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Processing and Storage Effects on Berry Bioactives

Explore the impact of processing and storage on the phytochemical content of berries and their potential health benefits. Learn about the factors that influence the stability of phytonutrients, such as temperature, light, oxygen, water, and biochemical factors. Discover the consequences of cell disruption and food matrix interactions. Case studies on blueberry preservation and retention of polyphenolics are also included.

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Processing and Storage Effects on Berry Bioactives

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  1. Processing and Storage Effects on Berry Bioactives Luke R. Howard, Ph.D .

  2. Phytonutrient/Phytochemical Components in a plant based diet other than traditional nutrients that can reduce the risk of degenerative diseases

  3. Berries and Health Promotion Prevention of Chronic Diseases CHD & stroke Cancer Neurological disorders Obesity Type II diabetes Mechanisms Antioxidant Anti-inflammatory Cell signaling Gene regulation Apoptosis Modulation of enzymes

  4. Free Radicals

  5. Antioxidants

  6. Fruit and Vegetable Phytochemicals • Fruit and vegetable phytochemicals play an important role in health-promotion • Due to limited shelf-life and seasonal availability, fruits and vegetables are commonly consumed in various processed forms • How does processing impact phytochemical content?

  7. Flavonoids

  8. Procyanidins Epicatechin Procyanidin B2

  9. Anthocyanin-Procyanidin Polymers a.k.aPolymeric Pigments

  10. The Problem • Phytochemicals losses are inevitable during fruit and vegetable processing • Losses are due a number of processing, biochemical, and food matrix factors • Losses can also occur during storage of processed products

  11. Processing Factors Influencing the Stability of Phytonutrients • Temperature (blanching and pasteurization) • Light • Oxygen • Water (washing, soaking, canning) • Physical removal of tissues

  12. Thermal Degradation of Anthocyanins

  13. Strawberry Puree Stored One Month at 25oC

  14. Biochemical Factors Influencing the Stability of Phytonutrients • Co-factors • Metals • Enzymes • pH • Ascorbic acid

  15. Consequences of Cell Disruption PPO O2 PPO/POD POD + o-diphenols quinones ACY Phenolics Organic acids Sugars ascorbic acid degradation products ACY tannins + ACY mediators? polymers O2 tannins polymers ACY tannins ACY

  16. pH Effect on Anthocyanin Structure

  17. Food Matrix Factors Influencing the Stability of Phytonutrients • Chemical structure/solubility • Tissue localization: Free vs. bound • Interactions among compounds

  18. Light Microscopy of Cranberry Pomace Differential interference contrast (DIC) microscopy image of residue remaining after ground cranberry pomace was extracted with acetone:water:acetic acid (70:29.5:0.5) and stained with dimethylaminocinnamaldehyde (DMAC) at 20x magnification Differential interference contrast (DIC) microscopy image of residue remaining after ground cranberry pomace was treated with 2 N NaOH at 60 °C for 15 m and stained with dimethylaminocinnamaldehyde (DMAC) at 20x magnification

  19. Procyanidin Oligomer (DP1 – DP6) Composition of Cranberry Pomace Before and After Treatment with Sodium Hydroxide

  20. Properties of Phytonutrients in Plant Tissues

  21. Changes in Antioxidant Activity as Affected by Heating Nicoli et al. (1999) Trends Food Sci. Tech. 10:94-100

  22. Food Matrix Interactions – Anthocyanin Co-pigmentation Intermolecular copigmentation Self-association Metal complexation Intramolecular copigmentation Aglycone Sugar Copigment Acid

  23. Food Matrix Interactions – Binding of Procyanidins to Cell Wall Polysaccharides Le Bourvellec et al. (2009) Carbohydrate Polymers 75:251-261

  24. Food Matrix Interactions – Binding of Procyanidins to Proteins Haslam (1998) Practical Polyphenolics: From structure to molecular recognition and physiological action. Cambridge University Press

  25. Case Study: Processing Effects on Blueberry Polyphenolics

  26. Case Study I Objectives • To determine how different preservation methods (canning, pureeing, juicing) affect the retention of blueberry polyphenolics and antioxidant capacity • To determine how storage of processed products affects the retention of blueberry polyphenolics and antioxidant capacity

  27. Fresh Blueberries (cv. Bluecrop) Analysis of Fresh Berries Frozen Berries Individually Quick Frozen (IQF) Baking Juice Puree Canning Canned (Syrup) Canned (Water) Non-Clarified Clarified Pie-Canned in Water Pie-Frozen Berries Sampling: 1 d, 1 mo, 3 mo, 6 mo

  28. Juice Processing Steps

  29. Chemical Analysis • Polyphenolics (anthocyanins, procyanidins, chlorogenic acid, flavonols) measured by HPLC • Antioxidant capacity: ORACFL assay • Polymeric color: Colorimetric assay, measures the amount of anthocyanin polymers

  30. Polymeric Color Assay

  31. Total Anthocyanin Retention and Polymeric Color in Blueberry Juices % Retention % Polymeric color

  32. Total Anthocyanin Retention and Polymeric Color in Canned Blueberries % Retention % Polymeric color

  33. Total Anthocyanin Retention in Blueberries Canned in Syrup % Retention

  34. Total Anthocyanin Retention and Polymeric Color in Blueberry Puree % Retention % Polymeric Color

  35. Total Flavonol Retention in Blueberry Juices % Retention

  36. Total Flavonol Retention in Blueberries Canned in Syrup % Retention

  37. Total Flavonol Retention in Blueberry Puree % Retention

  38. Total Procyanidin Retention in Blueberry Juices % Retention

  39. Total Procyanidin Retention in Blueberries Canned in Syrup % Retention

  40. Total Procyanidin Retention in Blueberry Puree % Retention

  41. Chlorogenic Acid Retention in Blueberry Juices % Retention

  42. Chlorogenic Acid Retention in Blueberries Canned in Syrup % Retention

  43. Chlorogenic Acid Retention in Blueberry Puree % Retention

  44. ORACFL Retention in Blueberry Juices % Retention

  45. ORACFL Retention in Canned Blueberries % Retention

  46. ORACFL Retention in Blueberry Puree % Retention

  47. Dietary polyphenols Tissue metabolites Tissues Small intestine Liver bile Kidney Colon Urine Microbial metabolites Feces

  48. Discussion • Which processing, biochemical, and food matrix factors most likely played a role in polyphenolic losses during processing and storage of blueberry products? • Why does the antioxidant capacity of stored products change little during storage despite losses of anthocyanins and procyanidins?

  49. Discussion Continued • What steps can processors take to minimize phytonutrient losses during processing and storage? • What steps can consumers take to minimize phytonutrient losses following purchase of processed berry products? • Would you expect processed berry products to have the same health benefits as fresh berries?

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