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1600 
Original Article 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1600-1608, Nov./Dec. 2015 

POTENTIAL PHYSIOLOGICAL SEED Clitoria fairchildiana HOWARD IN 
TIME FUNCTION AND DRYING TEMPERATURE 

 
POTENCIAL FISIOLÓGICO DE SEMENTE DE Clitoria fairchildiana HOWARD EM 

FUNÇÃO DO PERÍODO E DA TEMPERATURA DE SECAGEM 
 

Magnólia Martins ALVES1; Edna Ursulino ALVES2; Rosemere dos Santos SILVA1;  
Sueli da Silva SANTOS-MOURA3; Antônio Pereira dos ANJOS NETO4;  

Caroline Marques RODRIGUES4 
1. Mestrandas do Programa de Pós-Graduação em Agronomia, Departamento de Fitotecnia e Ciências Ambientais, Universidade Federal 

da Paraíba, UFPB, Areia, PB, Brasil; magecologia@hotmail.com; 2. Professora, Doutora, Departamento de Fitotecnia e Ciências 
Ambientais, Centro de Ciências Agrárias, CCA - UFPB, Areia, PB, Brasil. ednaursulino@cca.ufpb.br; 3. Doutoranda em Agronomia, 

Departamento de Fitotecnia e Ciências Ambientais, UFPB, Areia, PB, Brasil.4. Graduandos em Agronomia, Departamento de Fitotecnia 
e Ciências Ambientais, CCA, Universidade Federal da Paraíba – UFPB, Areia, PB, Brasil. 

 
ABSTRACT: The species Clitoria fairchildiana Howard, native to the Amazon region, by a rustic species and 

be of rapid growth, has been useful in heterogeneous reforestation for the reclamation of degraded areas, used in the 
planting of streets, public squares, roads and parking lots, due to its wide, leafy canopy and its rapid growth. The work was 
developed in the Laboratory of Analyses of Seeds of Centro de Ciências Agrárias of Universidade Federal da Paraíba. 
Thus, this study aimed to evaluate the physiological potential of C. fairchildiana seeds submitted to different drying times. 
The experimental design completely randomized, with treatments distributed in a factorial 4 x 5 (temperatures and periods 
of drying). It was evaluated to determine the water content after the drying processing for each period (0, 6, 12, 18 and 24 
hours). For the evaluation of the effect of temperatures (35, 40, 45 and 50 °C) were performed the following tests: water 
content, germination, germination speed index (IVG), as well as length and dry mass of roots and aerial portion of 
seedlings. Drying of seeds of C. fairchildiana is recommended at the temperature of 35 °C, within drying 6 hours without 
compromising the physiological quality of seeds. 

 
KEYWORDS: Sombreiro. Forest species. Desiccation. Water content. 
 

INTRODUCTION 
 
The forestal species Clitoria fairchildiana 

R.A. Howard commonly known as sombreiro, 
faveira, palheteira, belongs to the Fabaceae family. 
Its distribution is mainly in dense ombrophilous 
forest in Amazonia in secondary formations and 
features clear preference for fertil soils and high 
humidity, due to its wide, leafy canopy and its fast 
growth. It is widely used in urban and rural restation 
in degraded areas and reconstruction of permanent 
preservation (LORENZI, 2009). 

The desiccation tolerance of many seeds is 
important to ensure their physiological quality 
during storage. It also enables the anticipation of the 
harvest, depending on the moisture levels that each 
species requires or allows for your seeds, because 
depending on the way in which it is held, this 
operation may be detrimental to the maintenance of 
the seed quality, making it infeasible during storage 
(CARVALHO; NAKAGAWA, 2012). 

During the process of seed formation and 
maturation the water plays an important role, 
working initially in the expansion and cell division 
and later as a vehicle for production of 
photosynthesis. At the end of the seed development 

the water content still remains high, normally above 
40% of the wet weight (MARCOS FILHO, 2005). 

According to the level of the seed tolerance 
the desiccations of them are generally classified as 
recalcitrant, intermediate and orthodox. The 
orthodox seeds can be dewatered at low moisture 
levels, generally on average 5%. The seed longevity 
of these seeds increases with the reduction of 
moisture content under low temperatures and 
relative humidity. The orthodox seeds can be stored 
for many years without any significant loss in 
viability, while on in other hand quickly loses of 
viability can be find if recalcitrant seeds are dried to 
a very low water levels making the longevity be 
relatively short (ROBERTS, 1973). Also there is the 
seeds that show intermediate behavior and can 
survive under moderate drying, usually between 7 
and 10% of the water content. 

The drying process occurs by the 
transference of water from the surface of the seed to 
the surrounding air, otherwise occurs with the 
movement of water from the inside of the seed to 
the surface (CARVALHO; NAKAGAWA, 2012). 

That way this study aimed to evaluate the 
physiological potential of C. fairchildiana seeds 
submitted to different drying times. 

Received: 27/03/15 
Accepted: 10/06/15 



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Potential physiological seed…  ALVES. M. M. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1600-1608, Nov./Dec. 2015 

 
MATERIAL AND METHODS 

 
The present study was conducted at the 

Laboratório de Análise de Sementes (LAS) from the 
Departamento de Fitotecnia e Ciências Ambientais 
of the Universidade Federal da Paraíba, in Areia, 
PB. 

The fruits of C. fairchildiana were collected 
directly from trees matrices, with a minimum 
distance of 20 meters between them, and forwarded 
to the laboratory for processing through manual 
threshing of pods for withdrawal of seeds, which the 
ones that were badly formed, and with damage were 
eliminated. The seeds before being used for the 
evaluations were treated with the fungicide Captan® 
at the concentration of 240 g to 100 Kg-1 of seeds. 

After processing, four replicates of 25 seeds 
were removed and placed to germinate in paper roll 
of germination type test (the zero period without 
drying). The treatments with different levels of 
water were obtained by drying the seeds in the oven 
(at the temperatures of 35, 40, 45 and 50 °C) for 
four periods of six hours. The samples were dried 
were taken for determination of water content, 
germination, germination speed index, first count of 
germination, length and dry mass of seedlings. 

Water content was determined before and 
after each drying period using a four repetition of 10 
seeds for each drying period by the method of oven 
at 105 ± 3ºC for 12 h, following the 
recommendations of (BRASIL, 2009). 

Germination was conducted in a 
germination test paper moistened with distilled 
water the amount equivalent of 3.0 times the weight 
of the paper. The seeds were distributed on a double 
sheet of paper and covered by a single one, in four 
repetitions of 25 seeds. Subsequently were made 
rolls and put in plastic bags, which were placed in 
germination type Biochemical Oxigen Demand 
(B.O.D.) at a temperature of 30 °C. The count of 
seedlings was performed on 9 day after installation 
of the experiment, the criteria used for ratings was 
the normal seedling, the ones that showed 
previously root and epicotyl. 

For determining the germination speed 
index it was made daily counts of normal seedlings, 
at the same time, whose index has been calculated 
according to the Maguire formula (1962). 

The length and seedling dry mass at the end 
of the emergency and germination test was 
measured previously the normal seedlings 
evaluating with the help of a graduated ruler and the 
results were expressed as centimeter per seedling. 
Immediately after the measurements the normal 

seedlings had their cotyledons removed and were 
kept in paper bags and taken to the oven which was 
set up at temperature of 65 °C until them got the 
constant weight. After that they were weigthed on 
an analytical scale accurated to 0.001 g according to 
Nakagawa (1999).  

The statistical design was completely 
randomized with the treatments distributed in a 5 x 
4 factorial scheme, represented by five drying 
periods (0, 6, 12, 18 and 24 h) and 4 temperatures 
(35, 40, 45 and 50 °C), at four repetitions. The data 
was subjected to analysis of variance and 
polynomial regression by means with the software 
SISVAR version 4.6. for Windows.  
 
RESULTS AND DISCUSSION 

 
The water content of seeds of C. 

fairchildiana decreased continuously over the 
period tested independently of the temperatures 
tested. It was verified that when the seed dispersion 
was found with a water content of around 23% in 
both the temperature from this point there was a 
reduction (9%) for the seeds exposed at a 
temperature of 50 °C (Figure 1). According to 
Oliveira et al. (2006) seeds are hydroscopic 
sensitive and have the ability to absorb, yield and 
even retain water and its moisture content is mainly 
influenced by the relative humidity and temperature 
of the air. The initial moisture content of the 
quixabeira’s seeds (Bumelia obtusifolia Roem et 
Schult.) was 25%, which reduced to approximately 
5% in 24 h at a greenhouse environment. However 
when dried in a laboratory environment the moistore 
content found was 10%, then decreased to 8% after 
48 h of drying (NASCIMENTO, 2013). The water 
content of jenipapo’s seeds (Genipa americana L.) 
36 h of drying was around 30% of water content in a 
laboratory and environment roof condition, 
according to Oliveira et al. (2011). Carvalho and 
Nakagawa (2012) said that increasing water content 
help increase the temperature of the seed in due to 
the respiratory processes and higher microorganisms 
activity. 

The highest percentage of C. fairchildiana 
seeds germination achieved the maximum at the 
temperature of 45 °C reaching values (95%) within 
12 h and then starting to decline to 76% in 24 h after 
drying. The temperatures 35 and 40 °C it did not fit 
the polynomial regression model, with averages of 
95 and 96%, respectively, when the seeds were 
subjected at a temperature of 50 °C continuously 
decreased throughout the drying period, the 
maximum percentage (91%) of germination were 
achieved with 6 h of drying, and then began to 



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Potential physiological seed…  ALVES. M. M. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1600-1608, Nov./Dec. 2015 

reduce to values of 66% after 24 h of drying. 
However, the seeds of sucupira (Bowdichia 
virgilioides Kunth.) that were freshly harvested 
showed 10.63% humidity (MATHEUS et al., 2009). 
A study was conducted with seeds of ipê amarelo 
(Tabebuia chrysotricha (Mart. ex A. DC.) Standl.) 
found that the water content was acceptable in seeds 
stored at 20 °C with water levels of 13.6% and 
11.9% for 60 and 120 days, respectively Martins et 

al. (2009). Santos et al. (2010) found that seeds  of 
mangaba (Hancornia speciosa Gomes) are sensitive 
to drying in high temperature locations, particularly 
when the period is extended, resulting in a fast loss 
germination. According to Oliveira et al. (2011) 
studying the quality of seeds of jenipapo (Genipa 
americana L.) found that drying favored the 
emergency percentage in lab environment with 
(92%) during the period of 12 h of drying. 

 

0

10

20

30

0 6 12 18 24

Drying periods (hours)

W
at

er
 c

o
n
te

n
t 

(%
)

y35 ºC =  23,022  - 0,554x             R
2
 = 0,77

y40 ºC =  20,474 - 0,5052x            R
2
 = 0,83

y45 ºC =  22,138 - 0,6645x            R
2
 = 0,74

y50 ºC = 22,092  - 0,6225x            R
2
 = 0,82

35 ºC 40 ºC 45 ºC 50 ºC

 
Figure 1. Seed water content of seeds of Clitoria fairchildiana submitted to different drying periods and 

temperatures. 
 

0

20

40

60

80

100

0 6 12 18 24

Drying periods (hours)

G
er

m
in

at
io

n
 (

%
))

  

y35 ºC = 95

y40 ºC = 96

y45 ºC = 97,029  - 1,1095x  + 0,0476x
2
      R

2
 = 0,83

y50 ºC = 91,8 - 0,9667x                              R
2
 = 0,90

35 ºC 40 ºC 45 ºC 50 ºC

 
Figure 2. Germination of seeds of  Clitoria fairchildiana submitted to different drying periods and 

temperatures. 
 



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Potential physiological seed…  ALVES. M. M. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1600-1608, Nov./Dec. 2015 

When evaluating the data on the first count, 
it appears that the data did not fit the polynomial 
regression models when the seeds were subjected to 
drying at temperatures of 35, 40 and 45 °C, 
averaging results of 90, 83 and 82% for the first 
count of germination. However, for those dried at 50 
°C the first count of germination decreased as 
increased drying time (Figure 3).This test indirectly 
evaluates the speed of germination, and a high 
percentage of germination in the first count means 
that some seeds germinated more rapidly than the 
other (NAKAGAWA, 1999). Therefore, one can see 
that the seeds are sensitive to lost of water, and it 

has likely caused damage to vital tissues such as the 
embryo, which dramatically reduces the germination 
of seeds after drying periods. Similar to what was 
presented in this study, the drying was also 
damaging to the seeds of other species as an 
example the species of mangaba (Hancornia 
speciosa Gomes) whose the drying period reduced 
the  seed germination (BARROS et al., 2010). The 
percentage of seedlings in the first count of 
emergency was 67% after the first 4 h, after that 
period a significant decrease has occurred and, at 
144 h the percentages of emergence of seedlings 
were nulls (OLIVEIRA et al., 2011).

 

0

30

60

90

0 6 12 18 24

Drying periods (hours)

F
ir

st
 c

o
u

n
t 

o
f 

g
er

m
in

at
io

n
(%

))
)

y 35 ºC = 90

y40 ºC = 83

y45 ºC = 82

y50 ºC = 83,2 -1,0667x       R
2
 = 0,81

35 ºC 40 ºC 45 ºC 50 ºC

  
Figure 3. First seed germination of seeds of Clitoria fairchildiana submitted to different drying periods and 

temperatures. 
 

For seed germination speed index of (IVG) 
C. fairchildiana, depending on the different drying 
temperatures, it was affected by the drying 
temperature of 35 and 40 °C did not adjusted to the 
polynomial regression model with mean of 2.56 and 
2.5 respectively. The temperature of 45 °C favored 
highest values (12.33) was recorded after 0h, 
(witness). The temperature of 50 °C did not favored 
the (IVG), which decreasing linearly as the drying 
period increased (Figure 4). The force of the seeds is 
the reflection of a set of characteristics that 
determine its physiological potential, being 
recognized as a variable that indicate lots with 
greater or lesser likelihood of success after sowing 
in the field or during storage in different 
environmental conditions (MARCOS FILHO, 
2005).  For Oliveira et al. (2011) evaluating the 

jenipapo (Genipa americana L.) observed that the 
seeds can be dried in greenhouse environment (33 
°C and 70%) during 12 h and in the laboratory (28 
°C and 75%) for up to 48 h without compromising 
the physiological quality of the same. The 
germination speed index of quixabeira in the 
greenhouse (Bumelia obtusifolia Roem et Schult.) 
environment was higher than in the lab 
environment, in periods of 24 and 120 h 
(NASCIMENTO, 2013). 

The root growth of seedlings of C. 
fairchildiana (Figure 5) was also affected by the 
drying period, evidenced in the germination, first 
count and germination speed index. The greatest 
length of primary roots achieved values of 13.58 cm 
after drying for 12 h, and reducing to 8.72 cm in 24 
h of drying time at the temperature of 35 °C. When 



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Potential physiological seed…  ALVES. M. M. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1600-1608, Nov./Dec. 2015 

the seeds were put to dry at temperatures of 40 to 45 
°C there was no adjustment to any polynomial 
regression model, whose average was 11.53 and 
10.99 cm respectively. However, when the seeds 
were placed to dry at 50 °C, there is a reduction in 
root length of 7.5 cm to 12 cm within 24 h of 

drying. The results obtained can be seen that the 
seeds of this species are sensitive to desiccation, 
probably committed the seeds tissues, which is 
mainly reserve, resulting in lower transfer to the 
seedling growth (CARDOSO et al., 2015). 

 

0

1

2

3

0 6 12 18 24

Drying periods (hours)

G
er

m
in

at
io

n
 s

p
ee

d
 i

n
d

ex

y35 ºC = 2,56

y40 ºC = 2,5

y45 ºC =  2,5517 - 0,0296x + 0,0012x
2
         R

2
 = 0,76

y50 ºC = 2,42  -0,0277x                                 R
2
 = 0,88

 
Figure 4. Germination speed index of seedlings of Clitoria fairchildiana submitted to different drying periods 

and temperatures. 
 

0

4

8

12

16

0 6 12 18 24

Drying periods (hours)

R
o
o
t 

le
n

g
th

 (
cm

))

y35 ºC = 11,15 - 0,4078x + 0,0171x
2
      R

2
 = 0,62

y40 ºC = 11,53

y45 ºC = 10,99

y50 ºC = 11,55 - 0,2168x                          R
2
 = 0,99

35 ºC 40 ºC 45 ºC 50 ºC

 
Figure 5. Primary root length of seedlings of Clitoria fairchildiana submitted to different drying periods and 

temperatures. 
 
The length of the seedlings aerial part 

derived from seeds of C. fairchildiana submitted to 
different periods of drying (Figure 6) initially there 

was an increase in shoot length (8.67 cm), at 35 °C 
and decreased to (4.64 cm) after 14 h of drying, 
while in the temperature of 40 °C was achieved a 



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Potential physiological seed…  ALVES. M. M. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1600-1608, Nov./Dec. 2015 

length (6.68 cm) after 6 h of drying. At the 
temperature of 45 °C, when the seeds dried for 13 h 
obtained (5.22 cm) of shoot length. About the 50 °C, 
the length of aerial parts linearly reduced as it was 
prolonged the period of drying. For the shoot length 
of mangaba (Hancornia speciosa Gomes) seedlings 
grown from seeds subjected to different periods of 
drying initially there was an increase in shoot length 
(4,96 cm), corresponding to 56 h of drying; after 

this period there was a reduction in the size of 
seedlings, reaching approximately 144 h values of 
3.5 cm (SANTOS et al., 2010). The length of the 
seedlings of jenipapo (Genipa Americana L.) can be 
subjected to drying in lab environment for up to 31 
h, while in the greenhouse environment until 12 h 
(OLIVEIRA et al., 2011). 

 

 

y 35ºC=  6,6529- 0,2868x + 0,0102x
2
  R2 = 0,76

y 40ºC= 6,686 - 0,0778x  R
2
 = 0,59

y45ºC =  6,2609 - 0,1573x + 0,0059x
2
  R

2
 = 0,64

y 50ºC= 4,694 -0,1197x  R
2
 = 0,80

0

2

4

6

8

0 6 12 18 24

Drying periods (hours)

L
en

g
th

 o
f 

th
e 

ae
ri

al
 p

ar
t 

 (
cm

)

35 ºC 40 ºC 45 ºC 50 ºC

 
Figure 6. Length of the aerial part of seedlings of Clitoria fairchildiana submitted to different drying periods 

and temperatures. 
 
Figure 7 shows that the results for dry 

matter content of Clitoria fairchildiana seedling 
roots at the temperature of 35 °C showed the highest 
content of root dry weight with 0.0333 g. At 
temperatures of 40 and 45 °C it did not fit the 
polynomial regression model, averaging values of 
0.0242 and 0.0243 g respectively. At 50 °C after 24  
h of drying the highest content was 0.0182 g.  

The behavior of seeds can be considered as 
a result of the natural selection process that they are 
embedded in the environment, in accordance with 
the environmental conditions of the regions of 
origin of the species (MARCOS FILHO, 2005). The 
dry matter content of seedlings from seeds of 
ameixa-do-pará (Bunchosia armênica Cav.) 
plantlets were tolerant to desiccation for a period 
greater than 12 h (SILVA et al., 2012). 

As observed previously in the emergence 
tests, seedling length and mass results of the 
aboveground part of seedlings (Figure 8) decreased 

similarly over the period of drying. Thus, it was 
found that drying for a period of 6 h was responsible 
for a maximum dry matter content (0.0766 g) at 35 
°C. When the seeds were submitted to 40 °C it was 
not adjusted to the regression model with mean 
(0.0777 g), but at a temperature of 45 °C it was 
found that the greatest shoot dry weight of seedling 
at 6 h of drying. At the temperature of 50 °C the 
values decreased linearly when was increased the 
drying time. The mass of the dry matter of seedlings 
was found that the seeds of jenipapo (Genipa 
Americana L.) may be exposed to drying, in the 
laboratory for 43 h, while those subjected to drying 
in greenhouse reduced drastically after 12 h 
(OLIVEIRA et al., 2011).  

 
 
 
 
 



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Biosci. J., Uberlândia, v. 31, n. 6, p. 1600-1608, Nov./Dec. 2015 

 

0

0,006

0,012

0,018

0,024

0,03

0,036

0 6 12 18 24

Drying periods (hours)

R
o

o
t 

d
ry

 m
as

s 
(g

)
   
 

y35 ºC =  0,0283 - 0,0011x + 405x
2
      R

2
 = 0,71

y40 ºC = 0,0242

y45 ºC = 0,0243

y50 ºC =  0,0268 - 0,0004x                    R
2
 = 0,81

35 ºC 40 ºC 45 ºC 50 ºC

 
Figure 7. Root dry mass of seedlings of Clitoria fairchildiana submitted to different drying periods and 

temperatures.  
 

0

0,04

0,08

0,12

0 6 12 18 24
Drying periods (hours)

D
ry

 m
as

s 
o
f 

sh
o

o
ts

 (
g

))

y35 ºC =   0,0987 - 0,0039x + 0,0001x
2
     R

2
 = 0,98

y40 ºC = 0,0777

y45 ºC =  0,0995 - 0,0033x + 0,0001x
2
     R

2
 = 0,77

y50 ºC =   0,075 - 0,0017x                         R
2
 = 0,80

35 ºC 40 ºC 45 ºC 50 ºC

 
Figure 8. Aboveground dry weight of seedlings of Clitoria fairchildiana submitted to different drying periods 

and temperatures. 
 
CONCLUSION 

 
Drying of seeds of Clitoria fairchildiana is 

recommended at the temperature of 35 °C, within 6 

hours drying in order to not compromise the 
physiological quality of seeds. 

 
 

RESUMO: A espécie Clitoria fairchildiana Howard, nativa da região amazônica, por se trata de uma espécie 
rústica e de rápido crescimento, tem sido utilizada nos programas de reflorestamentos heterogêneos destinados à 
recuperação de áreas degradadas com potencialidade para arborização de ruas, praças, rodovias e estacionamentos, devido 



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Potential physiological seed…  ALVES. M. M. et al. 

Biosci. J., Uberlândia, v. 31, n. 6, p. 1600-1608, Nov./Dec. 2015 

à sua copa larga e frondosa. O presente trabalho foi conduzido no Laboratório de Análises de Sementes do Centro de 
Ciências Agrárias da Universidade Federal da Paraíba. Dessa forma, objetivou-se avaliar o potencial fisiológico de 
sementes de C. fairchildiana submetidas a diferentes períodos de secagem. O delineamento experimental utilizado foi 
inteiramente ao acaso, com os tratamentos distribuídos em arranjo fatorial 4 x 5,(temperaturas e períodos). 
Preliminarmente determinou-se o teor de água das sementes para cada período de secagem (0, 6, 12, 18 e 24 horas). Para a 
avaliação do efeito das temperaturas (35, 40, 45 e 50 °C) foram realizados os seguintes testes: teor de água, germinação, 
índice de velocidade de germinação (IVG), bem como comprimento e massa seca de parte raízes e parte aérea das 
plântulas. Para a secagem de sementes de C. fairchildiana é recomendada à temperatura de 35 °C por até 6 horas de 
exposição à secagem sem comprometer a qualidade fisiológica de suas sementes. 

 
PALAVRAS - CHAVE: Sombreiro. Espécie florestal. Dessecação. Teor de água. 

 
 

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