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Author(s): Sara Masood, Attiq ur Rehman, Shahid Bashir, Mohamed El Shazly, Muhammad 
Imran, Palwasha Khalil, Faiza Ifthikar, Hafiza Madiha Jaffar & Tara Khursheed 

Title: Investigation of the anti-hyperglycemic and antioxidant effects of wheat bread 
supplemented with onion peel extract and onion powder in diabetic rats 

Year: 2021 

Version: Published version 

Copyright:   The Author(s) 2021 

Rights: CC BY 4.0 

Rights url: http://creativecommons.org/licenses/by/4.0/ 

 

Please cite the original version: 

Masood, S., Rehman, A.u., Bashir, S. et al. Investigation of the anti-hyperglycemic and antioxidant 
effects of wheat bread supplemented with onion peel extract and onion powder in diabetic rats. J 
Diabetes Metab Disord (2021). https://doi.org/10.1007/s40200-021-00770-x 



RESEARCH ARTICLE

Investigation of the anti-hyperglycemic and antioxidant effects
of wheat bread supplemented with onion peel extract and onion
powder in diabetic rats

Sara Masood1
& Attiq ur Rehman2,3

& Shahid Bashir1 & Mohamed El Shazly4,5 & Muhammad Imran1
&

Palwasha Khalil1 & Faiza Ifthikar1 & Hafiza Madiha Jaffar1 & Tara Khursheed1

Received: 3 December 2020 /Accepted: 14 February 2021
# The Author(s) 2021

Abstract
Aim Onion is one of the commonly cultivated and consumed vegetables rich in nutrients and phytochemicals. Various
nutraceuticals are found in the outer fleshy layers and dry peel of onion which usually is treated as a common biowaste.
Diabetes mellitus is a leading non communicable disease causing hyperglycemia and increased production of free radicals that
potentially disrupts antioxidant enzymatic activity. Considering global consumption of wheat, the present study was designed to
evaluate the anti-hyperglycemic and antioxidant effects of wheat bread supplemented with onion peel extract (OPE) or onion
powder (OP) on diabetic rats.
Methods In this study, ethanolic extract of onion peel and onion bulb were prepared separately. Male Sprague Dawley rats were
divided into 6 groups (n = 7). Different regimens of supplemented wheat bread (OPE (1% and 3%) and OP (5% and 7%)) were
given to diabetic rats for eight weeks, plain bread was used as the control. Blood glucose level, body weight and activities of
SOD, CAT, GPx, GR, GSH and MDA in the liver and kidney tissues were evaluated. Statistical analysis was performed using
SPSS Version (25) and Dunnett’s multiple comparison test.
Results Bread supplementedwith 1% and 3% onion peel extract and 7% onion powder significantly reduced blood glucose levels
and MDA in the treated rats compared with the control group diabetic rats. Body weight of diabetic rats was reduced for control
group, while onion supplemented diet improved the body weight of treated rats. Onion supplementation also brought significant
improvement in antioxidant enzyme activities among the treated diabetic rats.
Conclusion These findings suggested that onion supplementation is effective in lowering blood glucose and could potentially aid
in protecting organs from oxidative stress.

* Attiq ur Rehman
attiq.rehman@luke.fi

Sara Masood
sarah.13494@gmail.com

Shahid Bashir
shahid.bashir@rsmi.uol.edu.pk

Mohamed El Shazly
mohamed.elshazly@pharma.asu.edu.eg

Muhammad Imran
mic_1661@yahoo.com

Palwasha Khalil
palwasha5993@gmail.com

Faiza Ifthikar
faizaifthikar@gmail.com

Hafiza Madiha Jaffar
madiha.jaffar@dnsc.uol.edu.pk

Tara Khursheed
tara.khursheed@dnsc.uol.edu.pk

1 University Institute of Diet and Nutritional Sciences (UIDNS),
Faculty of Allied Health Sciences, University of Lahore,
Lahore, Pakistan

2 Horticulture Technologies, Production Systems Unit, Natural
Resources Institute (Luke), Toivonlinnantie 518,
FI-21500 Piikkiö, Finland

3 Department of Agricultural Sciences, Faculty of Agriculture and
Forestry, University of Helsinki, FI-00790 Helsinki, Finland

4 Department of Pharmaceutical Biology, Faculty of Pharmacy and
Biotechnology, German University in Cairo, Cairo, Egypt

5 Department of Pharmacognosy, Faculty of Pharmacy, Ain Shams
University, African Union Organization Street,
Cairo, Abbassia 11566, Egypt

Journal of Diabetes & Metabolic Disorders
https://doi.org/10.1007/s40200-021-00770-x

http://crossmark.crossref.org/dialog/?doi=10.1007/s40200-021-00770-x&domain=pdf
http://orcid.org/0000-0002-0131-3928
mailto:attiq.rehman@luke.fi


Keywords Onion powder . Onion peel extract . Antioxidant activity . Hypoglycemic activity .Wheat bread . Phytochemicals

Introduction

Diabetes is characterized by impaired carbohydrate, protein, and
fat metabolism that results from poor insulin secretion, insulin
resistance, or both. Diabetes mellitus is currently one of themost
prevalent and life-threatening metabolic disorder globally.
Based on several estimations, it is suggested that its incidence
rate will rise even more rapidly in the coming future [1].
Recurrent hyperglycemia, which is the major clinical manifes-
tation in diabetic patients, is primarily associated with the pro-
gression of several acute and chronic diabetic complications.
Keeping blood glucose under controlled levels, understanding
the regulation of insulin response, and preventing diabetes-
associated complications are the most important goals in man-
aging diabetes [2]. Oxidative stress is one of the primary factors
involved in the development of diabetes complications and is
postulated to be linked with increased production of oxygen free
radical [3]. Under normal physiological conditions, various an-
tioxidant defensemechanismswork to protect the body from the
dangers of free radical production [4]. In diabetes, the elevation
of blood glucose levels promotes the production of reactive
oxygen species (ROS) [5]. The mechanisms involved in ROS
production not only includes auto-oxidative and non-enzymatic
glycosylation but also the metabolic stress that results from al-
tered energy metabolism, raised levels of inflammatory media-
tors, and poor status of the antioxidant defense system [6].

To understand the mechanism of diabetes and its relation to
oxidative stress, several in vivomodels were developed including
alloxan-induced diabetes in mice. Alloxan, a pyrimidine deriva-
tive, is used to induce diabetes and produce cytotoxic free radicals
that destroy animals’ pancreatic cells. These effects suggest that
alloxan could influence the intrinsic antioxidant defense system in
response to oxidative stress [7]. The hazardous effects of oxygen
and hydroxy radicals can be prevented by various antioxidant
enzymes such as catalase (CAT), glutathione peroxidase (GPx),
and superoxide dismutase (SOD). Glutathione (GSH) also works
efficiently to neutralize the damaging electrophiles [8].

Several classes of drugs were developed to manage diabetes
showing impressive results but many of the developed products
resulted in side effects because the antidiabetic drugs are life-
long. Therefore, there is growing interest to incorporate medic-
inal plant-based products into the diet of the general population
to reduce the medication use and thus their side effects and to
obtain maximum preventive outcome [9]. Onion (Allium cepa
L.) is a widely cultivated and consumed vegetable that serves as
an excellent source of macro and micronutrients [10]. Along
with the bulb, the peel of onion, which is generally regarded
as a biowaste is rich in various phytonutrients. Although the
management of diabetes with traditional plants has been a

widespread practice for centuries [11], only a few remedies have
been assessed scientifically. Many researchers demonstrated the
antidiabetic, hypocholesterolemic, and antioxidant potential of
onion peel extract and onion powder [12–18]. The evaluation
and utilization of biowaste (onion peel) as a supplementary in-
gredient in food for target groups will have sustainable health,
economic and environmental impact. Wheat (Triticum aestivum
L.) is one of themost commonly consumed staple food [19], and
there has been growing interest towards its fortification with
micronutrients and nutraceuticals [20–22]. Hence, in the present
study, the American Institute of Nutrition (AIN)-93G diet for
rodents was modified to formulate bread using ingredients like
wheat flour, onion powder/onion peel extract to evaluate the
effect of their supplementation on blood glucose level, and the
antioxidant activities of various enzymes in the kidney and liver
homogenates of diabetic rats. The potential physiological influ-
ence of the onion’s outer peel and the edible bulb has not been
compared yet in a scientific study. Considering all these points,
the present study examined the potential impact and antioxidant
activities of the peel extract and bulb powder of onion on the
in vivo kidney and liver cell metabolism of diabetic rats.

Material and Methods

Animals

Male Sprague Dawley rats (10–12 weeks old) weighing 250–
300 g, were purchased from the National Institute of Health
(NIH) Islamabad-Pakistan and were acclimatized for 2 weeks
in the animal house of the University of Lahore, Pakistan
(March 2019–May 2019). Seven rats were kept in each cage
and the environmental conditions such as humidity (55 ± 5%)
and temperature (23 ± 2 °C) were sustained during the entire
study with 12 h of light-dark period. Rats were given free
access to the basal diet and water ad libitum. The rats were
handled according to the international guidelines on the use
and handling of experimental animals (US National Institute
of Health) [23] and the guidelines provided by the ethical
committee of the University of Lahore, Pakistan (Ref No:
IRB-UOL-FAHS/435/2019).

Onion peel extract preparation

Excellent quality, even-sized, undamaged onions (Var. Desi
Red, Phulkara) were procured from the local market. The
outer dry and fleshy layers of onions were washed thoroughly
using sterile water. Extraction was done with 60% ethanol at
50 °C for 3 h [13]. The extract was filtered, concentrated, and

J Diabetes Metab Disord



stored after freeze-drying. The extraction yield was 5.35 ±
0.12% while the total phenolic content was 397.85 ±
4.03 mg/g as determined by the Folin-Ciocalteu method [24].

Onion powder preparation

The obtained peeled onion bulbs were chopped using a sterile
knife and placed in a drying oven at 50 °C for 3 days. The
dried onion pieces were grounded into a fine powder using an
electric grinder and the obtained powder was stored in an
airtight container inside the refrigerator [25]. The yield of
onion powder was 12 g/100 g of the raw onion.

Preparation of bread

Five different formulations of bread were prepared including
(1) a control bread (B0) based on the basic AIN-93G diet
without any supplementation; (2) bread with 1% onion peel
extract (B1); (3) bread with 3% onion peel extract (B2); (4)
bread with 5% onion powder (B3); and (5) bread with 7%
onion powder (B4). The preparation of all mentioned types
of bread was done by following the same procedure [26]
and the composition of each bread is presented in Table 1.

The control wheat bread comprised 100% wheat flour, 70%
water (vol/wt, flour basis), 2% dry yeast (wt/wt, flour basis)
(Rossmoor, Pakistan), 2% salt (wt/wt, flour basis), and 1%dough
improver (wt/wt, flour basis) (eka-300) [26]. For supplemented
bread, the formulation was the same but for bread B1 and B2, the
wheat flour was substituted with OPE at 1% and 3%, respective-
ly. Whereas for bread B3 and B4 the wheat flour was substituted
with onion powder at 5% and 7%, respectively [13, 27–29].

Induction of diabetes in rats

Diabetes was induced in overnight fasted Sprague Dawley rats
by injecting alloxan (120 mg/kg/BW) dissolved in normal sa-
line, through the subcutaneous route. Glucose solution (20%
(w/v)) was also given to these rats to prevent fatal post-alloxan
hypoglycemia. After 48 h of alloxan administration, the rats
with fasting blood glucose levels>250 mg/dl were considered
diabetic and were included in the study [18, 30].

Treatment groups

The animals were randomly divided into six groups (7 rats
each):

► Group 1 (NC): Normal rats fed with control bread.
► Group 2 (DC): Diabetic rats fed with control bread.
► Group 3 (OPE_1): Diabetic rats fed with bread supple-

mented with OPE (1%).
► Group 4 (OPE_3): Diabetic rats fed with bread supple-

mented with OPE (3%).
► Group 5 (OP_5): Diabetic rats fed with bread supple-

mented with onion powder (5%).
► Group 6 (OP_7): Diabetic rats fed with bread supple-

mented with onion powder (7%).
Before starting the trial, fasting blood glucose level (mg/dl)

and body weight (g) were determined using a glucometer [31]
and weighing scale, respectively. The modified diet was then
given to the rats for 8 weeks. During the study, physical pa-
rameters such as water and bread consumption were measured
daily (Appendix Table 4) while blood glucose was determined
fortnightly. At the end of the trial, the rats fasted for 12 h and
the final measurement of blood glucose level and body weight
was taken [32]. All rats were anesthetized and sacrificed as per
ethical committee guidelines and at 4 °C, the kidney and liver
tissues were excised. Ice-cold saline was used to wash the
isolated tissues that were later dipped in liquid nitrogen and
instantly stored at −80 °C until further analysis [33].

Biochemical analysis

In the liver and kidney tissue homogenates, the activity of
superoxide dismutase (SOD) was determined by the Misra
and Fridovichmethod using a Hitachi U-2000 spectrophotom-
eter for 4 min at 480 nm. The potential enzymatic activity is
stated based on its ability to inhibit the epinephrine oxidation
up to 50%, that is equivalent to 1 U per milligram of protein
[34, 35]. The method of Aebi was used to assess the activity of
catalase (CAT) in which absorbance was determined by UV
spectrophotometer at 240 nm for 1 min [35, 36]. The method
elaborated by Carlberg and Mannervik was used to determine
the activity of Glutathione reductase (GR) and recommenda-
tions of Akerboom and Sies were followed to measure the
reduced glutathione (GSH) concentration in the kidney and

Table 1 Ingredients (g/100 g) of the experimental diets (breads) fed to
rats for 56 days

Composition Control
Bread
(B0)

Bread
with 1%
OPE
(B1)

Bread
with 3%
OPE
(B2)

Bread with
5% onion
powder
(B3)

Bread with
7% onion
powder
(B4)

Wheat 68.2 67.2 65.2 63.2 61.2
Salt 1.36 1.36 1.36 1.36 1.36
Dry yeast 1.36 1.36 1.36 1.36 1.36
Improver 0.68 0.68 0.68 0.68 0.68
Casein 14.58 14.58 14.58 14.58 14.58
Soybean oil 8.93 8.93 8.93 8.93 8.93
Minerals 3.38 3.38 3.38 3.38 3.38
Vitamin mix 0.97 0.97 0.97 0.97 0.97
L-cysteine 0.29 0.29 0.29 0.29 0.29
Choline 0.24 0.24 0.24 0.24 0.24
TBHQ 0.001 0.001 0.001 0.001 0.001
Onion

powder
0 0 0 5 7

Onion peel
extract

0 1 3 0 0

J Diabetes Metab Disord



liver homogenates [37–40]. Hepatic and renal enzymatic ac-
tivity of glutathione peroxidase (GPx) was evaluated follow-
ing the Flohe and Gunzler method, using cumene hydrogen
peroxide while the absorbance was calibrated at 340 nm [41,
42]. The procedure described by Ohkawa, Ohishi, and Yagi
was used to determine the concentration of malondialdehyde
(MDA), which indicates the extent of lipid peroxidation [43,
44]. Enzymatic activities were reported as per milligram of
protein and the protocol of Lowry, Rosebrough, Farr, and
Randall was used for estimation of tissue protein content using
bovine serum albumin (BSA) as the standard [45, 46].

Statistical analysis

Data were analyzed using SPSS (Version 25.0) [47].
Dunnett’s multiple comparison test (p < 0.01) was performed
to compare the antioxidants and enzymatic activity between
the diabetic and control (DC) groups [33, 48].

Results

Effect of OPE and OP supplemented bread on the
bodyweight of diabetic rats

The results obtained in the current study indicated that the rat’s
body weight (BW) was substantially reduced after induction of
diabetes. The incorporation of bread supplemented with onion
peel or onion powder significantly improved the body weight,
although the effect was statistically significant by onion peel
supplementation (Table 2). The difference between the mean
body weight of the treated and diabetic control group was ini-
tially insignificant (day 0) but during the later stages of the trial
(day 28 and 56), a statistically significant increase in bodyweight
of the treatment groups was observed (p < 0.01) (Table 2).

Effect of OPE and OP supplemented bread on blood
glucose level of diabetic rats

Blood glucose levels were measured fortnightly and weekly
variation in all the groups is presented in Table 3. The results
showed a significant effect of the bread incorporated with
onion peel extract and onion powder on the blood glucose
level of alloxan-induced diabetic rats. The initial and final
blood glucose levels in diabetic rats that were fed with the
control bread did not vary significantly. In treatment groups
that were either fed with 1%, OPE supplemented bread, 3%
OPE supplemented bread, or 7% OP supplemented bread, the
final blood glucose level (day 56) was significantly lower
(p < 0.01) than the initial blood glucose levels (day 0). While
comparing the treatment groups, it can be seen that in OPE_3
group blood glucose level dropped remarkably from 289 ± 5.8
on day 0 to 205 ± 3.3 on day 56 which is significantly high as

compared to OPE_1 and OP_7 groups where the final day
blood glucose level was 234 ± 6.2 and 230 ± 3.3 respectively.
Whereas the glucose-lowering effect of 5% OP supplemented
bread remained non-significant for most of the observation
checkpoints except for the end-point measurement (day 56)
(p < 0.01). The overall glucose-lowering effect of 3% OPE
supplemented bread was more pronounced as compared to
any other supplemented bread.

Effect of OPE and OP supplemented bread on the
antioxidant enzyme activities and MDA levels of
diabetic rats

Significant (p < 0.01) rise in the level of malondialdehyde
(MDA) and decline in catalase (CAT), superoxide dismutase
(SOD), glutathione reductase (GR), glutathione peroxidase
(GPx) activities, and glutathione (GSH) content were reported
in the diabetic control group in comparison with the normal

Table 2 Effects of onion peel extract and onion powder supplemented
breads on body weight changes in diabetic rats

Groups Body Weight (g) Day 28 Day 56
Day 0

NC 257±2.5 276±3.0* 295±1.4*
DC 258±3.2 237±2.1 222±1.7
OPE_1 266±4.2 267±4.6* 270±4.2*
OPE_3 266±6.7 271±6.2* 282±6.1*
OP_5 262±6.2 256±6.0* 259±5.9*
OP_7 258±5.6 262±5.7* 266±6.2*

Values expressed as means ± SEM, (NC = normal control, DC = diabetic
control, OPE_1 = group fed with bread containing 1% onion peel extract,
OPE_3 = group fed with bread containing 3% onion peel extract, OP_5 =
group fed with bread containing 1% onion powder, OP_7 = group fed
with bread containing 7% onion powder), * shows the significant differ-
ence compared with the diabetic control group (p < 0.01) via Dunnett’s
multiple comparison test

Table 3 Effects of onion peel extract and onion powder supplemented
breads on blood glucose level in diabetic rats

Groups Blood glucose level (mg/dl)

Day 0 Day 14 Day 28 Day 42 Day 56

NC 82±0.4* 86±0.9* 87±1.0* 93±0.6* 93±0.7*
DC 285±5.8 288±6.3 289±5.7 290±6.1 294±4.8
OPE_1 285±7.9 280±7.8 257±5.9* 241±3.3* 234±6.2*
OPE_3 289±5.8 275±4.6 242±4.4* 219±3.4* 205±3.3*
OP_5 289±2.6 284±2.7 280±2.8 277±2.8 268±3.5*
OP_7 292±5.4 282±5.0 264±5.2* 246±4.5* 230±3.3*

Values expressed as means ± SEM, (NC = normal control, DC = diabetic
control, OPE_1 = group fed with bread containing 1% onion peel extract,
OPE_3 = group fed with bread containing 3% onion peel extract, OP_5 =
group fed with bread containing 1% onion powder, OP_7 = group fed
with bread containing 7% onion powder), * shows the significant differ-
ence compared to the diabetic control group (p < 0.01) via Dunnett’s
multiple comparison test

J Diabetes Metab Disord



rats (Figs. 1, 2 and 3). In the 5% OP supplemented group, no
significant changes were observed in GPx levels of the liver
and kidney in comparison to the diabetic control group. Also,
there was no significant variation in the kidney’s GR and GSH
levels by the end of the 56 days treatment. However, in a
similar group also supplemented with 5% OP there was a
significant 29% and 35% reduction (p < 0.01) in the liver’s
superoxide dismutase and catalase activity, respectively.

Diabetic rat groups that were treated with OPE (1% and 3%)
and OP (7%) showed a significant (p < 0.01) increase in the
activities of GPx, GR, CAT, SOD, and GSH levels but the effect
was more pronounced in the group supplemented with 3% OPE
bread. It was observed that MDA levels were reduced by (21%)
in the liver of the 3% OPE treated group in comparison with the
diabetic control. Alongwith the significant improvement in GPx,
GR, and GSH levels, the similar group presented a prominent
threefold increase in SOD and CAT levels in the liver as com-
pared with the diabetic control group showing the restoration of
the altered antioxidant defense system near to the normal level.

Discussion

We observed a significant increase in the blood glucose level
with alloxan induction. This might be due to the destruction of
Langerhans islets β-cells by alloxan which also elevates oxi-
dative stress by compromising the intrinsic antioxidant mech-
anism and by increasing the production of free radicals [18,
49, 50]. Oxidative damage induced by reactive oxygen spe-
cies can promote negative consequences including uncon-
trolled hyperglycemia [51].

The rats’ body weights were reduced after induction of dia-
betes (Table 2). This kind of weight reduction was observed in
alloxan-induced diabetes in rodents [52]. The breakdown of
lipids stored in adipose tissues and the disruption of the skeletal
muscle proteins might have contributed to this weight loss [53].
When supplemented bread was added to the diet of alloxan-
induced diabetic rats, their body weight increased along with
their body’s ability to regulate blood glucose levels. However,
the effect was more significant in rats that were given bread
supplemented with 3% of onion peel extract.

The effect of onion supplementation in reducing blood glu-
cose level was also reported in some recent studies [54–56].
Phytochemicals such as quercetin and allyl-propyl disulfides
found in onion peel and bulb might be responsible for the
beneficial effect on blood glucose level by up-regulating the
expression of insulin receptors and glucose transporters, im-
proving insulin sensitivity and promoting glucose metabolism
in peripheral tissues in diabetic rats [13]. Kim et al. (2011) had
reported that supplementation of onion peel extract brought
significant reduction in blood glucose level by slowing down
the glucose absorption rate via inhibition of sucrase enzyme in
the intestinal tract [57]. The uptake of glucose is carried out by

series of events from binding by insulin to the receptors pres-
ent on cell surface, and later the ability of insulin to increase
glucose transport inside muscle tissue by GLUT [58]. Hence,
it is anticipated that phytochemicals present in onion might
improve insulin sensitivity by amending the insulin receptor
and glucose transporters expression and by promoting glucose
metabolism in peripheral tissues of diabetic rats [13]. In the
present research, both onion peel and onion powder supple-
mented breads brought reduction in blood glucose level.
However, it was observed that effect of even smaller percent-
ages of onion peel extract was more pronounced as compared
to the relatively higher percentages of onion bulb powder.
Previous studies have demonstrated that in vitro antioxidant

Fig. 1 Effects of onion peel extract and onion powder supplemented
bread on SOD (a) and CAT (b) activities in the liver and kidney
tissues of normal and experimental rats. NC= normal control, DC =
diabetic control, OPE_1 = group fed with bread containing 1% onion peel
extract, OPE_3 = group fed with bread containing 3% onion peel extract,
OP_5 = group fed with bread containing 1% onion powder, OP_7 =
group fed with bread containing 7% onion powder. *shows the
significant difference compared with the diabetic control group (p <
0.01) via Dunnett’s multiple comparison test, while ‘ns’ shows a non-
significant difference

J Diabetes Metab Disord



potential of onion peel is fairly high as compared to the inner
bulb [17, 59]. Phytochemicals such as quercetin, isorhamnetin
and kaempferol which possess strong antidiabetic potential
are much more abundant in the outer dry scales and fleshy
peels than the inner layers [60, 61] and this might be the
reason behind more potent antihyperglycemic and antioxidant
activity of the onion peel as compared to the bulb [62].

Among human subjects, few studies have been conducted
which demonstrated that Allium cepa possess strong potential in
lowering blood glucose level of normal subjects as well as dia-
betic patients [63–65], but antidiabetic potential of onion bulb and
onion peel extract has not been compared previously. Although,

the use of onion powder and the peel as food supplements has
been analyzed on basis of sensorial acceptability by trained panel
indicating a potential use of such supplemented breads in future
[66]. Therefore, current study serves as a steppingstone towards
the development of onion powder and peel based functional
foods. In the present research, the activities of studied enzymes
of the antioxidative defense system such as CAT and SOD were
significantly reduced while the level of malondialdehyde (MDA)
was increased in alloxan-induced diabetic rats. The manifestation
of oxidative stress occurs whenROS production increases abrupt-
ly, or the ROS-scavenging capacity of the body gets attenuated

Fig. 2 Effects of onion peel extract and onion powder supplemented
bread on GPx (a) and GR (b) activities in the liver and kidney tissues
of normal and experimental rats. NC= normal control, DC = diabetic
control, OPE_1 = group fed with bread containing 1% onion peel extract,
OPE_3 = group fed with bread containing 3% onion peel extract, OP_5 =
group fed with bread containing 1% onion powder, OP_7 = group fed
with bread containing 7% onion powder.*shows the significant
difference compared with the diabetic control group (p < 0.01) via
Dunnett’s multiple comparison test, while ‘ns’ shows a non-significant
difference

Fig. 3 Effects of onion peel extract and onion powder supplemented
bread on GSH (a) and MDA (b) levels activities in the liver and
kidney tissues of normal and experimental rats. NC = normal
control, DC = diabetic control, OPE_1 = group fed with bread
containing 1% onion peel extract, OPE_3 = group fed with bread
containing 3% onion peel extract, OP_5 = group fed with bread
containing 1% onion powder, OP_7 = group fed with bread containing
7% onion powder.*shows the significant difference compared with the
diabetic control group (p < 0.01) via Dunnett’s multiple comparison test,
while ‘ns’ shows a non-significant difference

J Diabetes Metab Disord



[67]. In the alloxan-induced diabetic rats, weak antioxidant enzy-
matic activities, elevated lipid peroxidation, and lowered non-
enzymatic antioxidant levels were reported in previous studies
[68–71]. To protect the body against ROS-mediated oxidative
damage, antioxidant enzymes are released including superoxide
dismutase (SOD), catalase (CAT), glutathione peroxidase (GPx),
and glutathione reductase (GR) [72].

In the present research, the studied antioxidative defense
system enzymes such as CAT and SOD displayed lower ac-
tivities in the evaluated kidney and liver tissues (Fig. 1) and
these results agreed with earlier published results [73, 74].
Excess blood glucose and recurrent non-enzymatic glycation
of proteins promote the generation of O2 and H2O2 and this
might be the reason behind the reduced activities of CAT and
SOD [75]. The limited activation of antioxidant enzymes due
to the presence of H2O2 and other hydrogen radicals was
recently reported [76]. Another reason behind the decreased
activity of CAT and SODmight be the reduction of the protein
expression levels that is a common phenomenon in hypergly-
cemia [77].

The activity of another important antioxidant enzyme, gluta-
thione peroxidase (GPx), was also reduced in the hepatic and
renal tissues of diabetic rats indicating impaired scavenging ac-
tivity of lipid hydroperoxides and H2O2. A similar finding was
observed in a previous investigation [78]. When diabetic rats
were fed with bread supplemented with onion peel extract or
onion powder, the altered activities of the antioxidant enzymes
such as SOD, CAT, GPx, and GR were significantly restored
(p < 0.01) (Figs. 1 and 2). The antioxidant potential of various
nutraceuticals such as quercetin, isorhamnetin, kaempferol, and
allyl-propyl disulfides might have contributed to this effect. All
these constituents previously showed a potent effect in reducing
blood glucose level and oxidative stress as well by modulating
various antioxidant enzymes in diabetic rats [79, 80].

Also, it was observed in our present study that the enzy-
matic activity of GR was significantly reduced in diabetic rats
due to a reduction in its production [81]. In groups receiving
3% of onion peel extract or 7% onion powder, the GR activity
was raised significantly (p < 0.01) as shown in Fig. 2. It was
previously reported that the plasma antioxidant capacity was
improved in diabetic rats following onion treatment [80].
Glutathione (GSH) also serves as a marker of oxidative dam-
age as it is an important non-enzymatic antioxidant agent in-
volved in preserving the integrity of the cellular systems [82].
The present study indicated that in the renal and hepatic tis-
sues of alloxan-induced diabetic rats, the GSH level decreased
(Fig. 3). The downfall in tissue GSH levels increases the pro-
gression of cellular damage initiated by free radicals. The
increased rate bywhich GSH is used in diabetic rats highlights
its important activity against ROS [83]. When diabetic rats
were fed with onion supplemented bread it restored the GSH
to almost normal levels (Fig. 3) but, the effect was more pro-
nounced in the 3% OPE group as compared with other groups

suggesting that onion peel extract can be beneficial against
oxidative stress. Previous studies indicated the potent antiox-
idant potential of onion towards increasing the GSH level and
upholding the antioxidant enzymatic activities within the nor-
mal range [84, 85].

Lipid peroxidation is another crucial factor that is strongly
associated with the integrity of cellular membranes and it helps
in evaluating the composition and structure of the tissue lipids.
In diabetes, the raised level of free radicals in certain tissues
may lead to a rise in the rate of lipid peroxidation [86]. Hence
malondialdehyde (MDA), which is a product of lipid peroxi-
dation wasmeasured in tissues of diabetic rats as an indicator of
the raised rate of lipid peroxidation in their kidneys and liver
[87]. Nonetheless, the elevated MDA level observed in the
tissues of alloxan-induced rats was found to be declined after
treatment with onion in the form of both onion peel extract as
well as onion bulb powder. Another benefit that is offered by
onion supplementation was the prevention of membrane lipid
peroxidation. Previous studies proved that onion possesses
strong hypolipidemic properties [88–91]. The observed decline
in the concentration of MDA and the overall improved antiox-
idant status in the onion peel extract and onion powder treated
diabetic rats highlights their strong potential against oxidative
stress and lipid peroxidation.

The current study suggested that both onion peel and bulb
may have beneficial effects against diabetes by lowering glucose
levels and suppressing oxidative stress when given in a certain
amount and this holds the hope of a new generation of functional
foods. Onion peel is commonly treated as agro-biowaste but it
contains useful phytochemicals that need the attention of the
scientific community as well as the food industry. However,
the present study has some limitations. The phenolic content
and antioxidant capacity vary among different onion varieties
[92] and the biochemical properties of different wheat flour
types can affect the final product. Therefore, standardization of
both the constituents is needed before any further in vivo exper-
imentation is planned to account for such variations. In earlier
studies, the concentration of various phenolic acids and flavo-
noids in onion extracts was determined by HPLC [93, 94].
Phenols possess weak thermal stability and the baking process
increases the amount of the free phenolic acids and decreases the
concentration of bound phenolic compounds [95, 96] and thus it
is recommended to assess the concentration of phytochemicals
in the developed bread samples as well. Moreover, the current
study also suffered from being an animal study, and the obtained
findings cannot be exactly applied in humans in varying states of
health and with diverse dietary patterns. Therefore, it is sug-
gested to conduct a human trial to examine the postprandial
metabolic and appetitive responses to the developed bread. If
similar findings are projected to human trials, it will open fasci-
nating possibilities for formulating frequently consumed foods
like bread with health-promoting effects.

J Diabetes Metab Disord



Appendix Authors contributions Conceptualization: Sara Masood, Shahid
Bashir, Muhammad Imran and Attiq ur Rehman, Methodology:
Sara Masood and Attiq ur Rehman, Software and Formal Analysis:
Attiq ur Rehman, Investigation: Sara Masood, Palwasha Khalil,
Faiza Iftikhar, Hafiza Madfiha Jaffar, Tara Khursheed, Resources:
SaraMasood, ShahidBashir,Muhammad Imran, Data curation: Sara
Masood, Palwasha Khalil, Faiza Iftikhar, Hafiza Madfiha Jaffar,
Tara Khursheed, Writing—original draft preparation: Sara Masood,
and Attiq ur Rehman, Writing—review and editing; Mohamed El
Shazly, Supervision: Shahid Bashir and Muhammad Imran, Project
administration: Shahid Bashir and Muhammad Imran. All authors
have read and agreed to the published version of the manuscript.

Funding Open access funding provided by Natural Resources Institute
Finland (LUKE).

Declarations

Conflict of interest On behalf of all authors, the corresponding author
states that there is no conflict of interest.

Open Access This article is licensed under a Creative Commons
Attribution 4.0 International License, which permits use, sharing, adap-
tation, distribution and reproduction in any medium or format, as long as
you give appropriate credit to the original author(s) and the source, pro-
vide a link to the Creative Commons licence, and indicate if changes were
made. The images or other third party material in this article are included
in the article's Creative Commons licence, unless indicated otherwise in a
credit line to the material. If material is not included in the article's
Creative Commons licence and your intended use is not permitted by
statutory regulation or exceeds the permitted use, you will need to obtain
permission directly from the copyright holder. To view a copy of this
licence, visit http://creativecommons.org/licenses/by/4.0/.

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Days DC NC OPE_1 OPE_1 OP_5 OP_7

Day 1 111 106 110 113 109 110
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	Masood et al 2021.pdf
	xMasood_etal_2021_
	Investigation...
	Abstract
	Abstract
	Abstract
	Abstract
	Abstract
	Introduction
	Material and Methods
	Animals
	Onion peel extract preparation
	Onion powder preparation
	Preparation of bread
	Induction of diabetes in rats
	Treatment groups

	Biochemical analysis
	Statistical analysis

	Results
	Effect of OPE and OP supplemented bread on the bodyweight of diabetic rats
	Effect of OPE and OP supplemented bread on blood glucose level of diabetic rats
	Effect of OPE and OP supplemented bread on the antioxidant enzyme activities and MDA levels of diabetic rats

	Discussion
	Appendix
	References