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1246 
Original Article 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1246-1253, Sept./Oct. 2016 

RESPIRATORY ACTIVITY IN WHEAT SEEDS AS RELATED TO 
PHYSIOLOGICAL QUALITY 

 

 
ATIVIDADE RESPIRATÓRIA EM SEMENTES DE TRIGO CORRELACIONADA COM 

A QUALIDADE FISIOLÓGICA 
 

Juliana DODE
1
; Andréia da Silva ALMEIDA

2
; Cristiane DEUNER

2
; 

 Carolina Terra BORGES
2
; Géri Eduardo MENEGHELLO

2
; Francisco Amaral VILLELA

2
; 

Dario Munt de MORAES
3 

1. Cerest Macrosul Pelotas - Centro de Referência em Saúde do Trabalhado, Pelotas, RS, Brasil; 2. PPG em Ciência e Tecnologia de 
Sementes, Faculdade de Agronomia Eliseu Maciel, Universidade Federal de Pelotas, Pelotas, RS, Brasil. cdeuner@yahoo.com.br; 3. 

Departamento de Botânica, Instituto de Biologia, Pelotas, RS, Brasil. 
 

ABSTRACT: Seeds are a very important input for crops, and the use of low quality seeds and/or inadequate 
management affects the germination and hampers seedling emergence, which reduces the plant stand. There is a critical 
need for the development of rapid methods, which are both reliable and easy to perform, for evaluating the physiological 
potential of seeds. This would streamline the decision-making process regarding the management of lots and allow for the 
identification of seed lots of inadequate quality in the seed processing unit, which could then be discarded, and would 
consequently result in reduced costs associated with unnecessary processing. However, it is important that these methods 
are low cost and quick to perform. The aim of this study was to evaluate the correlation of respiratory activity of wheat 
seed, through Pettenkofer test, with tests that evaluate seeds physiological quality. We selected a seed lot of high 
physiological quality, then subjected the seeds to adverse temperature and relative humidity conditions to obtain different 
vigor levels. The adverse conditions used were 42ºC and 100% relative humidity, for periods of 6, 36, 66 and 96 hours. 
This process obtained seeds of five vigor levels which were subjected to the following tests: germination, field emergence, 
electrical conductivity, shoot and root length, total dry mass and respiratory activity. The results showed a negative 
correlation between respiratory activity and germination, emergence, shoot and root length and dry weight, whereas 
germination and emergence were strongly correlated with respiratory activity, r = -0.86 and r = -0.81, respectively. There 
was a significant positive correlation between conductivity and respiratory activity. Therefore, the respiratory activity test 
using the Pettenkofer method was correlated with other vigor tests, and allowed the classification of wheat seeds into lots 
of different levels of quality. 
 

KEYWORDS: Triticum aestivum L. Pettenkofer method. Vigor. 
 
INTRODUCTION 

 
Wheat (Triticum aestivum L.) grass is 

grown worldwide and is the second largest cereal 
crop, being of great importance for human and 
animal nutrition. In Brazil, the cultivation area for 
wheat is 2.5 million hectares, particularly in the 
states of Rio Grande do Sul and Paraná, with the 
production of 1919 and 169 thousand tons, 
respectively (CONAB, 2015). 

Seeds are an important input for the crop, as 
the use of high quality seeds provide a more rapid 
and uniform emission of the primary root during 
germination, producing seedlings with a larger 
initial size which results in higher growth and grain 
yields (MIELEZRSKI et al., 2008; MUNIZZI et al., 
2010).  

The term "seed quality" involves physical, 
physiological and sanitary characteristics, and when 
these characteristics are examined together they 
provide an indication of the value and the potential 
use of a seed lot. Germination and vigor tests are 

used to evaluate the physiological quality of seeds 
(MARCOS FILHO, 2005). 

One characteristic to be considered during 
the germination test is the time period for its 
performance, which requires between 7 and 28 days 
to obtain the results for most species. The length of 
this period determines the commercial interest in the 
seeds. In contrast, the vigor of the seed, which is the 
sum of all attributes which favor the rapid and 
uniform stand establishment in the field 
(DELOUCHE; CALDWELL, 1960), provides more 
rapid results. However, the seed quality cannot 
always be completely rated by only one test, 
therefore, it is recommended to use various different 
tests to give a better idea of the physiological 
quality of a seed lot (SCHEEREN et al., 2010).  

Rapid methods, which are both reliable and 
easy to perform, are required for the evaluation of 
the physiological potential of the seeds, in addition 
to streamlining the decision-making process 
regarding the management of lots (MERTZ et al., 
2012). Quicker evaluation methods would allow 

Received: 27/01/16 
Accepted: 06/06/16 



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seed lots of inadequate quality to be discarded in the 
seed processing unit, which would consequently 
saving on costs from unnecessary processing 
(MARCOS FILHO, 1999). 

Martins et al. (2014) evaluated the 
separation of seed lots by their respiratory activity 
and concluded that it was an efficient method for the 
separation of soy and bean seed lots of different 
vigor levels. Similar results have also been reported 
for cotton seeds (VENSKE et al., 2014). 
Furthermore, as shown in a study by Marini et al. 
(2013), respiratory activity is indicative of reduced 
seed quality and can be used to identify factors 
which are related to seed deterioration. 

This study aimed to evaluate the efficiency 
of the Pettenkofer method for the determination of 
respiratory activity, in order to differentiate between 
differences in the physiological quality of wheat 
seed lots. We also aimed to determine the 
correlation between respiratory activity and other 
vigor tests.  

 
MATERIAL AND METHODS 

 
The study was conducted in the Seed 

Laboratory and Greenhouse of the Federal 
University of Pelotas, Brazil. Wheat seeds from the 
CD 115 cultivar were obtained from the 
Agricultural Research Center of Temperate Climate 
(CPACT, EMBRAPA). 

A seed lot with 94% germination was 
selected and subjected to adverse temperature and 
relative humidity conditions to obtain different vigor 
levels. The seeds were distributed in single layer on 
a stainless steel screen surface, which was installed 
inside gerbox-type plastic boxes. Water (40 mL) 
was added to each individual compartment. The 
boxes were capped and maintained in a BOD 
(Biochemical Oxigen Demand) incubator chamber 
at 42°C for either 6, 33, 66 or 96 hours. Five vigor 
levels were obtained from this process, and each 
vigor level was divided into four sections, which 
were the replicates. 

The physiological quality and respiratory 
activity of the lots were evaluated with the 
following tests: germination, field emergence, 
electrical conductivity, shoot and root length of the 
seedlings, total dry mass and respiratory activity.  
 
Germination test  

The germination test (G) was performed 
with four groups of 200 seeds (four subgroups of 
50), totaling 800 seeds per wheat seed lot. The seeds 
were distributed in germitest paper rolls which were 
moistened with distilled water at a ratio of 1:2.5 

w/v, then maintained until germination at a 
temperature of 20 °C. Germination was evaluated on 
the fourth and eighth day after sowing, consistent 
with the method described by the Regras para 
Análises de Sementes-RAS (BRASIL, 2009), and 
the results were expressed as a percentage of normal 
seedlings.  
 
Field emergence  

The field emergence (FE) test used four 
groups of 50 wheat seeds per lot, totaling 200 seeds, 
which were sown in furrows 2 m in length and 5 cm 
deep. The results were expressed as the number of 
emerged seedlings 21 days after sowing. 
 
Electrical conductivity  

The electrical conductivity (EC) test used 
four groups of 50 seeds from the pure seed fraction, 
totaling 200 seeds per lot. The samples were 
weighed on a precision scale then placed for soaking 
in a plastic cup containing 75 mL of deionized 
water, shaken gently so that all seed were 
completely submerged, then kept in a germination 
chamber at 25°C. Two readings were performed, 
one after 3 hours of soaking and another after 24 
hours. The EC measurements were taken using a 
conductivimeter (CD-21, Digimed), and the results 
were expressed as µS m-1 g-1 of seed (AOSA, 1983). 
 
Length of the shoot and root of the seedlings  

The length of the shoot (LS) and length of 
the root (LR) of the seedlings were measured as the 
average length of the aerial part and roots of normal 
seedlings obtained after sowing of four replicates of 
10 seeds. The paper rolls containing the seeds 
remained in a germination chamber at 20°C for 7 
days, after which the length of the seedlings was 
measured with a millimeter ruler. The values 
obtained for LS and LR were divided by the number 
of seedlings, and the results expressed as mm 
seedlings-1, according to Nakagawa (1999). 
 
Total dry mass  

The total dry mass (TDM) of the same 10 
seedlings from each replicate was measured after 
placing the seedlings in a forced air oven at 70 ± 
2°C to determine the constant mass. The results 
were expressed in mg seedling-1. 
 
Respiratory activity  

The respiratory activity (RA) of the seeds 
was measured by determining the CO2 released by 
the seeds with Pettenkofer equipment, which 
consisted of four gas washing flasks. Two of the 
flasks contained sodium hydroxide (NaOH) at 25% 



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Biosci. J., Uberlândia, v. 32, n. 5, p. 1246-1253, Sept./Oct. 2016 

to retain CO2 from the ambient air, one flask was 
used to store seeds in an environment free from CO2 
in the ambient air, and another contained barium 
hydroxide Ba(OH)2 at 25%, which reacts with CO2 
produced from the respiratory activity of seeds to 
produce barium carbonate (BaCO3). The flasks were 
connected with a silicone hose which was connected 
to an air suction tube. The air flow was regulated 
with a tap which allowed the speed to be controlled 
through the observation of bubbles formed in the 
flasks. 

Seeds from the different lots (100 g) were 
placed in the storage flask for 60 minutes at 25°C. 
After the measurement period, five aliquots of 10 
mL were collected from the BaCO3 solution in an 
Erlenmeyer flask. Two drops of phenolphthalein 
reagent was placed in each flask, then titration with 
hydrochloric acid (HCl) 0.1 N was performed in a 
50 mL burette. At the turning point, the HCl volume 
for each aliquot was recorded. This volume, which 
was directly related to the amount of CO2 fixed by 
the Ba(OH)2 solution, was used to calculate the 
respiratory activity of the seeds, measured as the 
fixed CO2 produced from respiration. However, it 
should be noted that the calculated amount is the 
CO2 content of the titrated aliquot. 

Measurement of the respiratory activity of 
seeds was performed using the method described by 
Mendes et al. (2009), with some modifications. The 
calculation of respiratory activity was based on the 
following equation: RA = N × D × 22 (MÜLLER, 
1964), where N is the normality of the acid (HCl; 
0.1 N), D is the difference between the volume of 
HCl used in the blank titration and the volume of 

HCl used in the sample titration and 22 is the 
normality value for CO2. The result was expressed 
as the quantity of CO2 released per gram of seed per 
hour (µ g CO2 seed g

-1 h-1).  
 
Experimental design and statistical analysis 

This study used a completely randomized 
experimental design with four replicates in each 
group. The data obtained for each variable was 
subjected to analysis by analysis of variance 
(ANOVA) with Tukey’s post-hoc test at a 5% 
probability level. The data obtained from the 
germination tests, including the first counts for 
germination and field emergence were transformed 
into arcsen √x/100. Simple correlation analyses was 
performed for each of the vigor tests with seed 
respiration. 

 
RESULTS AND DISCUSSION 

 
The results from the germination, field 

emergence, electrical conductivity, measurement of 
shoot and root length, total dry mass and respiratory 
activity tests are shown in Table 1. Significant 
differences were found between the results for seed 
lots of different vigor levels. The results from the G 
test differed between lots over the five vigor levels, 
with the highest percentage of germination observed 
for lot 1 and the lowest observed for lot 5. In the FE 
test we were able to separate the lots into four of the 
five possible levels, and the difference between lot 1 
and 4 was 27 percentage points (pp), however, the 
difference between the maximum and minimum 
germination was 42 pp. 
 

Table 1. Germination (G), field emergency (FE), electrical conductivity (EC) with three and 24 hours of 
soaking, length of shoot part and root (LS; LR), total dry mass (TDM) and respiratory activity (RA) 
of five wheat seed lots, cultivar CD115. 

 
Lots 

 
G 

(%) 
FE 
(%) 

 
EC (µ S m-1 g-1) 

 
LS (mm 

seedling-1) 
LR (mm 

seedling-1) 

 
TDM (mg 
seedling-1) 

RA  
(µg CO2 g

-1 
seed) 

 
3h 

 
24h 

1 94 a 96 a 10,8 a   21,6 bc 95 a 67 a 0,4 a       0,3 a 
2 89 b 90 b 10,9 a 20,5 c  90 ab 72 a 0,2 b  0,9 ab 
3 79 c 86 b  11,3 ab   21,1 bc 81 b 66 a 0,1 c  1,1 ab 
4 59 d 79 c  12,6 bc 24,2 b 68 c 60 a  0,09 cd  1,8 bc 
5 40 e 54 d 13,6 c 28,4 a 31 d 34 b 0,04 d 2,3 c 

CV 
(%) 

 2,79 2,76 5,99 6,33 7,43 18,17 22,68     17,18 

*Averages followed by the same letter in the column do not differ to each other by Tukey test at 5% of probability. 
 

The electrical conductivity detected after 
three hours of soaking showed that lots 1 and 2 were 
the highest quality due to reduced leaching of 

exudates to the soaking medium. However, after 24 
hours of soaking, lot 2 was classified as being the 
highest quality. For both periods (3 and 24 hours), 



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the EC test was sensitive enough to detect that lot 5 
was the lowest quality compared to the other 
evaluated lots. 

The EC test has been recognized as an 
effective way to evaluate seed vigor in various 
species, including black oats (MENEZES et al., 
2007), popcorn (RIBEIRO et al., 2009) and white 
oats (SPONCHIADO et al., 2014). However, this 
was not found to be an efficient option for 
determining quality differences between sorghum 
seed lots (SOARES et al., 2010) or castor bean seed 
lots (MENDES et al., 2010) of different vigor 
levels. In some cases, the failure of this test has been 
attributed to the genotype, which is associated with 
differences in seed coat characteristics, allowing 
different amounts of leachate to be released 
(MARCOS FILHO, 2005). 

According to Perry (1977), the seedling 
length indicates the activity level and metabolism 
coordination of germination, and therefore, the vigor 
of the seed. The shoot length results are presented in 
Table 1, where lots 1, 2 and 3 were determined to 
have high vigor, lot 4 was medium and lot 5 was 
low vigor. However, only lot 5 was lower than the 
others for root length. In general, the process of 
evaluating the vigor of a seed lot is completed using 
various tests, each of which have different rating 
systems. In this study it did not appear that root 
development was affected by the detrimental 
conditions as much as the development of other 
parts, e.g. the shoot.  

The results for dry mass allowed for the 
separation of lots according to vigor levels, where 
lots 1 and 2 were the highest quality and lot 5 was 
the lowest, confirming the results found for the tests 
of field emergence, electrical conductivity and 
length of shoot. Bortolotto et al. (2008) also 
observed that lots of two cultivars of rice seeds were 
able to be stratified using the dry mass test. 
Conversely, Braz and Rossetto (2009) observed that 
the dry mass test was not able to differentiate 
between five lots of sunflower seeds, however, lots 
were able to be differentiated in other tests, such as 
the field emergence test. 

 Similarly, the test of respiratory activity 
was an efficient test for the separation of lots into 
three levels, with lot 1 considered to be high vigor, 
lot 5 to be low vigor and lots 2, 3 and 4 to be 
medium vigor. For the germination, field 
emergence, shoot length and seedling dry mass 
tests, lot 1 was found to be superior to the others. 

According to Delouche and Baskin (1973), 
the deterioration of seeds occurs gradually, 
manifesting in a sequence of events of biochemical 
or physiological origin, such as damage to the 
membrane permeability systems. This is the first 
deterioration event to appear, and has a strong 
relationship with the respiratory rate of the tissues, 
including changes in enzymatic activity, a decrease 
in tissue reserves, reduced speed and capacity of 
germination and decreased growth of normal 
seedlings. Therefore, deteriorated wheat seeds have 
reduced vigor and increased respiratory activity. 

The results from the RA test are in 
agreement with the hypothesis of Amaral and Peske 
(1984), who suggested that deteriorated seeds 
release greater amounts of solutes and CO2 than high 
quality seeds. It is also consistent with the work of 
Bopper and Kreese (2010), emphasizing that lower 
quality seeds consume less oxygen in the early 
stages of the germination process. 

In contrast, Mendes et al. (2009), noted that 
when rice and soybean seeds were soaked in water 
for one hour, the respiratory activity was higher 
with increasing levels of lot vigor. Following seed 
rehydration, the initial metabolic activity is an 
increase in respiration, which increases from 
extremely low to high levels shortly after imbibition 
begins (POPINIGIS, 1985; FERREIRA; 
BORGHETTI, 2004). 

When the relationship between respiratory 
activity and the other tests for evaluating the 
physiological quality of wheat seeds were compared 
(Table 2), a negative correlation was found between 
respiratory activity and the results from the 
germination, emergence, shoot and root length and 
dry mass results, whereas the results from the 
germination and field emergence tests were strongly 
correlated, r = -0.86 and r = -0.81, respectively. On 
the other hand, the length of the root had a lower 
correlation (r = -0.59). Dode et al. (2013) and 
Marini et al. (2013) also showed a negative 
correlation between respiration and vigor for 
sunflower and rice seeds, respectively, which can be 
explained by the fact that seeds in an advanced 
process of decay have a higher metabolism, possibly 
seeking to reorganize its cellular machinery in order 
to increase respiratory activity (VENSKE et al., 
2014). In watermelon seeds, Oliveira et al. (2015) 
found that the respiratory activity allowed the 
separation of seeds lots, but there were no positive 
or significant correlations with other vigor tests.  

 
 
 



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Table 2. Correlation coefficient between respiratory activity (RA) and physiological quality tests of wheat 
seeds, cv. CD1151 

Tests RA 
G -0,86** 
FE -0,81** 
LS -0,76** 
LR -0,59** 

TDM -0,72** 
EC 3H   0,65** 

EC 24H   0,73** 
1G = germination in sand; FE= field emergency; LS = length of shoot part; LR = length of root; TDM = total dry matter; EC 3H = 
electrical conductivity 3 hours; EC 24H = electrical conductivity 24 hours; ns = not significant, ** = significant at 1% of probability, * = 
significant at 5%, by the r test. 

 
The correlation between respiration and 

electrical conductivity after 3 and 24 hours of 
soaking was significant and positive, with r = 0.65 
and r = 0.73, respectively, therefore, the amount of 
leachate increases with seed respiration. 

Overall, the respiratory activity test was 
correlated with the physiological quality of seeds, 
and therefore, could potentially be used to quickly 
estimate the quality, consistent with results found 
for cotton seeds (VENSKE et al., 2014), soybean 

seeds (MENDES et al., 2009) and sunflower seeds 
(DODE et al., 2012). 

 
CONCLUSION 
 

The respiratory activity test using the 
Pettenkofer method was correlated with other vigor 
tests, and allowed the classification of wheat seeds 
into lots of different levels of quality. 

 
 

RESUMO: As sementes são um atributo muito importante para a cultura, sendo que o uso de sementes de baixa 
qualidade e/ou a gestão inadequada afeta a germinação e dificulta a emergência das plântulas, reduzindo o estande de 
plantas. A necessidade de métodos rápidos, confiáveis e de fácil execução é fundamental para a avaliação do potencial 
fisiológico das sementes. Eles poderiam agilizar as tomadas de decisões referentes ao manejo dos lotes e permitir o 
descarte de lotes de sementes com qualidade inadequada, na unidade de recepção e processamento de sementes, com a 
consequente redução de custos de um provável processamento desnecessário. Entretanto, é importante que os mesmos 
sejam de baixo custo e consideravelmente rápidos. O objetivo do presente trabalho foi correlacionar a atividade 
respiratória de sementes de trigo, através do teste de Pettenkofer, com testes que avaliam a qualidade fisiológica das 
sementes. Foi selecionado um lote de sementes com alta qualidade fisiológica e as mesmas foram submetidas a condições 
adversas de temperatura e umidade relativa do ar para obter diferentes níveis de vigor. As condições adversas foram de 42 
ºC e 100% de umidade relativa, por períodos de seis, 36, 66 e 96 horas. Com o processo obteve-se cinco níveis de vigor e 
estas sementes foram submetidas aos seguintes testes: germinação, emergência a campo, condutividade elétrica, 
comprimento de parte aérea e raiz, massa seca total e atividade respiratória. Os resultados mostraram correlação negativa 
entre a atividade respiratória e os testes de germinação, emergência, comprimento da parte aérea e da raiz, e massa seca, 
sendo que o teste de germinação e a emergência apresentaram alta correlação com a atividade respiratória, r = -0,86 e r = -
0,81, respectivamente. Já a correlação da condutividade elétrica com a respiração foi significativa e positiva. Portanto, 
conclui-se que o teste da atividade respiratória pelo método de Pettenkofer se correlaciona com outros testes de vigor e 
permite a classificação dos lotes de sementes de trigo em diferentes níveis de qualidade. 
 

PALAVRAS-CHAVE: Triticum aestivum L. Método de Pettenkofer. Vigor. 
 
 

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