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Original Article 

Biosci. J., Uberlândia, v. 34, n. 6, p. 1551-1554, Nov./Dec. 2018 

VIGOR DETERMINATION OF OKRA SEEDS BY RESPIRATORY ACTIVITY 
 

DETERMINAÇÃO DO VIGOR DE SEMENTES DE QUIABO PELA ATIVIDADE 
RESPIRATÓRIA 

 
Moadir de Sousa LEITE

1
; Salvador Barros TORRES

2
; Rômulo Magno Oliveira de FREITAS

3
; 

Narjara Walessa NOGUEIRA
2
; Tiago de Sousa LEITE

4
; Emanoela Pereira de PAIVA

5
 

1. Eng. Agrônomo, Universidade Federal Rural do Semi-Árido, Mossoró, RN, Brasil. moadir@outlook.com; 2. Professor, Doutor em 
Fitotecnia, Universidade Federal Rural do Semi-Árido, Mossoró, RN, Brasil; 3. Professor, Doutor em Fitotecnia, Instituto Federal de 

Educação, Ciência e Tecnologia Baiano, Salvador, BA, Brasil; 4. Mestrando em Solos e Nutrição de Plantas, Escola Superior de 
Agricultura Luiz de Queiroz, ESALQ/USP, Piracicaba, SP, Brasil; 5. Doutor em Fitotecnia, Universidade Federal Rural do Semi-Árido, 

Mossoró, RN, Brasil. 
 

ABSTRACT: Seed companies increasingly need to obtain reliable results on seed vigor. Therefore, the 
objective was to verify the efficiency of the respiratory activity measurement, by the CO2 released, to classify the vigor of 
okra seed lots. For this, five seed lots of okra cv. “Santa Cruz 47” were used. In order to determine seed physiological 
quality, the following tests were performed: germination, seedling emergence, emergence speed index, shoot length, total 
dry matter, potassium leaching, electrical conductivity and respiratory activity. Mean values of germination and vigor were 
compared by Tukey’s test. Respiratory activity was correlated with germination and other vigor tests by the Pearson’s 
correlation. The results indicate that CO2 measurement is a promising method to identify vigor differences between okra 
seed lots. 

 
KEYWORDS: Abelmoschus esculentus. CO2 measurement. Physiological quality. 

 
INTRODUCTION 

 
Okra (Abelmoschus esculentus (L.) 

Moench) is a vegetable adapted to tropical and 
subtropical climates, being cultivated in many parts 
of the world (SHARMA et al., 2014). Despite the 
economic importance of this species, research 
regarding its management is still scarce, especially 
in relation to seed handling. 

The germination test is the most widely 
used to determine the physiological quality of seed 
lots. However, this test does not always reflect the 
results obtained in field conditions and its 
conduction can be time-consuming. Thus, it is 
necessary to develop rapid tests with results 
comparable to the emergence in the field. The 
germination test for okra seeds lasts for 21 days 
(BRASIL, 2009), which is a long period. 

Several tests have been developed aiming at 
rapid and reliable results on seed quality. In this 
context, vigor tests stand out for their high 
correlation with field emergence. Among them, 
accelerated aging, potassium leaching and 
respiratory activity are some examples of low-cost 
and easily reproducible tests. 

The respiratory activity test consists in 
measuring the amount of CO2 released from seeds 
during the respiration process, which results from 
the oxidation of organic substances in the cellular 
system after the start of the imbibition process. 
Thus, high respiratory rates are associated with 

vigorous seeds due to the oxidation of a large 
amount of reserve tissues present in their cells. This 
test is economic, rapid and easy to perform, as 
reported for Helianthus annuus L. (DODE et al., 
2012), Glycine max L. (DODE et al., 2013) and 
Citrullus vulgaris Schrad. (OLIVEIRA et al., 2015). 
Therefore, the objective of this work was to verify 
the efficiency of CO2 measurement to determine 
vigor in okra seed lots. 
 

MATERIAL AND METHODS 

 
Five seed lots of okra cv. Santa Cruz 47, 

2014/2015 crop year, were obtained from Brazilian 
seed companies. The water content of each seed lot, 
determined in a forced-air oven at 105±3 °C for 24 
hours (BRASIL, 2009), ranged from 11.1 to 12.0% 
(wet basis). Then, the physiological quality of each 
seed lot was assessed as described below: 

Germination test: four replications of 50 
seeds per lot were sown in sand moistened with 
60% of its water retention capacity, placed to 
germinate at 20-30 °C under a light regime of 12 
hours at the highest temperature, and assessed at 21 
days after sowing (BRASIL, 2009). 

Seedling emergence, emergence speed index 
(ESI), shoot length and total dry matter: four 
replications of 50 seeds per lot were sown in 1.2 m 
wide, 0.15 m x 0.05 m apart and 0.02 m deep beds. 
Seedling emergence was daily assessed up to 21 
days after sowing in order to determine the ESI 

Received: 30/08/17 
Accepted: 15/08/18 



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Vigor determination…  LEITE, M. S. et al. 

Biosci. J., Uberlândia, v. 34, n. 6, p. 1551-1554, Nov./Dec. 2018 

(MAGUIRE, 1962). After this period, emergence 
percentage, shoot length and total dry matter 
(determined in a forced-air oven at 60 °C until 
constant weight) were also determined. 

Potassium leaching (KL) and electrical 
conductivity (EC): seeds were weighed and then 
soaked in 75 mL of distilled water at 25 °C for 90 
and 240 minutes for KL and EC, respectively. Then, 
the imbibition waters were subjected to readings, 
using a flame photometer for KL and a conductivity 
meter for EC (DIAS et al., 1998). 

Respiratory activity (RA): the CO2 released 
from seeds was determined by the Pettenkofer 
method by adapting the methodology described by 
Oliveira et al. (2015) for watermelon seeds, using 
four replications of 10 grams of okra seeds per lot. 
Seeds from the different lots were first soaked in 50 
mL of distilled water for 60 minutes. After this 
period, they were placed into the Pettenkofer 
apparatus for an additional period of 60 minutes and 
then respiration was measured (MENDES et al., 
2009). Respiratory activity was calculated based on 
the following expression: N x D x 22 (Müller, 
1964), where: N = normality of the acid used (0.1 N 
HCl); D = difference between the HCl volume used 
in the blank titration and the HCl volume used in the 

sample titration; 22 = normality of CO2. Results 
were expressed as quantity of carbon dioxide 
released per gram of seed per hour (µg CO2 g seed

-1 
h-1). 

A completely randomized experimental 
design with four replications was used. The data 
were subjected to ANOVA and means were 
compared by Tukey’s test (P ≤ 0.05), using the 
SISVAR® software (FERREIRA, 2011). Pearson’s 
correlation (P ≤ 0.05) was used to assess the 
relationship between the vigor tests and seed 
respiratory activity. 
 
RESULTS AND DISCUSSION 

 
The germination test showed significant 

differences between the okra seed lots, with 
variations from 60 to 96%. Lots 1 and 2 were 
superior to the others, although statistically similar 
to lot 3, and lot 5 had the lowest performance (Table 
1). The field emergence had similar results, 
indicating lots 1 and 2 as the most vigorous ones, 
whereas lot 5 showed the lowest vigor level. The 
emergence test evaluates the maximum potential to 
produce normal seedlings in the field, often under 
unfavorable environmental conditions. 

 
Table 1. Mean values1 of germination (G), seedling emergence (E), emergence speed index (ESI), shoot length 

(SL), seedling total dry mass (TDM), potassium leaching (KL), electrical conductivity (EC) and 
respiratory activity (RA), in lots of seeds of okra cv. Santa Cruz 47. 

Lot 
G 

(%) 
E 

(%) 
ESI 

 
SL 

(cm) 
TDM 
(mg) 

KL 
(ppm) 

EC (µS 
cm-1 g-1) 

RA (µg CO2 g 
seed-1 h-1) 

1 96 ab 94 a 7.4 b 5.43 a 9.07 a 3.47 d 14.95 a 5.57 a 
2 96 ab 94 a 8.5 a 4.61 ab 6.13 b 3.78 cd 16.33 ab 3.34 b 
3 92 ab 90 a 7.4 b 4.08 b 5.16 bc 4.24 bc 18.87 b 3.15 b 
4 90 b 82 b 6.9 bc 4.15 b 4.57 cd 4.65 b 22.04 c 1.58 c 
5 60 c 76 b 6.0 c 3.73 b 3.86 d 5.81 a 29.30 d 0.78 c 

CV (%) 4.2 5.6 7.2 11.8 8.5 6.3 6.4 18.7 
1 Means followed by the same letter in the column do not differ by Tukey test (P ≤ 0.05). 

 
Although seedlings obtained from lot 2 

emerged with greater speed, those from lot 1 
showed a higher average shoot length, but this 
variable did not differ statistically between these 
lots. A larger translocation of seed reserves to the 
embryonic axis growth leads to seedlings with 
increased shoot length, which characterizes a greater 
seedling vigor, as emphasized by Oliveira et al. 
(2015). 

Similarly to what was observed for shoot 
length, the total dry matter pointed lot 1 as having 
the best physiological quality and lot 5 as being the 
least vigorous, with the lowest content of dry matter 
in comparison to the other lots. According to Dode 
et al. (2012), for a given species, seedlings with 

greater shoot length and fresh and dry matter 
suggest that the seeds from which they were 
originated had better physiological quality. 
Therefore, these seedlings are considered as more 
vigorous, as it was verified for those obtained from 
lot 1. 

The data regarding electrical conductivity 
and potassium leaching indicated lot 1 as having the 
best physiological quality and lot 5 as the one with 
the worst performance, which gives support to the 
results obtained in the other tests. High conductivity 
values are related to a reduction in membrane 
integrity, directly undermining seedling 
development as less vigorous seeds have poorly 
structured membranes and damaged cells, which is 



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Vigor determination…  LEITE, M. S. et al. 

Biosci. J., Uberlândia, v. 34, n. 6, p. 1551-1554, Nov./Dec. 2018 

associated with the process of seed deterioration 
(OLIVEIRA et al., 2015). Similarly, seed lots of 
greater physiological quality undergo less leaching 
of potassium (ALVES; SÁ, 2010). 

It was possible to rank the respiratory 
activity into high, medium and low, confirming lots 

1 and 5 as the most and least vigorous, respectively. 
This test was positively correlated with seedling 
emergence, shoot length and total dry matter, and 
inversely proportional to potassium leaching and 
electrical conductivity tests (Table 2).  

 
Table 2. Coefficient of simple linear correlation between respiratory activity (RA) and germination (G), 

seedling emergence (E), emergence speed index (ESI), shoot length (SL), seedling total dry mass 
(TDM), potassium leaching (KL) and electric conductivity (EC) of okra seeds, cv. Santa Cruz 47". 

Coefficient of correlation 
Tests G E ESI SL TDM KL EC 
RA 0.77ns 0.91* 0.59ns 0.93* 0.97** -0.91* -0.90* 

* Significant (P ≤ 0.05); ** Significant (P ≤ 0.01); ns Not significant. 
 

The greater the release of leachate to the 
soaking solution, the smaller the amount of CO2 
released during cellular respiration and, 
consequently, the lower the seed vigor. According to 
Marcos Filho (2015), the reduction in germination 
speed is not the first event in the process of seed 
deterioration. Consequently, emergence speed index 
showed low sensitivity to identify small vigor 
differences. Thus, similarly to the germination test, 
it did not correlate significantly with respiratory 
activity. 

In lots of low physiological quality, such as 
lot 5, there is a reduction in the membrane 
reconstruction speed during imbibition, resulting in 
lower respiratory rates due to the lower number 
and/or efficiency of mitochondria (OLIVEIRA et 
al., 2015). Thus, this will result in less vigorous 
seedlings, as evidenced by the correlations between 

respiratory activity and the other vigor tests 
performed. In contrast, viable embryos have intact 
mitochondria, whose respiratory activity increases 
with the start of imbibition, which makes these 
organelles more efficient in the production of 
adenosine triphosphate (ATP). Therefore, a greater 
oxygen consumption is demanded, which 
consequently increases the production of carbon 
dioxide (BEWLEY; BLACK, 1994). In this context, 
vigorous seed lots have a higher respiratory rate, as 
evidenced in seeds from lot 1. 
 
CONCLUSION 

 
The measurement of respiratory activity by 

CO2 released is a promising test to identify vigor 
differences between seed lots of okra cv. Santa Cruz 
47. 

 
 

RESUMO: As empresas produtoras de sementes necessitam cada vez mais da obtenção de resultados confiáveis 
quanto ao vigor da semente. Nesse sentido, objetivou-se verificar a eficiência da medição da atividade respiratória, através 
da emissão de CO2, para classificação do vigor de lotes de sementes de quiabo. Para isso, utilizaram-se cinco lotes de 
sementes de quiabo cv. “Santa Cruz 47”. Para determinação da qualidade fisiológica das sementes, foram realizados os 
seguintes testes: germinação, emergência, índice de velocidade de emergência, comprimento da parte aérea, matéria seca 
total, lixiviação de potássio, condutividade elétrica e atividade respiratória. As médias de germinação e vigor foram 
comparadas pelo teste de Tukey. O teste de atividade respiratória foi correlacionado com a germinação e demais testes de 
vigor através da correlação de Pearson. A medição do CO2 constitui-se em um método promissor para identificar 
diferenças de vigor em lotes de sementes de quiabo. 

 
PALAVRAS-CHAVE: Abelmoschus esculentus. Medição de CO2. Qualidade fisiológica. 

 
 
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