Revista Brasileira de Engenharia Agrícola e Ambiental
Campina Grande, PB, UAEA/UFCG – http://www.agriambi.com.br

ISSN 1807-1929

v.21, n.10, p.715-720, 2017

Processing on the sanitary quality of seeds
of Panicum maximum cv. ‘Tanzânia’
Lilian F. Melo1, Givanildo Z. da Silva1, Rita C. Panizzi2 & Cibele C. Martins1

DOI: http://dx.doi.org/10.1590/1807-1929/agriambi.v21n10p715-720

A B S T R A C T
The aim of this study was to evaluate the sanitary quality of seeds of Panicum maximum cv. 
‘Tanzânia’, following the several phases of the seed processing process. Seeds were sampled 
before processing and after leaving the air and screen machine (upper and intermediary 
screens and bottom); first gravity table (drift, upper and intermediate spouts); second 
gravity table (upper, intermediate, and lower spouts), and treating machine for dyeing the 
seeds. The sanitary analyses were conducted according to the filter paper method, with 
and without superficial disinfestation of the seeds, which were incubated at a temperature 
of 20 ± 2 °C with photoperiod of 12 h for seven days. Some seed processing steps may 
reduce the incidence of seeds of P. maximum cv. ‘Tanzania’ contaminated with Phoma 
sp. and Helminthosporium sp. In general, the processing can increase the incidence of 
seeds contaminated with Cladosporium sp. and Cercospora sp. The fungi Phoma sp., 
Helminthosporium sp., Penicillium sp., Cladosporium sp. and Cercospora sp. are found inside 
and outside the seeds and can be disseminated by the processing machines.

Beneficiamento na qualidade sanitária
de sementes de Panicum maximum cv. Tanzânia
R E S U M O
Objetivou-se, neste trabalho, avaliar a qualidade sanitária de sementes de Panicum maximum 
cv. Tanzânia durante as etapas de beneficiamento. As sementes foram amostradas antes do 
processamento e após a saída da máquina de ventilador e peneiras (descarga das peneiras 
superior, intermediária e fundo), primeira mesa gravitacional (deriva, descarga superior e 
intermediária), mesa gravitacional (descarga superior, intermediária e inferior) e máquina 
tratadora para tingimento das sementes. A análise sanitária foi realizada pelo método do 
papel de filtro com e sem desinfestação superficial das sementes, as quais foram incubadas 
a 20 ± 2 °C, com fotoperíodo de 12 h durante sete dias. Algumas etapas de beneficiamento 
podem reduzir a porcentagem de sementes de P. maximum cv. Tanzânia contaminadas com 
Phoma sp. e Helminthosporium sp. Em geral, o beneficiamento pode aumentar a porcentagem 
de sementes com Cladosporium sp. e Cercospora sp. Os fungos Phoma sp., Helminthosporium 
sp., Penicillium sp., Cladosporium sp. e Cercospora sp. se encontram alojados nas sementes 
interna e externamente e podem ser disseminados pelas máquinas de beneficiamento.

Key words:
processing
seed pathology
health

Palavras-chave:
processamento
patologia de sementes
sanidade

1 Universidade Estadual Paulista/Faculdade de Ciências Agrárias e Veterinárias/Departamento de Produção Vegetal. Jaboticabal, SP. E-mail: lilianfariamelo@gmail.com; 
givanildozildo@hotmail.com; cibele@fcav.unesp.br (Corresponding author)

2 Universidade Estadual Paulista/Faculdade de Ciências Agrárias e Veterinárias/Departamento de fitossanidade. Jaboticabal, SP. E-mail: rpanizzi@fcav.unesp.br

Ref. 215-2016 – Received 8 Jan, 2017 • Accepted 31 Mar, 2017 • Published 25 Aug, 2017



716 Lilian F. Melo et al.

R. Bras. Eng. Agríc. Ambiental, v.21, n.10, p.715-720, 2017.

Introduction

The lots of Panicum spp. seeds received by the companies 
contain earth, rocks, straw and empty spikelets and these 
impurities should be removed by the processing in order 
to meet the requirements for commercialization (Melo et 
al., 2016a, 2016b). Processing machines perform sequential 
operations of cleaning, classification and treatments that allow 
the improvement of seed quality and disposal of undesired 
material (Hessel et al., 2012; Melo et al., 2016a, 2016b). 

This process, however, can also increase the chances of 
seed contamination, because the earth existing in the lots 
is deposited inside the machines and may contain fungal 
structures that contaminate the subsequently processed lots, 
as observed by Linares (1999) in bean seeds. Therefore, the 
processing of forage grass seeds must be enhanced in order to 
improve its sanitary quality (Marchi et al., 2010).

In seeds of P. maximum and Brachiaria spp., researchers 
have detected potentially pathogenic fungi such as the genera 
Curvularia, Fusarium, Phoma, Exserohilum, Cercospora 
and Helminthosporium, besides others, such as Alternaria, 
Aspergillus, Cladosporium, Epicoccum, Nigrospora, Penicillium 
and Trichoderma, (Marchi et al., 2010; Martinez et al., 2010; 
Mallmann et al., 2013; Marcos et al., 2015). These seeds can 
be a vehicle of dispersion of pathogens between regions 
(Vechiato et al., 2010).

The rejects of the processing can also contribute to 
spreading fungi, because this material is commonly purchased 
by companies with low technological level from the forage 
seeds sector to be mixed with the lots intended for less 
demanding markets (Hessel et al., 2012). Thus, this study aimed 
to evaluate the influence of the processing on fungal incidence 
in seeds of P. maximum cv. ‘Tanzânia’. 

Material And Methods

The seeds of P. maximum cv. ‘Tanzânia’ were harvested 
by ground sweeping in the 2013/2014 season in Jales, SP, 
processed in a forage grass seed processing unit, passing 
through an air and screen machine, two gravity tables and 
one treating machine to dye the seeds. The sequence of 
processing operations for forage seeds described by Melo et 
al. (2016b) was adopted.

Eleven treatments were obtained in the various processing 
steps and different machines, as described below:

T1 - control composed by raw seed, not processed.
Air and screen machine: T2 - after passing through the 

air and screen machines, the samples were collected from the 
material retained on the top screen, which has round mesh 
with diameter of 5.56 mm.

T3 - 20 AWG (0.8118-mm diameter) twisted wire 
intermediate screen, with square mesh and 30 x 30 mm 
opening.

T4 - metal plate bottom, which retained the fine material 
that passed through the screens. The seed company routinely 
discards the material from treatments T2 and T4, because it 
contains more than 90% of impurities (Melo et al., 2016b).

First gravity table: T5 - samples were collected from the 
drift material removed by an aspirator at the inlet of this 

machine, also considered as reject by the company, because 
it contains 97% of impurities in its composition (Melo et al., 
2016b). The surface of this device was 2.40 m long and 1.25 
m wide, with vibration speed of 1,750 rpm, 17º and 12º of 
transverse and longitudinal inclination, respectively.

T6 - After passing on the first gravity table, the samples 
were collected at the upper spout, composed of the fraction of 
material collected at 35 cm from the highest end of the table’s 
outlet considering its lateral inclination.

T7 - Samples collected at the intermediate spout, 
composed of material collected in the 60-cm intermediate 
segment of the table’s outlet.

The seeds of the lower spout, composed of the fraction 
of material collected in the 30-cm segment from the lowest 
end of the table considering its lateral inclination, were not 
sampled, but instead passed on a second gravity table.

Seed treating machine: T8 - in the sequence, only the seeds 
from the intermediate spout of the first gravity table were 
subjected to dyeing, aiming only to improve their appearance, 
performed by spraying the green dye of Laborsan Brasil® and 
mechanical movement of the mass in the treating machine 
Seed Mix VHM- 4/10 T. 

Second gravity table: T9 - the seeds were collected after 
passing on the second gravity table, identical to the first one, 
but with different adjustments of the spouts, because the upper 
spout was composed of the fraction of material collected in 
the 60-cm segment from the highest end of the table’s outlet.

T10 - intermediate spout, composed of the material 
collected in the 45-cm intermediate segment and T11 - 
lower spout, composed of the material collected in the 20-
cm segment of the lowest end. The seed company routinely 
considers as rejects the materials from treatments T10 and 
T11, because it contains more than 90% of impurities (Melo 
et al., 2016b).

The samples collected after the processing steps were 
reduced in soil splitter to obtain the working sample and 
the portion of pure seeds was separated for health analysis 
(BRASIL, 2009).

The health test was conducted at the Seed Pathology 
Laboratory of the Plant Health Department of the Faculty 
of Agrarian and Veterinary Sciences - (UNESP), Campus 
of Jaboticabal, SP, through the filter paper method (Blotter 
test) without and with superficial disinfestation of the seeds 
through immersion in NaClO (1%) for 3 min, followed by 
rinsing with sterilized water and drying at room temperature. 
For the test, 10 replicates of 10 seeds of each treatment 
were distributed equidistantly on three sheets of filter paper 
previously moistened with distilled water and incubated on 
9.0-cm-diameter Petri dishes for 7 days, at 20 ± 2 °C and 
under 12 h of light (Martins et al., 2001).

Then, the seeds were individually analyzed under 
stereoscopic microscope and the fungi were identified 
through the morphological characteristics of their structures 
(Barnett & Hunter, 1998). The results were expressed in 
percentage of contaminated seeds, for each fungus.

The experiment was evaluated using a completely 
randomized design, in 2 x 11 factorial scheme (superficial 
disinfestation x processing steps). The data of fungal incidence 



717Processing on the sanitary quality of seeds of Panicum maximum cv. ‘Tanzânia’

R. Bras. Eng. Agríc. Ambiental, v.21, n.10, p.715-720, 2017.

(%) in the seeds were transformed to (x + 0.01)0.5 to meet the 
assumptions of normality and homogeneity tests. The presented 
means are relative to the original data, which were subjected 
to analysis of variance by F test. The means of the treatments 
were compared by Tukey test at 0.05 probability level.

Results and Discussion

The pathological analysis of P. maximum seeds, cv. 
‘Tanzânia’, detected twelve fungal genera: six with higher 
incidence, above 5%, such as Phoma, Helminthosporium, 
Cladosporium, Cercospora, Fusarium and Penicillium, and the 
others with low incidence, inferior to 3%, regardless of the 
processing step or disinfestation procedure, such as Curvularia, 
Alternaria, Epicoccum, Rhizopus, Aspergillus and Rizoctonia 
(Figure 1).

Almost all these last six fungi with low incidence in the lot 
were not affected by the seed processing steps or disinfestation, 
except Alternaria sp., which increased from 0.63 to 3.63%, only 
due to the disinfestation procedure (data not shown). Probably, 
the higher incidence of Alternaria sp. in disinfested seeds may 
have occurred because of the reduction in the fungi of other 
genera, which competed for survival. This fact was observed 
for fungi of other genera in studies with seeds of forage grasses 
(Santos et al., 2014).

The occurrence of some fungi, even at percentages lower 
than 10%, still represents a risk of loss of seed quality, because 
these microorganisms have high capacity of multiplication 
and contamination of the lots in the storage, as observed for 
Penicillium sp. and Aspergillus sp. in soybean seeds (Cardoso 
et al., 2004).

The reduction in the occurrence of the genera Phoma, 
Helminthosporium, Fusarium, Penicillium, Cladosporium 
and Cercospora due to the disinfestation process (Figure 1) 
leads to the conclusion that a significant percentage of the 
structures of these fungi is found on seed surface and they can 
be disseminated by the machines during the processing, from 
one lot to another, as observed by Linares (1999) in bean seeds.

As shown in Figure 2, the forage grass seed processing units 
usually have large amount of dust and earth suspended in the 
air and the machines are impregnated with these particles, 
which may contain fungal structures.

On the other hand, the presence of Phoma  sp. , 
Helminthosporium sp., Penicillium sp., Cladosporium sp. and 

Figure 1. Total incidence of fungi detected during the 
sanitary test in seeds of P. maximum cv. ‘Tanzânia’, with 
and without superficial disinfection

Figure 2. Dust and earth in suspension impregnating the 
gravity table (A) and the air and screen machine (B) during 
the processing of Panicum maximum seeds

A.

B.

Cercospora sp. also in disinfested seeds allows to infer that 
the dissemination structures were found inside the seeds of 
P. maximum. Therefore, part of the contamination with these 
pathogens must have occurred still at the field during seed 
formation. This fact is possible, because there are reports on 
the occurrence of these fungi in pastures (Martinez et al., 2010; 
Mallmann et al., 2013).

Among the studied fungi, the interaction of the seed 
processing steps and disinfestation procedure was only observed 
on the percentage of incidence of Phoma sp., Helminthosporium 
sp., Fusarium sp. and Penicillium sp. (Table 1).

The disinfestation significantly reduced the incidence 
of Phoma sp. in the seeds obtained in almost all processing 
steps, except in those from the treating machine (T8). In 
this operation, the seeds were dyed and the procedure may 
have washed part of the dissemination structures present on 
seed surface. The seeds without disinfestation showed lower 
percentage of pathogens in comparison to those disinfested 
and subjected to the treating machine.

For the incidence of Phoma sp. in the seeds without 
superficial disinfestation, compared with the control, there 
were lower percentages of this pathogen in samples from the 
reject material obtained at the bottom of the air and screen 
machine (T4), in the upper spout of the first gravity table (T6), 
after the seed treating machine (T8) and in the lower spout 



718 Lilian F. Melo et al.

R. Bras. Eng. Agríc. Ambiental, v.21, n.10, p.715-720, 2017.

of the second gravity table (T11). Thus, it demonstrated the 
importance of the processing to reduce fungal structures of 
Phoma sp. in the seeds of P. maximum, cv. ‘Tanzânia’.

These results allow to claim that the rejects of the processing 
can also represent risk of fungal dissemination to other pasture 
areas, because this material is usually commercialized and 
mixed with other lots to meet less demanding markets of forage 
seeds (Hessel et al., 2012; Mallmann et al., 2013). 

The percentage of Helminthosporium sp. in the seeds 
was reduced by the superficial disinfestation and there was 
higher incidence of this microorganism in the seeds without 
disinfestation; this event was observed in some treatments, 
such as seeds not processed (T1), from the bottom of the air 
and screen machine (T4) and lower spout of the second gravity 
table (T11). 

In the seeds without disinfestation, the reject material 
obtained in the upper screen of the air and screen machine 
(T2) and drift of the first gravity table (T5) and seeds obtained 
in the intermediate spout of the first gravity table (T7) showed 
lower incidence of Helminthosporium sp. in comparison to the 
control. Hence, it highlights the importance of seed processing 
for the improvement of sanitary quality, corroborating the 
reports of Fessel et al. (2003) for maize seeds and Mertz et al. 
(2007) for cowpea seeds.

The processing steps did not affect the incidence of 
Fusarium sp. in the seeds, because none of them significantly 
altered the occurrence of this fungus, regardless of the 
disinfestation process. The superficial disinfestation of the 
seeds also did not affect the incidence of Fusarium sp. along 
each processing step. This means that the detected fungus was 
found inside the seeds (Cappelini et al., 2005).

Phoma sp. and Fusarium sp. can be considered as the 
main pathogenic microorganisms associated with forage grass 
seeds, have rapid, aggressive growth, and can cause seed death 
and reduction in seedling emergence percentage (Yang et al., 
2011; Kuhnem Júnior et al., 2013; Mallmann et al., 2013). 
Additionally, they were considered by Martins et al. (2001) 

and Marchi et al. (2010) as the most common fungi in pastures 
of P. maximum.

In general, Penicillium sp. was found with low frequency 
in the treatments, between 0 and 14%. This is considered 
by Vechiato et al. (2010) as a fungus of storage and its low 
incidence in this research can be attributed to the use of 
recently collected seeds.

There was no interaction between the seed processing 
steps and disinfestation procedure on the occurrence of 
Cladosporium sp. and Cercospora sp. (Table 2). However, the 
disinfestation reduced the incidence of these fungi, possibly 
because they are found on the surface of the seeds.

Table 1. Fungal incidence in seeds of Panicum maximum cv. ‘Tanzânia’ with (WD) and without (WOD) superficial 
disinfestation with sodium hypochlorite, as a function of the processing steps

Processing steps (P)

Phoma sp. Helminthosporium sp. Fusarium sp. Penicillium sp.

%

WOD WD WOD WD WOD WD WOD WD

T1 65 dB 30 bcA 64 cB 28 aA 6 abcA 11 abA 0 aA 0 aA
T21 53 cdB 14 abA 23 abA 24 aA 1 aA 10 abB 4 abA 8 bA
T3 46 bcdB 29 bcA 54 cA 46 aA 2 abA 3 aA 0 aA 1 abA
T41 27 abB 12 aA 45 abcB 20 aA 6 abcA 4 aA 5 abA 5 abA
T51 48 bcdB 30 bcA 27 abA 27 aA 2 abA 3 aA 1 aA 5 abA
T6 31 abcB 19 abA 42 abcA 31 aA 14 bcA 11 abA 5 abB 0 aA
T7 49 bcdB 31 bcA 21 aA 28 aA 6 abcA 3 aA 2 aA 2 abA
T8 17 aA 30 bcB 30 abcA 35 aA 18 cB 2 aA 1 aA 1 abA
T9 44 bcdA 42 cA 33 abcA 36 aA 9 abcA 20 bB 0 aA 2 abA
T101 40 bcdA 33 bcA 42 abcA 37 aA 20 cB 5 aA 14 bB 4 abA
T111 31 abcA 28 bcA 47 bcB 28 aA 17 Cb 7 abA 7 abA 7 abA
F Disinfestation (D) 38.12** 6.68* 1.78* 6.68*

F Processing (P) 6.85** 3.55** 4.45** 3.55**

F (D x P) 4.66** 2.80** 4.41** 2.80**

CV (%) 28.37 30.79 90.65 30.79

**; *Significant at 0.01 and 0.05 probability levels by F test, respectively; Means followed by the same lowercase letter in the column and same uppercase letter in the row do not differ by 
Tukey test at 0.05 probability level; ASM - Air and screen machine; GTI - First gravity table; GTII - Second gravity table; T1 - Control (not processed); T2 - Upper screen of the ASM (reject); 
T3 - Intermediate screen of the ASM; T4 - Bottom of the ASM (reject); T5 - Drift GTI (reject); T6 - Upper spout of GTI; T7 - Intermediate spout of GTI; T8 - Treating machine (T7 + dyeing); 
T9 - Upper spout of GTII; T10 - Intermediate spout of GTII (reject); T11 - Lower spout of GTII (reject); 1Processing steps that result in reject material by the company, for having more than 
90% of impurities in its composition

**; *Significant at 0.01 and 0.05 probability levels by F test, respectively; Means followed by 
the same lowercase letter in the column and same uppercase letter in the row do not differ by 
Tukey test at 0.05 probability level; ASM - Air and screen machine; GTI - First gravity table; 
GTII - Second gravity table; T1 - Control (not processed); T2 - Upper screen of the ASM 
(reject); T3 - Intermediate screen of the ASM; T4 - Bottom of the ASM (reject); T5 - Drift GTI 
(reject); T6 - Upper spout of GTI; T7 - Intermediate spout of GTI; T8 - Treating machine (T7 
+ dyeing); T9 - Upper spout of GTII; T10 - Intermediate spout of GTII (reject); T11 - Lower 
spout of GTII (reject); 1Processing steps that result in reject material by the company, for 
having more than 90% of impurities in its composition

Processing

steps (P)

Cladosporium sp. Cercospora sp.

(%)

T1 5 a 7 a
T21 9 ab 7 a
T3 3 a 10 ab
T41 20 b 9 ab
T51 11 ab 12 ab
T6 18 b 12 ab
T7 15 b 12 ab
T8 15 b 19 b
T9 18 b 15 ab
T101 18 b 14 ab
T111 16 b 14 ab
F Disinfestation (D) 38.55** 42.10**

F Processing (P) 4.70** 2.33*

F D x P 1.70ns 1.61ns

CV (%) 69.78 76.95

Table 2. Fungal incidence in seeds of Panicum maximum 
cv. ‘Tanzânia’ with and without superficial disinfestation 
with sodium hypochlorite, as a function of the processing 
steps



719Processing on the sanitary quality of seeds of Panicum maximum cv. ‘Tanzânia’

R. Bras. Eng. Agríc. Ambiental, v.21, n.10, p.715-720, 2017.

Regarding the effect of processing steps on the incidence 
of Cladosporium sp., it was possible to observe, in comparison 
to the control, that the reject from the bottom of the air and 
screen machine (T4) and all samples from the spouts of the two 
gravity tables (T6, T7, T9, T10 and T11) and from the treater 
(T8) have seeds with higher percentage of contamination. 
Therefore, in general, the processing favored the increase in 
the incidence of Cladosporium sp.

Some fungi, such as Cladosporium sp., are favored by 
mechanical damages to the seeds, as observed in soybean by 
Gomes et al. (2009). In the processing, the successive impacts and 
falls in the deposits of the machines cause injuries; therefore, these 
damages are cumulative and favor the access of microorganisms 
to the inside of the seeds (Carvalho & Nakagawa, 2012). This 
phenomenon must have favored the incidence of Cladosporium 
sp., because the final steps of the processing contain seeds with 
higher percentages of this pathogen.

The same phenomenon seems to have occurred with 
Cercospora sp., although it was only possible to observe 
higher significant incidence of this fungus in comparison to 
the control, due to the use of the treater to dye the seeds (T8). 
The increase in incidence of Cercospora sp. due to the treater 
(T8) may have been caused by the greater mechanical damage 
caused by the machine during the movement of the seeds 
soaked in the dyeing solution, favoring the access of the fungus.

Conclusions

1. Some processing steps can reduce the percentage of seeds 
of P. maximum cv. ‘Tanzânia’ contaminated with Phoma sp. 
and Helminthosporium sp. 

2. The processing, in general, can increase the percentage 
of seeds with Cladosporium sp. and Cercospora sp.

3. Phoma sp., Helminthosporium sp., Penicillium sp., 
Cladosporium sp. and Cercospora sp. are found inside and 
outside the seeds and can be disseminated by the processing 
machines.

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