macromolecules composed of many small molecules added to each other to form linear, branched, or cross-linked structures.

Synthetic origin - Teflon™, nylon, polyvinylchloride, polystyrene, polyurethanes, etc.

Natural origin (biopolymers) – Protein, polysaccharides, polynucleotides, or

natural rubber.

Page 3: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Pollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment.

Biopolymers degrade rapidly in the biological medium via the enzymatic route.

Biopolymers from renewable sources (proteins, carbohydrates, etc.) have gained considerable research interests.- Used for food coating or stand-alone film wrap.- Retard unwanted mass transfer in food products.

Page 4: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Biopolymeric Protein FilmsBiopolymeric Protein Films

Positive: Excellent O2 and CO2 barriers.

Negative: (1) Highly hydrophilic and tend to absorb large quantities of water under elevated relative humidity conditions.

(2) Mechanical properties are weakened and their water vapor permeabilities are increased.

Page 5: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

To Extend Functional and Mechanical Properties of Protein Films

(1) Optimization of the interactions between polymers.

- protein–protein interactions.- charge–charge electrostatic complexes between proteins and polysaccharides.

(2) Formation of cross-links through physical, chemical, or enzymatic treatments.

Page 6: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Protein CrossProtein Cross--linkslinks

Confer elastomeric properties to the materials.

Improve the mechanical strength and water resistance of materials.

Page 7: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Protein CrossProtein Cross--linkslinks

Enzymes (e.g. transglutaminase) have been used to cross-link many food protein including caseins.

However, the use of enzymes is - High cost. - Application is limited on a large scale.

Physical treatment such as γ-irradiation improved the mechanical strength of biopolymeric films at much lower costs.

Page 8: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Radiation of BiopolymersRadiation of Biopolymers

γ-Irradiation can also affect proteins by causing conformational changes, formation of protein free radicals, and recombination/polymerization reactions (Urbain,1986).

γ-Irradiation has been reported to be useful in the cross-linking of proteins, which increase the tensile strength of the product (Ressouany et al., 1998).

Page 9: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Tyrosine-Tyrosine cross-links - Protein cross-linking by γ-irradiation - Improved the mechanical resistance, and water

resistance of the biopolymeric films.(Mezgheni et al., 1998: Ressouany et al., 1998)

Higher irradiation doses in combination with Ca2+

could further increase the mechanical strength of the protein films by forming a dense network.

(Brault et al. 1997)

Page 10: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Attempts have been made to establish the suitability of irradiation for the development of cross-linked protein solutions for edible or biodegradable packaging applications.

Furthermore, γ-irradiation generates sterile biomaterials which could be used in pharmaceutical or biomedical application.

Page 11: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

MATERIALS AND METHODSMATERIALS AND METHODS

Page 12: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Biopolymeric Film preparationBiopolymeric Film preparation

Different protein sources were used for the film formations.

Solutions were irradiated at several total doses from 4 to 128 kGy in a 60Co underwater calibrator unit (UC-15; 17.33 kGy/h).

Film forming solution ⇒ Cast onto Petri dishes ⇒Spread evenly ⇒ Dry in a climatic chamber ⇒ Peel dried films

Optichromic and Gammachrome dosimeters were used to validate the dose distribution throughout the samples.

Page 13: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Analysis & MeasurementsAnalysis & Measurements

Film thickness

Mechanical properties of films (Puncture tests)

Insoluble matter determination

Microstructure observationsFluorescence measurements for bityrosine formationPermeability measurement (Water vapor permeability)

Page 14: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

RESULTS AND DISCUSSIONRESULTS AND DISCUSSION

Page 15: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Mechanical properties of films Mechanical properties of films ((Puncture tests)Puncture tests)

Mechanical properties of cross-linked films improved significantly the puncture strength for all types of films.

(Lacroix et al., 2002)

Fig 1. Puncture strength of unirradiated and irradiated caseinate films.

Page 16: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Insoluble matter determinationInsoluble matter determination

The proportion of the insoluble fraction increased with the irradiation dose up to 32 kGy.

(Vachon et al., 2000)

Fig 2. Fraction of insoluble matter as a function of irradiated dose.

Page 17: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Microstructure ObservationsMicrostructure Observations

Observed by transmission electronic microscopy.Microstructures

- (a) slicker and porous- (b) Clearly more dense

(Vachon et al., 2000)

Fig 3. Cross sections of (a) unirradiated or (b) irradiated (32 kGy) calcium caseinate films

Page 18: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Microstructure ObservationsMicrostructure Observations

Cross-link, present in irradiated films, increased the molecular proximity of the protein chains.

Increased molecular proximity and additional molecular bonds directly influenced on Mechanical Strength and Water Resistance.

Page 19: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Fluorescence Measurements Fluorescence Measurements -- bityrosine formationbityrosine formation

Fig 4. Effect of CaCl2 and irradiation dose on bityrosine fluorescence.

Page 20: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Fluorescence MeasurementsFluorescence Measurements

• Bityrosine increased with irradiation dose, resulting in a higher number of cross-links between tyrosine units.

Ca2+ enhanced the formation of bityrosine.

CaCl2 - Indirect effect by forming salt bridges between adjacent protein molecules.

- Reduce the molecular distances, thus makethe formation of bityrosine easier.

(Ressouany et al., 1998)

Page 21: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Permeability measurement Permeability measurement ((Water vapor Permeability)Water vapor Permeability)

WVP = (WX) / AT (P1-P2)

W: weight gain (g)T : time (d)X : film thickness (mm) A : exposed area of the film (m2) P2-P1 : water vapor pressure differential across

the film.

Page 22: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

Permeability measurement Permeability measurement ((Water Vapor Permeability)Water Vapor Permeability)

• γ-Irradiation treatment reduced significantly (P<0.05) the WVP of various protein films.(Lacroix et al., 2002 and Ouattara et al., 2002)

• Resulted from the formation of high molecular weight proteins and extensive cross-linking.

Page 23: Radiation of Biopolymers · zPollution due to ‘plastics’ is a result of the slow rate of disappearance of the synthetic polymers from the environment. zBiopolymers degrade rapidly

CONCLUSIONCONCLUSION

γ-Irradiation is efficient for inducing cross-links in biopolymeric protein films.

γ-Irradiation can enhance physico-chemical properties of biopolymers.