Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation

Department of Veterinary and Animal Sciences

Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation

Research output: Contribution to journal › Journal article › Research › peer-review

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Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation. / Chatterton, Dereck E. W.; Aagaard, Sasha; Hesselballe Hansen, Tim; Nguyen, Duc Ninh; De Gobba, Cristian; Lametsch, René; Sangild, Per T.

In: Food & Function, Vol. 11, No. 3, 2020, p. 2309-2327.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Chatterton, DEW, Aagaard, S, Hesselballe Hansen, T, Nguyen, DN, De Gobba, C, Lametsch, R & Sangild, PT 2020, 'Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation', Food & Function, vol. 11, no. 3, pp. 2309-2327. https://doi.org/10.1039/c9fo02998b

APA

Chatterton, D. E. W., Aagaard, S., Hesselballe Hansen, T., Nguyen, D. N., De Gobba, C., Lametsch, R., & Sangild, P. T. (2020). Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation. Food & Function, 11(3), 2309-2327. https://doi.org/10.1039/c9fo02998b

Vancouver

Chatterton DEW, Aagaard S, Hesselballe Hansen T, Nguyen DN, De Gobba C, Lametsch R et al. Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation. Food & Function. 2020;11(3):2309-2327. https://doi.org/10.1039/c9fo02998b

Author

Chatterton, Dereck E. W. ; Aagaard, Sasha ; Hesselballe Hansen, Tim ; Nguyen, Duc Ninh ; De Gobba, Cristian ; Lametsch, René ; Sangild, Per T. / Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation. In: Food & Function. 2020 ; Vol. 11, No. 3. pp. 2309-2327.

Bibtex

@article{077276462ba041cab6c4d0978f523f6b,

title = "Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation",

abstract = "Bovine colostrum (BC) contains bioactive proteins, such as immunoglobulin G (IgG), lactoferrin (LF) and lactoperoxidase (LP). BC was subjected to low-temperature, long-time pasteurization (LTLT, 63 °C, 30 min) or high-temperature, short-time pasteurization (HTST, 72 °C, 15 s) and spray-drying (SD), with or without γ-irradiation (GI, ∼14 kGy) to remove microbial contamination. Relative to unpasteurized liquid BC, SD plus GI increased protein denaturation by 6 and 11%, respectively, increasing to 19 and 27% after LTLT and to 48% after HTST, with no further effects after GI (all P < 0.05). LTLT, without or with GI, resulted in 15 or 29% denaturation of IgG, compared with non-pasteurized BC, and 34 or 58% for HTST treatment (all P < 0.05, except LTLT without GI). For IgG, only GI, not SD or LTLT, increased denaturation (30-38%, P < 0.05) but HTST increased denaturation to 40%, with further increases after GI (60%, P < 0.05). LTLT and HTST reduced LP levels (56 and 81% respectively) and LTLT reduced LF levels (21%), especially together with GI (47%, P < 0.05). Denaturation of BSA, β-LgA, β-LgB and α-La were similar to IgG. Methionine, a protective amino acid against free oxygen radicals, was oxidised by LTLT + GI (P < 0.05) while LTLT and HTST had no effect. Many anti-inflammatory proteins, including serpin anti-proteinases were highly sensitive to HTST and GI but preserved after LTLT pasteurization. LTLT, followed by SD is an optimal processing technique preserving bioactive proteins when powdered BC is used as a diet supplement for sensitive patients.",

author = "Chatterton, {Dereck E. W.} and Sasha Aagaard and {Hesselballe Hansen}, Tim and Nguyen, {Duc Ninh} and {De Gobba}, Cristian and Ren{\'e} Lametsch and Sangild, {Per T.}",

year = "2020",

doi = "10.1039/c9fo02998b",

language = "English",

volume = "11",

pages = "2309--2327",

journal = "Food & Function",

issn = "2042-6496",

publisher = "Royal Society of Chemistry",

number = "3",

}

RIS

TY - JOUR

T1 - Bioactive proteins in bovine colostrum and effects of heating, drying and irradiation

AU - Chatterton, Dereck E. W.

AU - Aagaard, Sasha

AU - Hesselballe Hansen, Tim

AU - Nguyen, Duc Ninh

AU - De Gobba, Cristian

AU - Lametsch, René

AU - Sangild, Per T.

PY - 2020

Y1 - 2020

N2 - Bovine colostrum (BC) contains bioactive proteins, such as immunoglobulin G (IgG), lactoferrin (LF) and lactoperoxidase (LP). BC was subjected to low-temperature, long-time pasteurization (LTLT, 63 °C, 30 min) or high-temperature, short-time pasteurization (HTST, 72 °C, 15 s) and spray-drying (SD), with or without γ-irradiation (GI, ∼14 kGy) to remove microbial contamination. Relative to unpasteurized liquid BC, SD plus GI increased protein denaturation by 6 and 11%, respectively, increasing to 19 and 27% after LTLT and to 48% after HTST, with no further effects after GI (all P < 0.05). LTLT, without or with GI, resulted in 15 or 29% denaturation of IgG, compared with non-pasteurized BC, and 34 or 58% for HTST treatment (all P < 0.05, except LTLT without GI). For IgG, only GI, not SD or LTLT, increased denaturation (30-38%, P < 0.05) but HTST increased denaturation to 40%, with further increases after GI (60%, P < 0.05). LTLT and HTST reduced LP levels (56 and 81% respectively) and LTLT reduced LF levels (21%), especially together with GI (47%, P < 0.05). Denaturation of BSA, β-LgA, β-LgB and α-La were similar to IgG. Methionine, a protective amino acid against free oxygen radicals, was oxidised by LTLT + GI (P < 0.05) while LTLT and HTST had no effect. Many anti-inflammatory proteins, including serpin anti-proteinases were highly sensitive to HTST and GI but preserved after LTLT pasteurization. LTLT, followed by SD is an optimal processing technique preserving bioactive proteins when powdered BC is used as a diet supplement for sensitive patients.

AB - Bovine colostrum (BC) contains bioactive proteins, such as immunoglobulin G (IgG), lactoferrin (LF) and lactoperoxidase (LP). BC was subjected to low-temperature, long-time pasteurization (LTLT, 63 °C, 30 min) or high-temperature, short-time pasteurization (HTST, 72 °C, 15 s) and spray-drying (SD), with or without γ-irradiation (GI, ∼14 kGy) to remove microbial contamination. Relative to unpasteurized liquid BC, SD plus GI increased protein denaturation by 6 and 11%, respectively, increasing to 19 and 27% after LTLT and to 48% after HTST, with no further effects after GI (all P < 0.05). LTLT, without or with GI, resulted in 15 or 29% denaturation of IgG, compared with non-pasteurized BC, and 34 or 58% for HTST treatment (all P < 0.05, except LTLT without GI). For IgG, only GI, not SD or LTLT, increased denaturation (30-38%, P < 0.05) but HTST increased denaturation to 40%, with further increases after GI (60%, P < 0.05). LTLT and HTST reduced LP levels (56 and 81% respectively) and LTLT reduced LF levels (21%), especially together with GI (47%, P < 0.05). Denaturation of BSA, β-LgA, β-LgB and α-La were similar to IgG. Methionine, a protective amino acid against free oxygen radicals, was oxidised by LTLT + GI (P < 0.05) while LTLT and HTST had no effect. Many anti-inflammatory proteins, including serpin anti-proteinases were highly sensitive to HTST and GI but preserved after LTLT pasteurization. LTLT, followed by SD is an optimal processing technique preserving bioactive proteins when powdered BC is used as a diet supplement for sensitive patients.

U2 - 10.1039/c9fo02998b

DO - 10.1039/c9fo02998b

M3 - Journal article

C2 - 32108849

AN - SCOPUS:85082542701

VL - 11

SP - 2309

EP - 2327

JO - Food & Function

JF - Food & Function

SN - 2042-6496

IS - 3

ER -

ID: 240009493