Production Technology for Adding GDL (Glucono Delta Lactone) to Soy-Based Foods

Abstract

The technology of adding Glucono Delta Lactone (GDL) to food made from soybeans is gaining popularity because it has many advantages. GDL is an acid that functions to coagulate proteins. GDL is a food additive that is Generally Recognized as Safe (GRAS). GDL has been applied in soy-based products such as tempeh and tofu. The use of GDL in tempeh products can reduce the acidification time of tempeh to 2-3 hours so that the production capacity of tempeh can increase significantly and reduce the amount of water used in the production process. The use of GDL in tofu is as a coagulant which makes the quality of tofu better than other agglomerates. The main objective of this paper is to provides an explanation of the application of GDL to soy-based foods. So, GDL can be used as an innovation to develop soybean-based food industries. It begins from describing about GDL, provides comparison between natural soy-based food and soy-based foods with GDL from study literature. Then moves to the application of GDL in tempeh, the application of GDL in tofu, and Back-Slopping technology.

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International Journal of Quantitative Research and
Modeling
Vol. 2, No. 2, pp. 75-82, 2021
Al Jazari Journal of
Mechanical
Engineering
ISSN: 2527-3426
Al Jazari Journal of
Mechanical
Engineering
ISSN: 2527-3426
e-ISSN 2721-477X
p-ISSN 2722-5046
Production Technology for Adding GDL (Glucono Delta Lactone)
to Soy-Based Foods
Athila Safira Rahma
Department of Food Technology, Faculty of Science and Technology, Universitas Terbuka, Indonesia
*Corresponding author e-mail address: athilasafira@gmail.com
Abstract
The technology of adding Glucono Delta Lactone (GDL) to food made from soybeans is gaining popularity because
it has many advantages. GDL is an acid that functions to coagulate proteins. GDL is a food additive that is
Generally Recognized as Safe (GRAS). GDL has been applied in soy-based products such as tempeh and tofu. The
use of GDL in tempeh products can reduce the acidification time of tempeh to 2-3 hours so that the production
capacity of tempeh can increase significantly and reduce the amount of water used in the production process. The
use of GDL in tofu is as a coagulant which makes the quality of tofu better than other agglomerates. The main
objective of this paper is to provides an explanation of the application of GDL to soy-based foods. So, GDL can be
used as an innovation to develop soybean-based food industries. It begins from describing about GDL, provides
comparison between natural soy-based food and soy-based foods with GDL from study literature. Then moves to
the application of GDL in tempeh, the application of GDL in tofu, and Back-Slopping technology.
Keywords: Back-slopping, Glucono Delta Lactone (GDL), Soybean
1. Preliminary
Soybean (Glycine max) is a plant that has long been cultivated in Indonesia (Mariyono, 2019; Malik, A.,
and Nainggolan, 2020). Soybean is a secondary crop category with a high enough source of vegetable
protein to overcome the lack of calories and contains more complete essential amino acids (Naito et al.,
1993; Krisnawati and Adie, 2015). Some of the famous processed soy foods are tempeh and tofu. In
addition, both are processed food products that have a fairly high level of demand at affordable prices and
contain high protein (Ningrum et al., 2018; Adie et al., 2014).
Tempeh and tofu have a long production time. Tempeh has a production time of up to 3 days and tofu
has a production time of 12-24 hours. The processing time is long enough to make the quantity of tempeh
and tofu production low. However, the high level of demand makes it unable to meet market needs. So,
we need innovation so that the processing of tempeh and tofu is faster, namely by adding GDL (Wang et
al., 2020; Zheng et al., 2020).

Rahma / International Journal of Quantitative Research and Modeling, Vol. 2, No. 2, pp. 75-82, 2021 76
The technology of adding GDL to food made from soybeans is gaining popularity because it has many
advantages. GDL is an acid that functions to coagulate proteins and food additive that is Generally
Recognized as Safe (GRAS) (Johnson et al., 2003; Ojukwu et al., 2020). GDL has been applied in soy-
based products such as tempeh and tofu. The use of GDL in tempeh products can reduce the acidification
time of tempeh to only 2-3 hours so that the production capacity of tempeh can increase and reduce the
amount of water used in the production process (Yang et al., 2021; Wijaya and Nurjanah, 2015). While
the use of GDL in tofu will provide a better quality of tofu (Inggrid and Hananjaya, 2020; Sim et al.,
2020; Arii et al., 2021)
The use of GDL in tempeh and tofu did not affect the taste, compactness, texture, and nutrition of both
(Jia et al., 2009). However, GDL has a fairly expensive price so that production costs are high. Therefore,
back-slopping technology has begun to be developed in the process of making tempeh and tofu is still
being tested. Back-slopping technology is the reuse of the remaining GDL solution from the tempeh
soaking process. The use of a back-slopping solution can produce tempeh which is no different from the
results of the initial soaking of the GDL solution. The application of back-slopping is expected to reduce
production costs for using (Wijaya and Nurjanah, 2015). So, that the application of back-slopping
technology can increase the quantity, quality, and production benefits for tempeh producers. The main
contribution of this research is to provides an explanation of the application of GDL to soy-based foods.
So, GDL can be used as an innovation to develop soybean-based food industries.
2. Study Literature
2.1 Definition Of GDL (Glucono Delta Lactone)
Glucono Delta Lactone (GDL) or also known as lactone is a food additive derived from the
hydroxycarboxylic acid group of cyclic ester types. GDL is Generally Recognized as Safe (GRAS)[2].
GDL is naturally found in the body of bees and humans. Synthetically, GDL can be made by fermenting
corn starch. GDL in the food industry functions as a protein coagulant because it has a strong affinity for
water and protein deposits. GDL is commercially available and has been widely applied in the food
industry[5]. GDL available in the market has a white fine crystalline form, odorless, and tasteless. In
soybean-based food preparations, initially, GDL was only used as tofu coagulation. But now, GDL has
been used as an acidifier that speeds up the tempeh fermentation process. GDL is also used in other
processed foods such as sausages, yogurt, and various dessert mixes.
2.2 Comparison Between Natural Tempeh Acidification and GDL’s Tempeh Acidification
The demand for tempe products both in Indonesia and other countries is quite high. So, it is
expected that the amount of production can meet consumer needs but with quality that matches
expectations. However, the facts on the ground show that tempe processing is still using the traditional
method. This method takes a long processing time and the resulting product sometimes is not uniform.
Therefore, an innovation is needed to speed up the tempeh production process and produce uniform
quality products, one of which is using GDL. Comparison natural tempeh with GDL can be seen in Table
1.
Table 1. Comparison natural tempeh with GDL
Comparison Criteria
Natural Tempeh
Tempeh With Gdl
Acidification Time
Overnight
2-3 hours
Washing Proccess
Two steps
One step
Acidification Proccess
Not controlled
More controlled
Consistency
Less uniform
More uniform
Nutrition
Not much different

Rahma / International Journal of Quantitative Research and Modeling, Vol. 2, No. 2, pp. 75-82, 2021 77
2.3. Comparison Between Tofu With GDL and Tofu With Other Coagulants
Tofu is the one of soybean products that has long been known in many countries. Tofu has a soft
texture and a distinctive aroma and taste. In the tofu processing process, a coagulant is needed, so that the
tofu can solidify properly. The agglomerates used are usually acid coagulation (lactic acid and acetic
acid), calcium coagulation, or magnesium coagulation. However, the wrong choice of agglomerate will
result tofu with less acceptable organoleptic properties. Therefore, a coagulation agent is needed that can
produce better organoleptic tofu, namely GDL. Comparison tofu with gdl and tofu with other coagulants
can be seen in Table 2.
Table 2 Comparison tofu with gdl and tofu with other coagulants
Comparison Criteria
Tofu with Other Coagulants
Tofu With Gdl
Texture
Coarsed textured (magnesium or calcium
coagulants) and brittle (acid coagulants)
Soft and not easy brittle
Aroma
Unpleasant aroma
Pleasant aroma
Taste
Sour (acid coagulant)
Slightly sour
Water holding capacity
Low (magnesium or calcium coagulants)
High
Clotting
Faster (magnesium or calcium coagulants and GDL)
3. Results and Discussion
3.1 The Application of GDL in Tempeh
Tempeh is a product obtained from fermenting soybean seeds using Rhizopus sp., in the form of a
compact solid, slightly grayish-white, and has a characteristic tempeh odor (Christian et al., 2019).
Fermentation in tempeh can be done spontaneously or using a starter culture to produce uniform quality.
An important process for good tempeh fermentation is acidification both naturally and chemically.
Tempe acidification process in Indonesia is done by soaking soybeans that have been boiled at a
temperature of 28-31°C until the water is foamy and smells sour. While the chemical acidification
process is widely used by countries with subtropical climates by adding acidifying agents to obtain
suitable conditions for molds to grow. The natural process of making tempeh can be seen in Figure 1.
Figure 1 The natural process of making tempeh

Rahma / International Journal of Quantitative Research and Modeling, Vol. 2, No. 2, pp. 75-82, 2021 78
However, there are several obstacles in the natural acidification process such as the length of time of
production, the consistency of the final quality of tempeh which is less uniform, and the wastewater from
the processing is feared to pollute the environment. So that the chemical acidification process began to be
developed by adding GDL (Glucono Delta Lactone) to the tempeh making process through the product
"Quick Tempe". GDL works by replacing the natural acidification process obtained by soaking soybeans
overnight. So, this process can summarize the acidification time of tempeh in just 2-3 hours. This is
because the soaking process using GDL can bind water and protein in soybeans so that soybeans can
later form mycelium in a short time. In addition, the resulting quality will be more uniform and water use
will be reduced.
Figure 2 Making Tempeh with GDL (Wijaya and Nurjanah, 2015)
Although the acidification process uses chemicals, this will not affect the taste, compactness, and
nutrients contained in tempeh. Controlled acidification can produce tempeh quality with a more stable
taste (Wijaya and Nurjanah, 2015). There was no significant difference between tempeh processed using
GDL and natural tempeh. In addition, there was no decrease in nutrition between natural tempeh and
tempeh processed using GDL (See Figure 2). So, it can be concluded that processing tempeh using GDL
saves more time but does not reduce the taste, compactness, and nutrients contained in tempeh.
comparison natural tempeh and GDL's Tempeh can be seen in Figure 3. The nutrient content between
natural tempeh and GDL’s Tempeh can be seen in Table 3.
Figure 3 Natural Tempeh (Left) and GDL's Tempeh (Right) (Wijaya and Nurjanah, 2015)
Table 3. Nutrient content between natural tempeh and GDL’s Tempeh

Rahma / International Journal of Quantitative Research and Modeling, Vol. 2, No. 2, pp. 75-82, 2021 79
Product
Contents (%)
Protein
Fat
Carbohydrate
Fiber
Traditional Tempeh
35.30
24.87
28.12
6.30
Tempeh with GDL
39.85
23.20
26.43
6.11
3.2 The Application of GDL in Tofu
Tofu is a product made from the clumping of protein from beans. Tofu has been widely known both
in Indonesia and foreign countries (Li et al., 2014). Tofu consists of several types including white tofu,
beancurd, hard tofu, silken tofu, kori tofu, sufu, and Thai tofu. Tofu is made using auxiliary materials in
the form of coagulants. Coagulants work by precipitating protein and trapping water contained in
soybean juice. Then the water is removed from the protein deposits by applying pressure to leave only
the protein clumps. The clumps of protein are then referred to as tofu.
Some of the coagulation materials that can be used are tofu or sioko, vinegar acid, tofu (whey), pure
calcium sulfate, and GDL (Tseng and Xiong, 2009). However, not all coagulants will produce good
quality tofu. Acid coagulants such as lactic acid and acetic acid produce low yields tofu with a brittle and
slightly acidic texture. Meanwhile, calcium or magnesium chloride coagulant produces tofu with good
flavor, faster clotting, but coarse-textured tofu due to low water holding capacity. So, we need a type of
coagulant that can produce tofu with better texture, flavor, and aroma. After conducting various studies,
the right coagulant was obtained, namely Glucono Delta Lactone (GDL).
Glucono Delta Lactone (GDL) in the tofu production process works as an acid-type coagulant. The
reason why GDL is appropriate to be used as a coagulant is because it has a high water-holding capacity
and the resulting tofu has a soft, gel-like texture and is not easily brittle. Tofu that is processed using
GDL also produces a slightly sour taste and no unpleasant aroma. Some of these reasons make tofu with
GDL coagulant preferred by the public. So, it can be concluded that tofu that is coagulated with GDL
will produce tofu with much better quality than tofu that is coagulated using other coagulants (Li et al.,
2021).
Figure 4 Tofu Making with GDL (Source: Interview Result)

Rahma / International Journal of Quantitative Research and Modeling, Vol. 2, No. 2, pp. 75-82, 2021 80
3.3 Advantages and Disadvantages of the Use of GDL in Soy-Based Foods
The use of GDL in food made from soybeans certainly has advantages and disadvantages. In tempeh, the
excess use of GDL will shorten the soy acidification time to only 2-3 hours. The water used is less
because the washing process is not carried out many times so that it can prevent environmental pollution.
In addition, acidification using GDL will make the taste and results more uniform because the
acidification process is controlled. Although processed using chemical acidification, the nutrients and
compactness produced are not much different from tempeh produced by natural acidification.
The advantage of using GDL in tofu is that it can produce a better-quality tofu. Tofu that is processed
using GDL will have a softer and stronger texture. In addition, the use of GDL in tofu will not affect the
nutrition, color, and aroma of tofu so that the organoleptic quality of tofu is guaranteed. This causes tofu
processed with GDL coagulant to be preferred by the public. It can be concluded that the excess use of
GDL in processing tempeh and tofu will shorten processing time, but the resulting product still has good
quality and even increases in several aspects.
While the disadvantage of using GDL is the selling price on the market. GDL in the market has a
fairly expensive price. This causes producers to prefer to process products with natural acidification and
coagulation to save production costs. In addition, the use of GDL with the wrong amount will damage
the quality of the resulting product. So, we need an innovation using GDL which is more cost-effective
but product quality is guaranteed.
3.4 Opportunities and Challenges of using GDL
The use of GDL in the manufacture of tofu and tempeh has great opportunities. Currently, in Indonesia,
there are around 81 thousand tempeh-making businesses that produce 2.4 million tons of tempeh per
year. Based on the SUSENAS data in 2015 released by BPS, the average consumption of tempeh per
person per year in Indonesia is 6.99 kg and tofu 7.51 kg (Zheng et al., 2020). So, the use of GDL will be
needed to meet market demand. The use of GDL in the manufacture of tempeh will produce a product
with less waste-water, uniform product quality, and shorter production time. In addition, we already
know that tempeh which is processed using a GDL acidifier has been selected as one of the 100
Indonesian innovations in 2008 with a product called "Quick Tempe". So this will be an opportunity for
tempeh industries that still use natural acidification processes to switch to chemical acidification
processes using GDL.
The use of GDL as tofu coagulation has been applied for quite a long time. However, there are still
many manufacturers who choose to use other coagulants than GDL. This is because other types of
coagulants have lower prices. Even though it is cheaper, the tofu produced is of poor quality. Such as
brittle texture, mushy, unpleasant, and sour so that it is not liked by the public. Based on this, GDL began
to be used as tofu coagulation and the resulting product had a better quality. Tofu that is processed using
GDL coagulant has a soft, strong texture, no unpleasant aroma, and a slightly sour taste so that it is
preferred by the public.
The various opportunities available certainly have their challenges. The challenge for using GDL
experienced by producers is the relatively expensive price of GDL compounds. This causes many tempeh
producers to choose to use a natural acidification process even though it takes time. Meanwhile, tofu
producers choose to use other coagulants and even hazardous materials such as formalin so that the tofu

Rahma / International Journal of Quantitative Research and Modeling, Vol. 2, No. 2, pp. 75-82, 2021 81
produced is better organoleptically. The challenges faced by manufacturers then create new technology,
namely back-slopping.
Back-sloppping is a technology in the form of reusing the remaining GDL solution from soaking
which can be used in the next tempeh production proccess. The use of back-slopping aims to save the
cost of using GDL from tempeh production, but with the concentration of the solution that must be
optimized. After testing, the results obtained tempeh which has a quality that is not much different from
"Quick Tempe". The application of back-slopping technology can also reduce 4.8 percent of the total
production cost of "Quick Tempe" compared to without the application of back-slopping and can
increase the total profit by 49.9 percent compared to natural acidification tempeh (Wijaya and Nurjanah,
2015). Although the use of back-slopping technology has been tested in tempeh production, this
technology has not been tested in the tofu production process. So that in the future it is hoped that this
technology can be tested in the manufacture of tofu.
4. Conclussion
Soybean is one of the important crops that has been processed into various products including tempeh
and tofu. They both have a fairly high demand but the processing process is quite long, 3 days for tempeh
and 12-24 hours for tofu. So, we need an innovation that aims to produce tempeh and tofu faster but the
quality produced is better. The innovation is the use of GDL in the process of making tempeh and tofu.
GDL in the tempeh production process functions as a substitute for soaking soybeans for one night to 2-3
hours and fermentation for only 36 hours. Tempeh produced has uniform quality and compactness but
does not reduce the nutrients in it. Whereas in tofu, the use of GDL will result in a better quality of tofu,
namely soft texture, strong, not unpleasant aroma, and slightly sour taste so that it is preferred by the
public.
Although GDL has a high chance of processing tempeh and tofu, there are also have drawbacks. The
price of GDL in the market is quite high so that it will increase production costs that are burdensome for
producers. Therefore, an innovation was carried out, namely back slopping technology, where the
remaining of soaking GDL solution was reused in the next tempeh production process. It has been
proven that there is no significant difference between tempeh processed using back-slopping and "Quick
Tempe". In addition, it can reduce production costs by 4.8 percent and increase profits by up to 49.9
percent. However, the back-slopping technology in tofu has not yet been tested. So that in the future it is
hoped that back-slopping technology will be tested on tofu.
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