A Narrative Review of Artificial Sweeteners
Gefei Zhang
Wuhan Britain China School, Wuhan, 430000, China
Keywords:
Nonnutritive Sweeteners, Artificial Sweeteners.
Abstract:
Nonnutritive sweeteners (NNS) are a class of food additives used by the food industry worldwide to combat
diseases such as weight gain and type 2 diabetes by maintaining their sweet taste while maintaining low or no
calorie intake. Artificial sweeteners have been widely used in food-production industry for their advantages
of supernal sweetness, no nutrition and low calorie. However, the safety and effectiveness of artificial
sweeteners remain controversial. This paper introduces the metabolic characteristics and detection methods
of five common artificial sweeteners, including Acesulfame-K, aspartame, neotame, saccharin and sucralose.
Suggestions on the development of artificial sweeteners were put forward to provide reference for further
rational development and safe use of artificial sweeteners.
1 INTRODUCTION
More than a century has passed since saccharin, the
oldest NNS (Mooradian, 2013) was first used.
American children are reported to be consuming
NNS every day, up from 30 percent in 2008. Public
interest in NNS has increased because they lessen the
energy density of the diet without loss of sweetness.
A variety of artificial sweeteners have been
discovered and applied in different fields, especially
in the production of beverages and foods, such as
baked goods, dairy products and beverages (Dunford,
2018)
By definition, NNS, also known as very low-
calorie sweeteners, artificial sweeteners, no-calorie
sweeteners and high-intensity sweeteners, are
sweeter than nutritional sweeteners like table sugar.
As a result, small amounts of NNS are needed to
create the sweetness needed by many nutritional
sweeteners. In this way, they do not offer or offer
low-calorie ones (Gardner, 2012).
The effects of NNS on human metabolic
responses are complex. Some studies have shown
positive effects, such as significant weight loss in the
short term and weight control in the long term (Li,
1997). Some have no effect on glycemic control in
patients with type 2 diabetes (Grotz, 2003). Some
studies have shown many adverse effects, including
cardiovascular, renal toxicity, obesity, and cognitive
effects (Lohner, 2017). There are some physiological
mechanisms for the occurrence of these symptoms,
such as intestinal microbes causing intestinal
inflammation and so on, thus promoting the
occurrence of these symptoms
A number of metabolic disorders associated with
obesity. This review aims to explain how artificial
sugars produce sweetness, introduce different types
of artificial sugars, their effects on human health, and
explore possible future research areas from articles
collected on Pubmed.
2 THE PRINCIPLE OF
ARTIFICIAL SWEETENERS
CREATE THE TASTE OF
SWEETNESS
These two G protein-coupled receptors of the c
family can detect all sweet compounds (GPCR) T1R2
and T1R3 expressed on the surface of mammalian
taste buds (Li, 2002). Studies have shown that Sac is
a single master site in mice that affects the response
to several sweet substances, including preference for
sucrose, acesulmae-K and dulcin (Fuller, 1974).
Sweet transduction of natural sweeteners may be
explained by the activation of adenylate cyclase,
adenosine 3', 5' -cyclic adenosine phosphate (cAMP)
dependent membrane generation (Streem, 1991), K+
channel inactivation (Avenet, 1998), and Ca2+
240
Zhang, G.
A Narrative Review of Artificial Sweeteners.
DOI: 10.5220/0012019000003633
In Proceedings of the 4th International Conference on Biotechnology and Biomedicine (ICBB 2022), pages 240-244
ISBN: 978-989-758-637-8
Copyright
c
2023 by SCITEPRESS – Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
(Lindemann, 1996) depolarization after flavor
transducers bind to receptors. The opening of
voltage-gated Na+ and K+ channels leads to action
potentials in presynaptic neurons (Cummings, 1993).
Some studies have shown that artificial
sweeteners increase sweetness intensity by increasing
affinity for one or more sites on T1R2 and T1R3
receptors (Xu, 2004). Some studies have shown that
receptors T1R2 and T1R3 respond differently to
artificial sweeteners. Daly et al demonstrated that the
commonly used NNS sucralose, saccharin and
acesulfame K activated T1R2 and T1R3 in pigs,
while NNS aspartame and cyclohexylsulfamate did
not (Daly, 2001).
3 TYPES OF ARTIFICIAL
SWEETENERS
The five NNS approved by the FDA include
Acesulfames, aspartame, neotame, saccharin, and
sucralose (Brown, 2010). In addition, basic
information about these five non-nutritional
sweeteners is shown in Table 1.
Saccharin is the oldest artificial sweetener used. It
was developed by Johns Hopkins University in 1878.
The FDA approved it in 1879. It is 200 to 700 times
sweeter than sucrose (Bermann, 2017).
Aspartame was first discovered in 1965. It
consists of two amino acids, phenylalanine and
aspartic acid, with methanol as the main chain. It was
approved by FDA in 1981. It is 200 times sweeter
than table sugar. Aspartame's safety remains in
question as its metabolism ultimately leads to the
formation of formaldehyde, formic acid and
diketopiperazine.
Acesmeline K was first discovered in 1967 and
approved for use by the FDA in 2003. It is 120 times
sweeter than sucrose (Rymon, 1991). Because it is
thermally stable and has a bitter aftertaste when used
alone, it is used in cooking and baking. When used in
cooking and baking, it is often mixed with other
sweeteners, such as sucralose or aspartame (Horne J,
2002).
Neotame was approved by the FDA in 2002 and
is currently the most effective sweetener available. It
is chemically related to aspartame. It is 7000 times
sweeter than sucrose (Prakash I, 2007).
Sucralose was synthesized in 1976 by replacing
chlorine with three hydroxyl groups in sucrose and
was approved by the FDA in 1999. It is 600 times
sweeter than sucrose (Arora, 2009).
Table 1: The basic information of five Nonnutritive Sweeteners.
Sweetener
Chemical
formula
*Sweetness FDA-approved date
Saccharin C
7
H
5
NO
3
S 200 - 700 1879
Aspartame C
14
H
18
N
2
O
5
200 1981
Acesulfame-K C
4
H
4
KNO
4
S 120 2003
Neotame C
20
H
30
N
2
O
5
7000 2002
Sucralose C
12
H
22
O
11
600 1999
*Sucrose=1 (Relative to a 10% sucrose solution) Different numbers indicate effect in different foods
4 ARTIFICIAL SWEETENERS
AND HUMAN HEALTH
4.1 Artificial Sweeteners and Obesity
Feijo et al., Foletto et al., and rats showed that intake
of saccharin or aspartame promotes weight gain
without significant changes in caloric intake, insulin
resistance, and fasting leptin (Feijo, 2013). A large
number of studies have shown that the use of NNS is
positively correlated with weight gain (Stellman,
1986). In a cohort study completed by Chia et al.,
NSS users significantly increased BMI and waist
circumference from 1984 to 2012 with a median
follow-up of 10 years of 1,454 participants (741
males, 713 females) (Liu, 1990). A cohort study
included 3,033 volunteers whose mothers consumed
artificially sweetened and sugary drinks between
2009 and 2012. Studies have shown an association
between daily intake of NNS and a two-fold
increased risk of being overweight at age 1
A Narrative Review of Artificial Sweeteners
241
4.2 Effects on Gut Microbes
The effects of NNS on microbes vary. Table 2 shows
the effects of five non-nutritive sweeteners on the gut
microbiome.
Due to the fast absorption and excretion rate of
acesulphine potassium into systemic circulation, it
has little effect on colon flora (Magnuson, 2016).
Similarly, aspartame has little effect on colonic flora
(Stegink, 1987) because it is rapidly absorbed in the
duodenum and jejunum. On the other hand, a small
amount of saccharin (less than 15%) is not absorbed
as a whole molecule and thus enters the colon,
affecting the microflora (Plaza-Diaz, 2020). In in
vitro model studies, saccharin increased the number
of bifidobacterium (Renwick, 1985). The minimum
amount of sucralose (less than 15%) is absorbed and
hardly metabolized. Thus, more than 85% of
sucralose reaches the colon. However, more than
94% were recovered from feces, and no structural
changes occurred, indicating no impact on microbial
community (Magnuson, 2016). The effect of
neotsuan on gut microbes has not been assessed, as
only trace amounts of neotsuan are needed to sweeten
foods. It can be metabolized quickly. Therefore,
neotame is unlikely to affect gut microbes.
Table 2: The effect on microbiome in the gut of Five
Nonnutritive Sweeteners.
Sweetener
Effect on microbiome in the
gut
Saccharin
Affect bacteria such as
Bifidobacterium
Aspartame
Almost no effect since large
amount is absorbed
Acesulfame-K
Almost no effect since large
amount is absorbed
Neotame -
Sucralose Almost no effect
4.3 Influence on Kidney
Recent studies have also found a relationship
between NNS intake and chronic kidney disease
(including proteinuria, the threshold of the
albumin/creatinine ratio >17mg /g in men and >25mg
/g in women) and decreased renal function. In a cross-
sectional analysis of 9358 subjects from 1999 to
2004, soda consumption and NNS may be associated
with proteinuria. In addition, a study of 3,318 women
from 1989 to 2000 found that drinking more than two
servings of artificially sweetened soda a day tripled a
woman's risk of kidney function decline.
5 CONCLUSION
This literature review combines systematic reviews,
prospective cohort studies, and meta-analyses to
illustrate the possible mechanisms of neural network
sweetness and the possible negative effects of neural
network on human body. Although NNS created as
an alternative to sugar attempts to provide the same
sweet intensity as the nutritional sweetener sucrose,
there is substantial evidence of profound negative
effects on the human body, including host microbes,
weight gain, and kidney health. Although NNS are
thought to be healthier than sugar, most data
contradict this claim.
Future research should include novel sweeteners
such as naturally occurring rare sugars, including D-
Allulose (D-Psicose), D-Tagatose, D-sorbide and D-
Allose, their effects on humans, and the feasibility of
using them in mass production.
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