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1283 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1283-1291, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-47813 

HYDRATION METHODS AND PHYSIOLOGICAL POTENTIAL OF SWEET 
CORN SEEDS 

 
MÉTODOS DE HIDRATAÇÃO E POTENCIAL FISIOLÓGICO DE SEMENTES DE 

MILHO DOCE 
 
Jéssica de Lucena MARINHO1; Inês Cristina de Batista FONSECA1; Claudemir ZUCARELI1 

1. Universidade Estadual de Londrina/UEL, Departamento de Agronomia, Londrina, Paraná, Brasil. jlmarinho@live.com 
 
 

ABSTRACT: The evaluation of the physiological potential of sweet corn seeds is fundamental in the 
production process, because the germination and vigor reflect the potential for storage, commercialization and 
use of these seeds. The choice of vigor tests with an adequate and efficient analysis methodology is 
fundamental to obtaining reliable results. In this sense, the objective of this study was to assess the 
physiological potential of sweet corn seeds after hydration using different moistening methods to increase water 
content to 20%. First, the lot of seeds was characterized as to its moisture content and initial physiological 
potential. Subsequently, two experiments were conducted, both under a completely randomized design. In the 
first experiment, different volumes of water on the filter paper sheets were assessed for seed hydration a 
method that uses a wet substrate. In the second, four hydration methods were evaluated: wet substrate (WS), 
humid atmosphere (HU), immersion in water (IW) and addition of the required amount of water (WR). A 
constant temperature of 25ºC was used in both experiments and then the moisture content and physiological 
potential of seeds were determined. The humid atmosphere method reduces the physiological quality of sweet 
corn seeds because it favors the deterioration and hence is unsuitable for the hydration of seeds of this species. 
The wet substrate method, in an amount equivalent to 2.5 times the paper mass, increased the water content of 
sweet corn seeds to 20%, achieving the desired degree of moisture without altering their physiological 
potential. 
 

KEYWORDS: Germination. Moisture Content. Vigor. Zea mays convar. Saccharata. 
 
INTRODUCTION 

 
Sweet corn is a type of a special corn 

indicated for human consumption whose the seeds 
have specific characteristics (ALVARENGA; 
MARCOS FILHO; TIMÓTEO, 2013). They differ 
drastically from ordinary corn seeds regarding the 
structure and thickness of the pericarp and the 
chemical composition of the endosperm. These 
differences are due to the fact that sweet corn seeds 
have less amount of starch in their endosperm 
compared to ordinary corn seeds, due to the action 
of mutant alleles that prevent the conversion of 
monosaccharides (sugars) into polysaccharides 
(starch) (LUZ et al., 2014). 

The wrinkled aspect and the lower thickness 
of the pericarp of sweet corn seeds make them more 
susceptible to damage during the germination or 
vigor test procedures. This makes it more difficult to 
assess the quality of the seeds, since such damage, 
mostly physiological, such as imbibition damage 
(ALVARENGA; MARCOS FILHO; TIMÓTEO, 
2013), may underestimate the results obtained in 
seed tests that require previous moistening. 

Water absorption by seeds is a physical 
process, as it occurs also in dead seeds, and its 
purpose is the activation of metabolic activities, 
which result in the breakdown of the molecules, 
releasing the energy and nutrients necessary for the 
growth and development of the embryonic axis 
(MARCOS FILHO, 2015). However, accelerated 
imbibition caused by excess water in the substrate or 
by damage to the seed coat can lead to the 
disorganization of membranes and tissue rupture, 
which favors anaerobic respiration, leading to 
irreversible damage (ROSSETTO et al., 1997; 
ZUCARELI et al., 2008). 

The water potential of seeds has a direct 
impact on seed imbibition rate, and its definition 
considers the initial moisture content. The water 
potential of dried seeds is generally lower than that 
of the substrate used in the germination or vigor test 
and, therefore, there is movement of water 
molecules from the substrate into the seed 
(ZUCARELI et al., 2008). Therefore, due to the 
particularities of this species, the selection of a 
suitable substrate that does not contain excessive 
moisture, is very important, since studies on seeds 
from other species, e.g. beans, found that the 

Received: 08/04/19 
Accepted: 20/12/19 



1284 
Bioscience Journal  MARINHO, J. L. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1283-1291, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-47813 

substrate interferes with the availability of water 
and, consequently, with the speed and percentage of 
germination of seeds (SHIOGA; SILVA, 1998; 
GORDIN; SCALON; MASETTO, 2015). 

Vigor tests that require previous seed 
moistening and standardization of seed moisture 
content, such as tetrazolium and controlled 
deterioration, must be carefully investigated, so that 
the wetting process does not affect seed quality and 
do not underestimate the result obtained. Thus, the 
definition of an appropriate methodology for 
hydration, especially of seeds more susceptible to 
damage, is essential (ZUCARELI et al., 2008). 

Based on the aforementioned, Hampton; 
Tekrony (1995) recommended three alternative 
methods to prevent seed damage during 
standardization of moisture content: humid 
atmosphere, addition of the required amount of 
water or wet substrate. The selection of the most 
appropriate method depends to a large extent on the 
intrinsic characteristics of the seed such as chemical 
composition (reserve material) (BEWLEY et al., 
2013), permeability of the integument, area of 
contact of the seed (anatomy) (BECKERT; SILVA, 
2002) and the initial physiological quality 
(ZUCARELI et al., 2008). 

A moisture content around 20% has been 
used in different seed species to perform vigor tests 
that involve hydration, as in the controlled 
deterioration test (SILVA; VIEIRA, 2010; TORRES 
et al., 2012; TORRES et al., 2013). 

In their study on the physiological potential 
of ordinary corn seeds after being submitted to 
hydration through the methods of humid 
atmosphere, wet substrate, immersion in water and 
addition of the required amount of water under two 
temperatures, 20 and 30° C, Zucareli et al. (2011) 
found that the humid atmosphere method reduced 
the physiological quality of corn seeds and the 
method of direct immersion in water at 30º C did 
not impact the physiological quality of the seeds, 
being the most suitable for this purpose. 

Therefore, the present study aimed to assess 
the physiological potential of sweet corn seeds after 
hydration under different hydration methods to 
reach a 20% water content. 

 
MATERIAL AND METHODS 

 
The research was done at the Seed Analysis 

Laboratory of the Agronomy Department of State 
University of Londrina, in Londrina, Parana state. 

A lot of hybrid seeds of super sweet corn, a 
carrier of the shrunken (sh2) gene was used in the 
study. The lot was initially homogenized and then 

sampled for preliminary analyzes, which indicated 
the initial seed quality: 

Water content: determined with four 
replicates of 15 whole seeds, submitted to oven at 
105 ºC ± 2 ºC, for 24 hours, in accordance with the 
Rules for Seed Testing (BRASIL, 2009). 

Germination: conducted with four replicates 
of 100 seeds, on moistened germitest paper in an 
amount equivalent to 2.5 times the substrate (paper) 
mass at a temperature of 25 °C, with evaluation 
seven days after the installation of the test 
(BRASIL, 2009). 

First count: performed concomitantly with 
the germination test and using the same 
methodology, with evaluation on fourth day after 
sowing. 

Cold test: conducted through the method of 
rolled paper towel without soil, with four replicates 
of 100 seeds sown on moist germitest paper in an 
amount equivalent to 2.5 times its mass, and kept at 
10 °C for seven days, and at 25 °C for four days, for 
the count of normal seedlings. 

Accelerated aging: use of four replicates of 
120 seeds aged at a temperature of 42 ºC for 72 
hours. Four replicates of 15 seeds were used to 
determine the water content, and four replicates of 
100 seeds were submitted to the germination test, 
and count was performed four days after sowing 
(AOSA, 2009). 

Electrical conductivity: four replicates of 50 
seeds with the previously determined masses were 
imbibed in 25 mL of distilled water for a period of 
24 hours at 25 °C (PARERA et al., 1995). 

Length of normal seedlings: measurement 
began after the sowing of four replicates of 10 seeds 
per treatment, in the upper third of the germitest 
paper, kept in germinator for four days in darkness, 
at 25 ºC. Subsequently, the length of normal 
seedlings, separated in shoot and roots, was 
measured with the aid of a ruler graduated in 
centimeters. 

Dry mass of normal seedlings: assessed with 
the use of the normal seedlings obtained in the test 
of length, and these seedlings were separated into 
shoot and roots. The parts were oven dried with 
forced air circulation, at a temperature of 80 ºC ± 5 
ºC until reaching constant mass. Subsequently, the 
mass of seedlings was assessed for each replicate in 
precision scale. 

Emergence of seedlings in sand substrate: 
carried out using four replicates of 50 seeds, which 
were sown in sandboxes at a 5-cm depth. Fourteen 
(14) days after sowing, the number of emerged 
seedlings was counted, and the result was expressed 
in percentage. 



1285 
Bioscience Journal  MARINHO, J. L. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1283-1291, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-47813 

Rate of seedling emergence: conducted 
concomitantly with the emergence of seedlings in 
sand substrate, and counts were made daily from the 
emergence of the first seedling until the 14th day. 
Based on the number of seedlings emerged for each 
reading, the rates of seedling emergence (IVE) were 
calculated (MAGUIRE, 1962). 

The lot of sweet corn seeds showed high 
values of germination and vigor, being suitable for 

evaluation of hydration methods (Table 1), since 
lots of seeds with low physiological potential, 
especially those with percentages of germination 
lower than the minimum values established for 
commercialization, are not recommended for studies 
of methods of seed hydration (ZUCARELI et al., 
2008). 

 
Table 1. Characterization of moisture and initial physiological potential (germination and vigor) of the lot of 

sweet corn seeds used in the experiment 

U(%) 
G 

(%) 
FC 
(%) 

AS 
(%) 

DS 
(%) 

CT 
(%) 

AA 
(%) 

EC 
(µS/cm/g)    

SL 
(cm/pl) 

RL 
(cm/pl) 

DMS 
(mg/pl) 

DSR 
(mg/pl) 

ES 
(%) 

RSE        

7,99 91 79 6 3 56 78 156 3,30 8,01 9,20 6,99 91 4,32 
Legend: Plant (pl); moistening level (U); germination (G); first germination count (FC); abnormal seedlings (AS); dead seeds (DS); cold 
test (CT); accelerated aging (AA); electrical conductivity (EC); shoot length (SL); root length (RL); dry mass of shoot (DMS); dry mass 
of root (DMR); emergence of seedlings in sand substrate (ES); rate of seedling emergence (RSE). 
Source: data provided by the author 
 

Subsequently, two experiments were 
conducted to determine the best hydration method 
for sweet corn seeds. The experimental design used 
in both experiments was completely randomized. In 
the first experiment, five water contents were 
evaluated in the wet substrate, with four 
replications, to raise the moisture content to 20%: 
equivalent to 1.5; 2.0; 2.5; 3.0 and 3.5 times the 
paper mass. During moistening, seed rolls were kept 
in a germination chamber at 25 °C. 

In the second experiment, four hydration 
methods were evaluated: wet substrate (WS), humid 
atmosphere (HU), immersion in water (IW) and 
adding required amount of water (WR) to raise the 
moisture content of the seeds to 20%, under a 
constant temperature of 25 °C, with 6 replicates. 

The determination of the mass to be reached 
by the seeds to obtain a moisture content of 20% in 
both experiments was based on the initial mass and 
moisture of the seeds and was constantly monitored 
by weighing in analytical scale (HAMPTON; 
TEKRONY, 1995). 

In the wet substrate method, three sheets of 
germitest paper were used, which were moistened 
with water at an amount equivalent to 2.5 times the 
paper mass, and then paper rolls were prepared and 
kept in a sort of BOD (biochemical oxygen demand) 
determination test chamber at 25 °C until the seeds 
reached the predetermined mass. 

In the humid atmosphere method, each 
replicate was distributed over the metal screen of 
plastic boxes with a lid (11 cm × 11 cm × 3.5 cm), 
containing 40 mL of distilled water. The boxes were 
packed in plastic bags and kept in BOD chambers at 
a temperature of 25 °C until the seeds reached the 

mass previously determined for the moisture content 
of 20%. 

In the water immersion method, the seeds 
were placed in plastic containers and immersed in 
100 mL of distilled water, and the containers were 
kept in BOD at 25 ºC.  The water used for seed 
immersion was kept at the temperature used for the 
assay (25 °C). Before weighing, the seeds were 
dried superficially with paper towels for the 
monitoring of the mass obtained. 

For the method of addition of the required 
amount of water, the volume of water required to 
raise the moisture content to 20% was previously 
calculated, considering the mass and the initial 
water content of each replicate. The seeds were 
stored in plastic bottles with a lid (250 mL 
capacity), in which the volumes of distilled water 
were also calculated, and the bottles were kept in 
chambers regulated at a temperature of 25 ºC for 12 
hours. 

When the previously calculated mass was 
reached, the moisture content of ten seeds of each 
sample of the two experiments was determined, and 
the remainder was packed in sealed plastic bottles, 
which were kept in chambers at a temperature of 10 
°C for five days, for standardization of the moisture 
content (ZUCARELI et al., 2008). 

Subsequently, the moisture and the 
physiological properties of the seeds of the two 
experiments were determined through the following 
tests: first count of germination, germination test 
(normal, abnormal and dead seedlings), electrical 
conductivity, length of seedlings (separated in shoot 
and roots) and dry mass of seedlings (separated in 



1286 
Bioscience Journal  MARINHO, J. L. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1283-1291, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-47813 

shoot and roots), according to the previously 
described methodologies. 

The data obtained was submitted to the 
analysis of normality and homogeneity of variances 
by the Bartlett and Shapiro-Wilk tests, and for the 
germination and first count tests after the hydration 
methods, the data were transformed to square root 
√x. Subsequently, they were submitted to analysis 

of variance and the means were compared by Tukey 
test, at 5% of significance. 

 
RESULTS AND DISCUSSION 

 
Experiment 1:  water content in the wet substrate 

A significant effect of the different water 
contents on the substrate was observed only for the 
first count of germination, germination (normal 
seedlings) and electrical conductivity (Table 2). 

 
Table 2. Moisture level and physiological characteristics of sweet corn seeds imbibed with different volumes of 

water in paper substrate, through the wet substrate method. 

TREAT. 
U  

(%) 
G  

(%) 
FC 
(%) 

AS 
(%) 

DS 
(%) 

EC 
(µS/cm/g) 

SL 
(cm/plant) 

RL 
(cm/plant) 

DMS 
(mg/plant) 

DSR 
(mg/plant) 

1.5 19.68 88 ab 70 ab 5 8 113.71 a 4.10 7.38 8.50 5.50 
2.0 20.33 93 a 75 a 2 5 110.42 ab 3.53 7.25 6.82 4.75 
2.5 20.46 92 ab 73 a 2 7 104.29 b 3.13 7.38 7.40 4.52 
3.0 21.31 89 ab 67 ab 5 6 104.96 b 3.63 7.85 7.95 5.07 
3.5 20.54 87 b 62 b 5 8 116.71 a 3.10 7.40 6.25 4.97 

P-Value - 0.04 0.01 0.53 0.17 0.00 0.08 0.94 0.51 0.92 
CV (%) 2.62 3.01 6.46 42,16 27.11 3.56 14.71 13.91 26.36 31.13 
Means followed by the same letter in the column do not differ by Tukey test at 5% significance. Legend: treatments (TREAT.); 
coefficient of variation (CV); moistening level (U); Germination of normal seedlings (G); first germination count (FC); abnormal 
seedlings (AS); dead seeds (DS); electrical conductivity (EC); shoot length (SL); root length (RL); dry mass of shoot (DMS); dry mass 
of root (DMR). 
Source: data provided by the author. 

 
The wet substrate method with different 

water volumes in the paper was found to effectively 
adjust the seed moisture to a level of 20%, (Table 
2), considering that the difference in moisture 
content after hydration (1.63%) was lower than the 
maximum difference allowed, of 2 to 3%, ensuring a 
safe interpretation of the results (TOMES; 
TEKRONY; EGLI, 1988).   

Although all the treatments showed a 
germination rate higher than 70%, which is the 
minimum standard established for corn crop by 
Normative Ruling no 45 (BRASIL, 2013), the 
treatment consisting of a water volume equivalent to 
2.0 times the paper mass showed a percentage of 
germination higher than the other treatments and 
higher than the percentage of initial germination 
(Table 2). The germination rate obtained with 
addition of a water volume equivalent to 2.5 times 
the paper mass, although not different from the 
germination rates after addition of water contents of 
1.5 and 3.0, also showed a germination value above 
the initially obtained level. Thus, these two water 
contents in the substrate were suitable for the 
activation of membrane repair mechanisms and 
enzymatic activation without causing physiological 
damage (ZUCARELI et al., 2008), which 
accelerated the degradation of reserves and favored 

the formation of normal seedlings. The higher 
germination speed, represented by the values of the 
first count, confirms the greater effectiveness of the 
treatments with water volumes equivalent to 2.0 and 
2.5 times the paper mass compared to the others. 

On the other hand, the treatment with water 
volume corresponding to 3.5 times the paper mass 
showed a germination rate lower than the rates of 
the other treatments, and of the initial germination 
rate. The excess water in the substrate associated 
with the reduced water potential of the seeds may 
have caused accelerated imbibition, which causes 
tissue ruptures and membrane disorganization 
(ROSSETTO et al., 1997; ZUCARELI et al., 2008) 
and reduces the germination rate. Moreover, excess 
water on paper may have caused deficiency in 
oxygen supply, which is essential for germination. 
During imbibition, embryonic respiratory activity is 
intensified to supply energy to the metabolic 
processes responsible for the development of the 
embryonic axis, and oxygen is essential for these 
reactions. An excessive amount of water limits 
oxygen uptake, reducing respiration and retarding 
germination (TANAKA; MARIANO; LEÃO, 
1991), which can be confirmed by the lower 
germination rate demonstrated in the first count of 



1287 
Bioscience Journal  MARINHO, J. L. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1283-1291, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-47813 

the treatment of addition of a water volume 
equivalent to 3.5 times the paper mass (Table 2). 

As for the lower germination rates caused 
by high water contents in the substrate, as observed 
in this study, Silva; Carvalho (2008), in their study 
of faveira (Clitoria fairchildiana) seeds of different 
sizes, under four moistening levels of sand substrate 
(25%, 50%, 75% and 100% of retention capacity) 
found that excess water imbibition reduced 
germination rates. This can be related to the increase 
of anaerobic respiration, which causes the death of 
tissues due to the greater production of toxic 
substances. 

In their study of the effects of two substrates 
(germitest paper and blotter paper) and six water 
volumes (equivalent to 1.5; 2.0; 2.5; 3.0; 3.5; 4.0 
times the paper mass) on the germination of soybean 
seeds, with germination conducted on germitest 
paper, Jacinto; Benett; Benett (2014) found that the 
use of higher water volumes to moisten the substrate 
caused a linear reduction in the percentage of 
normal seedlings. For a water content equivalent to 
3.5 times the paper mass, the authors obtained the 
lowest percentages of germination, corroborating 
the results of this study. However, the opposite was 
observed in the germination test conducted on 
substrate between blotter paper, which demonstrates 
the impact of the substrate on the availability of 
water for the seeds, as well as the need for studies 
on other substrates or hydration methods that are 
more suitable and cause less damage to corn seeds. 

The electrical conductivity values observed 
in all treatments after moistening (Table 2) were 
lower than the initial electrical conductivity of the 
lot (Table 1), possibly due to the influence of the 
water content of the seeds on the test results. The 
lower the water content, the greater the 
disorganization of the membranes and, 
consequently, the greater the release of solutes, 
which increases the electrical conductivity value. 
Moreover, after imbibition, the membranes are 
reorganized, which minimizes the release of 
exudates (VIEIRA; KRZYZANOWSKI, 1999). 
Also, according to Zucareli et al. (2008), these 
lower values after hydration may also be associated 
with the loss of leachates during the moistening 
period that are transferred from the seed to the 
substrate, which subsequently reduced the amount 
of these electrolytes released to the imbibition 
solution. 

The water volumes equivalent to 2.5 and 3.0 
times the paper mass were more effective than the 

other treatments, because they had lower values of 
electrical conductivity, indicating that the 
membranes are more organized and have higher 
quality and, consequently, greater vigor. The higher 
electrical conductivity values detected in the 
treatment containing the highest amount of water in 
the substrate (3.5 times the paper mass) may be 
related to damage or ruptures in the membranes due 
to accelerated imbibition caused by the higher water 
content in the paper, which demonstrates the lower 
vigor of seeds submitted to hydration through this 
method (CARVALHO; NAKAGAWA, 2012; 
MARCOS FILHO, 2015). 

The treatment with the lowest water content 
in the paper (equivalent to 1.5 times the substrate 
mass), extended the time required for the seeds to 
reach the expected water content, and during this 
period the seeds were exposed to unfavorable 
conditions that may have accelerated the aging 
process, producing a negative impact on their 
physiological quality (VILLELA; MARCOS 
FILHO; NOVEMBRE, 2003).  

In general, in the wet substrate method (on 
germitest paper), the proportions of water content 
equivalent to 2.0 and 2.5 times the paper mass were 
found to be suitable for the hydration of sweet corn 
seeds, because they allow water uptake and increase 
the moisture level without damage that might impair 
the physiological potential of the seeds, 
corroborating the results obtained by Zucareli et al. 
(2008) for ordinary corn. However, since the 
amount of water equivalent to 2.5 times the paper 
mass has been widely used as reference for several 
species, and has shown slightly higher results, this 
amount is more suitable for the hydration of sweet 
corn seeds. However, other hydration methods 
should be evaluated to demonstrate the efficiency of 
the method that uses a wet substrate moistened with 
water equivalent to 2.5 times the paper mass. 

Experiment 2: Methods for moistening 
sweet corn seeds 

According to analysis of variance of the 
physiological characteristics of the seeds (Table 3), 
there was a significant effect of the treatments for 
the variables investigated, except for root length. 

The methods assessed effectively increased 
the moisture content of the seeds to 20%, and the 
maximum variation observed was 0.91 percentage 
point, which ensures uniformity and minimizes the 
impact of moisture in the comparisons of the effects 
of the different methods. 

 
 



1288 
Bioscience Journal  MARINHO, J. L. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1283-1291, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-47813 

Table 3. Moisture level and physiological characteristics of imbibition of sweet corn seeds using different 
hydration methods. 

TREAT. 
U 

(%) 
G 

(%) 
FC 
(%) 

AS 
(%) 

DS 
(%) 

EC 
(µs/cm/g) 

SL 
(cm/plant) 

RL 
(cm/plant) 

DMS 
(mg/plant) 

DMR 
(mg/plant) 

HU 21.1 76 b 48 c 14 a 10 a 166.61 a 4.08 a 8.24 11.12 a 8.18 b 

WS 20.8 88 a 75 a 8 b 4 bc 116.02 b 4.02 a 9.17 11.34 a 8.81 ab 

IW 20.8 92 a 61 b 6 b 3 c 142.32 ab 3.05 b 8.43 877 b 10.98 a 

WR 20.2 74 b 53 bc 18 a 8 ab 172.35 a 3.44 ab 8.66 8.93 b 10.06 ab 

P-Value - 0.00 0.00 0.00 0.00 0.01 0.00 0.43 0.00 0.01 

CV (%) 2.82 2.81 5.13 16.37 43.05 19.86 11.47 11.63 11.69 14.81 
Means followed by the same letter in the columns do not differ by the Tukey test at 5% significance. Legend: Treatments (TREAT.); 
humid atmosphere (HU); wet substrate (WS); direct immersion in water (IW); addition of required amount of water (WR); coefficient of 
variation (CV); degree of humidity (U); germination of normal seedlings (G); first germination count (FC); abnormal seedlings (AS); 
dead seeds (DS); electrical conductivity (EC); shoot length (SL); root length (RL); dry mass of shoot (DMS); dry mass of root (DMR). 
Source: information provided by the author. 
 

The methods tested resulted in germination 
values higher than 70%, which is the minimum 
standard established by Normative Ruling no. 45 
(BRASIL, 2013). However, the wet substrate 
method and direct water immersion methods were 
the most effective because their values for 
germination, abnormal seedlings and dead seeds 
were similar to those observed in the seeds before 
imbibition (Table 1), which indicates the best 
quality of the seeds submitted to hydration through 
these processes. 

On the other hand, the methods addition of 
required amount of water and, again, humid 
atmosphere showed the lowest percentages of 
germination due to the greater number of abnormal 
seedlings and dead seeds, with the number of 
abnormal seedlings higher than the number of dead 
seeds. These two methods reduced the physiological 
potential of the seeds, either by causing imbibition 
damage to the membranes, in the method of addition 
of the required amount of water (HAMPTON; 
TEKRONY, 1995), or by accelerating the aging 
process due to the long imbibition period, in the 
humid atmosphere method (VILLELA; MARCOS 
FILHO; NOVEMBRE, 2003). 

According to Villela; Novembre; Marcos 
Filho (2007), degradation of proteins and insoluble 
carbohydrates, in seeds with reduced physiological 
potential, is detrimental to vigor and germination, 
since these compounds are responsible for water 
uptake. Thus, increasing the moisture content of 
seeds through inadequate methods that accelerate 
deterioration processes, such as humid atmosphere 
and addition of the required amount of water, reduce 
not only vigor but also the normal ability of seeds to 
germinate. 

The wet substrate method showed the 
highest value of first count of germination, which 

was also the closest to the value of first count of 
germination of the lot of seeds not initially hydrated 
(Table 1). Thus, this method is suitable for seed 
moistening, as it does not have a negative impact on 
germination speed. The other methods showed 
lower values for this variable, with emphasis on the 
humid atmosphere method, which may be related to 
the long period required to raise the water content, 
in which the seeds are exposed to a high degree of 
humidity that accelerates the aging processes 
associated with the water content (VILLELA; 
MARCOS FILHO; NOVEMBRE, 2003). 

The wet substrate method showed lower 
values of electrical conductivity, followed by the 
water immersion method, which did not differ 
statistically from the others. On the other hand, the 
methods of addition of the required amount of water 
and humid atmosphere provided higher conductivity 
values. Regarding electrical conductivity, the lower 
the value, the higher the quality of the seed; and the 
higher the value, the greater the degree of 
deterioration of the lot because of the greater 
amount of exudates released by the membrane. 

According to Silva; Rosseto (2012), the 
higher conductivity value obtained for seeds 
submitted to the humid atmosphere method may be 
related to slow imbibition of seeds in this procedure, 
due to the lower availability of water vapor, which 
prolongs the time of exposure of the seeds to a 
humid atmosphere, favoring deterioration. On the 
other hand, adding the required amount of water 
may result in imbibition damage to the membranes, 
which, according to Hampton; Tekrony (1995), is 
one of the limitations of this method. This 
characterizes the beginning of the degenerative 
changes in the seeds and culminates in their lower 
vigor (DELOUCHE, 2002), as demonstrated in the 
electrical conductivity test. 



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Biosci. J., Uberlândia, v. 36, n. 4, p. 1283-1291, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-47813 

Regarding the length of the shoot, the 
methods wet substrate and humid atmosphere 
showed the highest values, followed by the method 
of addition of the required amount of water, which 
did not differ statistically from the previous ones nor 
from the water immersion method, the latter being 
the one with the lowest value. Regarding root 
length, no significant difference was observed 
between the methods investigated. However, the wet 
substrate method presented the highest value for this 
characteristic, standing out positively from the 
others. 

A higher dry shoot mass was obtained with 
the methods wet substrate and humid atmosphere. 
Regarding the dry mass of roots, a higher value was 
obtained with the water immersion method. 
However, the methods wet substrate and addition of 
the required amount of water did not differ 
statistically from the water immersion method, nor 
from the humid atmosphere method, which showed 
the lowest value. 

In a study of four hydration methods (wet 
substrate, humid atmosphere, immersion in water 
and addition of the amount of water required) to 
raise the moisture content of corn seeds, Zucareli et 
al. (2011) found that the humid atmosphere method 
reduced the physiological potential of the seeds, 
corroborating the results obtained for the different 
characteristics assessed in the present study. On the 
other hand, the authors found that a temperature of 
30 °C and the method of direct immersion in water 
did not alter the physiological quality of ordinary 
corn seeds, being suitable for the hydration of these 
seeds, diverging from the results of this study. 

Silva; Rosseto (2012), in their assessment of 
the physiological quality of sunflower seeds after 
hydration through the humid atmosphere and wet 
substrate methods at temperatures of 10 and 20 °C, 
found that the method of wet substrate at 10 °C 
effectively raised the moisture content, similarly to 
the results obtained here, except for the temperature. 
However, for sunflower, seedling vigor was 
reduced. 

Of all the procedures analyzed, the wet 
substrate method showed results higher than or 
statistically equivalent to the results of the other 
methods for all the variables analyzed. In addition, 
this method has not adversely affected the 
physiological potential of the seeds and can be 
considered fast and easy to perform, which is 
essential for large-scale use. On the other hand, the 
method of humid atmosphere is time consuming and 
reduced the physiological potential of the seeds. 
Thus, it is unsuitable for raising the moisture 
content of sweet corn seeds. 

 
CONCLUSIONS 

 
The humid atmosphere method reduces the 

physiological potential of sweet corn seeds and is 
unsuitable for the hydration of seeds of this species. 

The wet substrate method, in an amount 
equivalent to 2.5 times the paper mass was suitable 
for raising the moisture content of sweet corn seeds 
to 20%, by allowing the desired degree of moisture 
to be obtained without altering the physiological 
potential of the seeds. 

 
 

RESUMO: A avaliação do potencial fisiológico de sementes de milho doce é fundamental no processo 
de produção, pois a germinação e o vigor refletem o potencial de armazenamento, comercialização e utilização 
dessas sementes. A escolha de testes de vigor com uma metodologia de análise adequada e eficiente é 
fundamental para a obtenção de resultados confiáveis. Nesse sentido, o objetivo deste estudo foi avaliar o 
potencial fisiológico de sementes de milho doce após hidratação sob diferentes métodos de umedecimento, 
visando elevar o teor de água para 20%. O lote de sementes foi caracterizado quanto a umidade e o potencial 
fisiológico inicial. Posteriormente, foram conduzidos dois experimentos, ambos sob delineamento inteiramente 
casualizado. No primeiro, foram avaliadas diferentes quantidades de água no papel para hidratação das 
sementes pelo método do substrato úmido. No segundo, foram avaliados quatro métodos de umedecimento: 
substrato úmido (WS), atmosfera úmida (HU), imersão em água (IW) e adição da quantidade de água requerida 
(WR). Em ambos experimentos foi utilizada temperatura constante de 25ºC e, posteriormente, foram 
determinados a umidade e o potencial fisiológico das sementes. O método da atmosfera úmida reduz a 
qualidade fisiológica das sementes de milho doce pois favorece a deterioração, sendo inadequado para a 
hidratação de sementes desta espécie. O método do substrato úmido, na proporção de 2,5 vezes a massa do 
papel em água, mostrou-se adequado para a elevação do teor de água de sementes de milho doce para 20%, por 
permitir a obtenção do grau de umidade desejado sem alterar o potencial fisiológico. 
 

PALAVRAS-CHAVE: Germinação. Teor de Água. Vigor. Zea mays convar. Saccharata. 
 



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Biosci. J., Uberlândia, v. 36, n. 4, p. 1283-1291, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-47813 

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