Fermentation of spinach (Amaranthus sp) and Broccoli (Brassica oleracea) using Kombucha Culture has been shown to produce biomass that has the potential to become natural sources of folic acid. To produce the materials, following the fermentation, the biomass was filtered using membrane microfiltration (0.15 µm) at a pressure of 40 psia, at room temperature, yielding the concentrate and the permeate fractions. Following this step, freeze drying process was done on the biomass feeds, as well as on the concentrate and permeate fractions. For the freeze drying stage, the samples were frozen, and the condenser was kept at -50°C for 40 hours, while the pressure in the chamber was set at 200 Pa. Freeze drying results showed that the final products, have differences in compositions, as well as differences in the dominat monomers of folates. After water content was driven out, freeze drying increased the concentrations of folic acid in the dried products, and was found to be the highest in the concentrate fractions. Freeze drying has been shown to be capable of protecting the folates from heat and oxidative damages that typicaly occur with other types of drying. The final freeze dried concentrates of fermentation of spinach and broccoli were found to contain folic acid at 2531.88 µg/mL and 1626.94 µg/mL, total solids at 87.23% and 88.65 %, total sugar at 22.66 µg/mL and 25.13 µg/mL, total reducing sugar at 34.46 mg/mL and 15.22 mg/mL, as well as disolved protein concentrations at 0.93 mg/mL and 1.45 mg/mL. Liquid Chromatography Mass Spectometry (LC-MS) identification of the folates in the freeze dried concentrates of fermented spinach and broccoli was done using folic acid and glutamic acid standard solutions as the reference materials. The results showed the presence of folic acid and showed that the dominant monomers of molecules of folates with molecular weights of 441.44 Da. and 441.54 Da. for spinach and broccoli respectively. Moreover, the monomers of glutamic acid were also found at molecular weights of 147.21 Da. and 147.35 Da. for spinach and broccoli respectively. Thus, it has been shown that kombucha fermentation of spinach and broccoli, followed by membrane microfiltration and freeze drying process, could produce dried materials with high concentrations of folates that have the potential to be used as naturally derived sources of folic acid.

1.
J.F.
Cordero
,
A.
Do
and
J.
Berry
,
Food and Nutrition Bulletin
, Vol.
29
, No.
2
(Suplement),
2008
2.
V.
Gorelova
,
L.
Ambach
,
F.
Rebeille
,
C.
Stove
,
D
Van Der Straeten
,
Frontiers in Chemistry
, Vol.
5
, Article 21, March
2017
3.
A.
Susilowati
,
Aspiyanto
,
H.
Melanie
, “
Characterization on Concentrates and Powders of fermented Broccoli (Brassica oleracea L.) and Spinach (Amaranthus sp.) as Folic Acid Source for Smart Food Formula
”,
Sriwijaya International Conference on Engineering, Science and Technology 2016 (SICEST 2016) Conference Proceedings
, edited by
I.
Iskandar
,
2016
, pp.
22
27
4.
Aspiyanto
,
A.
Susilowati
,
J.M.
Iskandar
,
J.M.
Iskandar
,
H.
Melanie
,
Y.
Maryati
,
P.D.
Lotulung
, “
Characteristic of fermented spinach (Amaranthus spp.) polyphenol by kombucha culture for antioxidant compound
International Symposium on Applied Chemistry (ISAC) 2016 Conference Proceedings
,
2016
5.
V.
De Crécy-Lagard
.,
B.
El Yacoubi
,
R.D.
de la Garza
,
A.
Noiriel
, and
A.D.
Hanson
.
Comparative genomics of bacterial and plant folate synthesis and salvage : predictions and validations
,
BMC Genomics.
8
:
245
,
2007
,.
6.
Hauser
,
P. M.
and
Macreadie
,
I. G.
“Isolation of the Pneumonic carinii dihydrofolate gene and functional compllementation in Saccharomyces cerevisiae:,
Federation of European Microbiological Societies Lett
256
,
Published by Blackwell Publishing Ltd.
,
2006
, pp.
244
250
.
7.
C.
Dufresne
, and
E.
Farnworth
,
Food Research International
, Vol.
33
(
6
),
2000
, pp.
409
421
.
8.
R.
Malbasa
,
E.
Loncar
,
M.
Djuric
,
Food Chemistry
, Vol.
106
,
2008
, pp.
1039
1045
.
9.
M.H.V.
Mulder
, Basic Principles of Membrane Technology,
Kluwer Academic Publishers
,
Dordecht, The Nederlands
,
1996
10.
M.
Cheryan
,. Membrane Technology in Food Bioprocessing, In :
R. P.
Singh
and
M. A.
Wirakartakusumah
,
Advances in Food Engineering
,
CRC Press Inc.
,
Boca Ratan, Florida
,
1992
11.
Anonymous
,
Official Methods of Analysis, Association of Official Analytical Chemistry (AOAC)
,
Washington D.C
.,
1995
12.
W.
Ruengsitagoon
, and
N.
Hattanat
, “
Simple spectrophotometric method for determination of folic acid
”,
The 4th Annual Northeast Pharmacy Research Conference
,
Thailand
,
2012
13.
M.
Holasova
,
V.
Fiedlerova
, and
S.
Vavreinova
, “
Czech Journal of Food Science
, Vol.
26
, No.
1
,
2008
, pp.
31
37
.
14.
H.D.
Belitz
,
W.
Grosch
,
P.
Schieberle
,
Food Chemistry
, 2nd edition,
Springer-Verlag Berlin Heidelberg.
ISBN 3-540-15043-9,
2002
, pp
379
393
.
15.
P
Eichhorn
, and
T.P.
Knepper
, “
Electrospray ionization mass spectrometric studies on the amphoteric surfactant cocamidopropylbetaine
”,
Journal of Masspectrometry
, Vol.
36
, Issue
6
, ESWE Institute for water Research and water Technology, Soecheinstr, 158, D-65201 Wiesbaden, Germany. Fenemma, O.R. 1976. Principle of Food Science, Marcel Dekker Inc. New York,
2001
, pp.
677
684
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