BIOGENIC AMINES PRODUCED - PowerPoint PPT Presentation

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BIOGENIC AMINES PRODUCED

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BIOGENIC AMINES PRODUCED BY MICROORGANISM Minggu-3 B.A. : Histamine, Tyrramine, Tryptamine, Cadavarine, Putrescine, 2-Phenyl-ethylamine, Spermidine, and Spemine ... – PowerPoint PPT presentation

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Title: BIOGENIC AMINES PRODUCED


1
  • BIOGENIC AMINES PRODUCED
  • BY MICROORGANISM

Minggu-3
2
  • B.A. Histamine, Tyrramine, Tryptamine,
    Cadavarine, Putrescine, 2-Phenyl-ethylamine,
    Spermidine, and Spemine
  • Health problem nervous, gastric and intestinal
    system, and blood presure.
  • Present in living organism
  • In Food, Mainly Produced by microbial
    decarboxyltion of amino acid.
  • Their physiological mecanism to get energy
  • Their precursors amino acid and M.O. have enzyme
    amino acid decarboxlases
  • B.A. were found cheese, fermented vegetables,
    meat, and fish products

3
  • Familia Enterobacteriaceae
  • Generlly high Decarboxylase Activity (D.A)
  • Citrobacter freundii and Proteus vulgaris, weaker
    D.A. species
  • Enterobacter cloacea and Serratia were high
    putrescine and cadaverine producers
  • E. cloacae, E. eogenes, Klesiella oxytoca and
    Morganella morganii were histamine producers
  • These M.O. are present in low number, but not
    correct storage of raw material and uncontrolled
    fermentation can induce to release their
    decrboxylase.

4
  • Lactic acid bacteria (LAB)
  • LAB are generally considered to be not
    toxinogenic or phatogenic
  • But some species can produce BA
  • Some strain Lactococcus and Leuconostoc are
    tyramine producers.
  • Lactobacilli L. buchneri, L. alimentarius, L.
    plantarum, L. curvatus, and so on were also
    tyramine producers
  • Carnobacterium was observed to produce tyramine
  • LAB are not produce histamine, diamine
    (putrescine and cadavarine)

5
  • Family Micrococcaceae
  • Histidine decarboxylase activity was observed in
    some species of genera Micrococcus and
    Straphylococcus.
  • S. xylosus and some strain Kocuria spp. are high
    histamine producer
  • S. cornosus and S. piscifermentans can produce
    Histamine, Cadavarine, Putrescine, and
    2-Phenyl-ethylamine.
  • Staphylococci (used as starter) are not produce
    histamin but weak tyramine

6
  • Other microorganism
  • Yeast, Debariomyces and Candida have high
    histidine decarboxylase activity than LAB and
    staphylococci
  • Some unidentified strain yeast were able produce
    2-Phenyl-ethylamine and tyramine.
  • Gram negative bacteria (pseudomonas) are strong
    producer BA

7
  • Proteolitic activity
  • Was done by microbial and endogenous enzymes
  • Proteolysis is favoured by the denturation of
    protein
  • Production of BA has often been related to the
    proteolytic activity of M.O.
  • However, no direct correlation has been found
    between proteoltic activity of S. xylosus and BA
    production
  • High temperature, pH and low salt can acelerate
    the amino acid accumulation and stimulate amine
    formation

8
  • Starter culture
  • LAB are widely used fermented food industry as
    starter culture.
  • Micrococci and/or coagulase-negative
    staphylococci, inoculated together with LAB,
    contribute to development flavour as a result of
    their proteolytic and lipolytic activities.
  • Produce catalase to protect rencidity and reduce
    netrates to nitrites, improving colour formation
    and stability
  • The starter organism Dont Form BA
  • Rapid pH decrease by starter can largerly prevent
    BA

9
  • Selected strain L. sakei can reduce BA
  • L. sakei CTC494 along with proteolytic S.
    cornosus and S. xylosus reduce total BA content
    80-90 with respect to fermented food without
    starter (Bover-Cid et al., 2001).
  • In contrast, the use single starter LAB
    Pediococcus cerevisiae and L. plantarum did not
    decrease BA (Rice and Koehler, 1976 Buncic et
    al., 1993)
  • Slight reduction of tyramine, cadaverine and
    putrescine was fermented sausages with starter M.
    carnosus plus L. plantarum and M. carnosus plus
    L. pentosaceus (Hernandez- et al., 1997).
  • BA controlling raw fish microbial quality,
    particularly amine positive bacteria.

10
  • Chemico-physical factor influencing BA production
  • pH
  • Key factor influencing the amino acid
    decarboxylase
  • Amine Formation was a physicological mechanism
    to counteract an acid environment (Koessler,
    1928)
  • Bacterial BA have acid pH optimum (Gale, 1946)
  • Corelation BA production and decrease pH,evidence
  • However, amin formation depended on growth of
    M.O., than growth condition (Yosinaga
    Frank,1986)
  • Acidification MRS broth by glucono-d-lactone
    decrease amine and cell count (Maijala et
    al.,1993)
  • Rapid sharp reduction pH is known to reduce
    growth of the amine-positive M.O.

11
  • Sodium chloride
  • Rate amine production L. bulgaricus was reduced
    when salt increased from 0-6 (Chander, 1989)
  • Henry Koehler (1986) demonstrate NaCl 3.5- 5.5
    could inhibit histamine production
  • Redox potential
  • Low redox potential influence to low BA
  • Aw has corilation with growth and BA
  • Temperature
  • Has marked effect formation BA in fishing
    industries an cheese.
  • Carnobacterium devergens produce more BA at 25oC
    than 15oC

12
  • High temp. (15oC) can favour proteolytic and
    decarboxylating reaction, increasing BA
  • Incontrast, low temp. (4oC), putrescine can be
    produced by psychrotrophic pseudomonas. However
    lower BA amount were detected in fermented
    sausage.
  • Additive
  • Sugar influence population dinamics,
    consequently, production BA, because can enhace
    growth starter culture.
  • Enterococci develop earlier if sugar not add

13
  • Bacterial amine oxidase (AO)
  • AO can oxidase several BA. BAs inactivated by AO
  • The potential role of MO involved in food
    fermenta-tions with AO activity has been
    inverstigated with aim to prevent or reduce the
    acumulation of BA
  • Leuschner et al.(1998) tested in vitro potential
    amine degradation by many MO isolated from
    f-food, genera Lactobacillus, Pediococcus,
    Micrococcus, S. carnosus and Brevibacterium
    linens.
  • AO have high activity in high temp.
  • Highest degradation rate amine waas observed at
    37oC.
  • S. xylosus S81 completely oxidised histamine.
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