Bioscience Journal  |  2022  |  vol. 38, e38023  |  ISSN 1981-3163 
 

1 

 

 
 

Gabriella Fernandes SILVA1 , Weisler Borges FERNANDES1 , Gabriel de Oliveira ROCHA2 ,  

Flávia de Oliveira Scarpino VAN CLEEF3 , Bruno Humberto Rezende CARVALHO2 ,  

Manoel Eduardo Rozalino SANTOS1  
 
1 Faculty of Veterinary Medicine, Federal University of Uberlandia, Uberlandia, Minas Gerais, Brazil.  
2 Postgraduate Program in Veterinary Medicine, Federal University of Uberlandia, Uberlandia, Minas Gerais, Brazil.  
3 Postgraduate Program in Animal Science, Estate University of São Paulo, Jaboticabal, São Paulo, Brazil.  

 
Corresponding author: 
Manoel Eduardo Rozalino Santos 
E-mail: manoel.rozalino@ufu.br 
 
How to cite: SILVA, G.F., et al. Does amount of cut vegetal residue on the canopy influence growth and the structural characteristics of 
marandu palisadegrass? Bioscience Journal. 2022, 38, e38023. https://doi.org/10.14393/BJ-v38n0a2022-54109 

 
Abstract 
The pasture mowing in late winter removes the old forage, improving the pasture structure in spring and 
summer. However, the residue after mowing can affect tillering, thus limiting forage production and the 
structural characteristics of pasture. We hypothesized that the high amount of cut vegetal residues on the 
plants in late winter causes a decrease in forage production and modifies the structural characteristics of 
the forage canopy during the spring and summer. The treatments were four cut vegetal residues (0; 2,000; 
4,000 and 8,000 t ha-1 of natural material) deposited on Urochloa brizantha cv. Marandu canopy in late 
winter. After that, the forage production and structure characteristics were evaluated during the spring and 
summer for two years. The complete randomized block design, with four replications, was used. The 
defoliation management was characterized by the adoption of pre- and post-cut heights of 25 and 15 cm, 
respectively. For both years, there was no effect of cut vegetal residue on all the characteristics evaluated. 
No variable was affected by the interaction cut vegetal residue amount × year of evaluation. The dead leaf 
blade percentage was greater in year 2 (6.9%) than in year 1 (3.5%). The average values of variables were 
live leaf blade percentage = 84.2%; live stem percentage = 8.7%; dead stem percentage = 1.9%; number of 
vegetative tiller = 653 tiller/m2; number of reproductive tiller = 5 tiller m-2. The forage production rate 
presented an average value of 46 kg/ha/day of dry matter. The cut vegetal residue amount of up to 8,000 
t/ha of natural material on the plants in late winter does not affect the forage production or modifies the 
structural characteristics of marandu palisadegrass during the subsequent spring and summer. 
 
Keywords: Brachiaria brizantha syn. Forage Production. Morphological Composition. Number of Tiller. 
Urochloa brizantha. 
 
1. Introduction 

In Brazil, Brachiaria brizantha syn. Urochloa brizantha (Hochst ex A Rich) Stapf. Cv. Marandu 
(marandu palisadegrass) is one of the most used grasses by ranchers for pasture formation. When using the 
deferment of pastures, it is common that marandu palisadegrass to have high forage mass, with high stems 
and dead material percentages in late winter (Silva et al. 2016), which may have negative effects on tillering 
(Santana et al. 2014).  

DOES AMOUNT OF CUT VEGETAL RESIDUE ON THE CANOPY 
INFLUENCE GROWTH AND THE STRUCTURAL 

CHARACTERISTICS OF MARANDU PALISADEGRASS? 

https://orcid.org/0000-0003-2761-7468
https://orcid.org/0000-0001-8373-1252
https://orcid.org/0000-0002-5557-2458
https://orcid.org/0000-0002-2153-8059
https://orcid.org/0000-0003-1844-0699
https://orcid.org/0000-0002-3668-4518


Bioscience Journal  |  2022  |  vol. 38, e38023  |  https://doi.org/10.14393/BJ-v38n0a2022-54109 

 

 
2 

Does amount of cut vegetal residue on the canopy influence growth and the structural characteristics of marandu palisadegrass? 

In order to avoid problems of tall grasses in late winter, mowing the sward can be used to rapidly 
remove older plants, which would stimulate the renewal of its population from the spring on and, 
consequently, it would provide the formation of a structure more available to animal apprehension and 
intake, improving the animal performance. In this context, Sousa et al. (2018), in a work with B. brizantha 
cv. Marandu, found that tall pasture (31.3 cm) and mowed to 8 cm at the late winter had a higher live leaf 
blade percentage and a lower stem dead percentage in the subsequent spring, compared to no-mowed tall 
pasture (31.4 cm). Thus, the sheep performance in spring, when all pastures were managed in continuous 
stocking, was 33% higher in the tall/mowed pasture than in the tall pasture in late winter. 

A large amount of cut vegetal residue on the lowered pasture can reduce the incidence of light at the 
bottom of the canopy and, therefore, inhibiting tillering (Matthew et al. 2000; Sbrissia et al. 2010), 
consequently reducing the forage production. The high carbon: nitrogen ratio of tropical forage grasses may 
also limit the mineralization of the plant residue, causing immobilization of nitrogen by the microorganisms 
in the soil. As a consequence, this nutrient may be unavailable to forage plants (Carneiro et al. 2008), which 
would also reduce tillering. In this sense, Santana et al. (2014) founded that deferred pastures of Brachiaria 
decumbens cv. Basilisk with lower heights (10 and 20 cm) at the beginning of the deferment period showed 
a greater renewal of tillers in the spring, in comparison to the tall, deferred pastures (30 and 40 cm). The 
authors argued that this response pattern was a consequence of the lower forage mass at late winter in the 
deferred pastures with 10 and 20 cm, in contrast to those deferred with 30 and 40 cm. 

Because of the large number of Brazilian farmers using mowing as a management strategy, which 
results in a large amount of cut vegetal residue on plant base, this study was developed to verify if the forage 
production and the structural characteristics of the marandu palisadegrass during spring and summer are 
modified in response to the deposition of cut vegetal residues after canopy cutting in late winter. We 
hypothesized that the high amount of cut vegetal residues on the plants in late winter causes a decrease in 
forage production and modifies the structural characteristics of the forage canopy during the spring and 
summer. 
 
2. Material and Methods 

The experiment was conducted from October to March and in two consecutive years (2014/2015 and 
2015/2016) on pasture with Brachiaria brizantha syn. Urochloa brizantha (Hochst ex A Rich) Stapf. cv. 
Marandu (marandu palisadegrass), in which 16 experimental plots (experimental units) of 9 m² each were 
demarked. The experimental area was located at the Experimental Capim-Branco Farm, at Federal University 
of Uberlândia, Uberlândia, MG, Brazil. The approximate geographical coordinates of the site are 18° 30' 
south latitude and 47° 50' west longitude of Greenwich, and its altitude is 776 m. The climate of Uberlândia, 
according to the Köppen classification, is Aw type, tropical savannah (Alvares et al. 2013), with well-defined 
dry (April to September) and rainy (October to March) seasons. Information on the climatic conditions during 
the experimental period was monitored at a meteorological station located 200 m away from the 
experimental area (Figure 1). 
 

 
Figure 1. Monthly rainfall and average of maximum, minimum and mean air temperatures on the 

experimental site from October to March of the two experimental years. 
 

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Precipita çã o pluvia l Tempera tura  média
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Precipita çã o pluvia l Tempera tura  média

Tempera tura  mínima Tempera tura  má xima



Bioscience Journal  |  2022  |  vol. 38, e38023  |  https://doi.org/10.14393/BJ-v38n0a2022-54109 

 
 

 
3 

SILVA, G.F., et al. 

In October of 2014, soil samples were collected from the experimental area to analyze the fertility 
level. The results were: pH in H2O: 6.0; P: 5.2 (Mehlich-1) and K: 156 mg dm-3; Ca2+: 5.4; Mg2+: 2.0 and Al3+: 
0.0 cmolc dm-3 (KCl 1 mol/L). Based on these results, liming and potassium fertilization was not necessary. 
Phosphate and nitrogen fertilization were performed after cutting the plants in October, applying 50 kg ha-
1 of N and P2O5. In December, an extra 50 kg ha-1 of N dose was applied. Urea and simple superphosphate 
were used as fertilizer sources. Fertilization was carried out with a single application in the late afternoon 
and coverage, according to the recommendations of Cantarutti et al. (1999) for a medium-level technological 
system. 

The experiment was conducted in a randomized complete block design with four replicates. The 
effects of deposition of cut vegetal residues (0; 2,000; 4,000 and 8,000 kg.ha-1 of natural material) at late 
winter on forage production and structural characteristics of marandu palisadegrass during the following 
spring and summer were evaluated. 

In early October, forage canopies were 37 and 43 cm in height in the first and second year of the 
study, respectively. In addition, forage mass (6,233 and 7,073 kg ha-1 of DM in the first and second year, 
respectively) consisted of the high stem (43.7% and 47% in the first and second year, respectively) and dead 
material (51.8% and 49.3% in the first and second year, respectively) percentages. Thus, to eliminate this old 
forage, all the plants were cut at 15 cm height. Subsequently, all cut plants were removed from above and 
between the canopies of the remaining plants. Then, the amounts of cut vegetal residue in each 
experimental unit, according to the treatments, were distributed evenly on the lowered plants. The cut 
vegetal residue consisted of the forage from above the 15 cm cut, with 81% DM and 78% DM in the first and 
second experimental years, respectively. 

As of October, and according to recommendations of Trindade et al. (2007), canopies were cut when 
the plants reached an average height of 25 cm, leaving a post-cut residue of 15 cm. This procedure occurred 
until March of each year. Three cuts were performed in the first year and four cuts in the second 
experimental year. 

All evaluations were performed before the cuts. The canopy height was measured with a graduated 
ruler, in 10 points of each plot, observing the distance from the soil surface to the highest living leaf in the 
canopy as the criterion. 

The forage production rate was estimated with a cut above 15 cm, using a quadrat of 0.5 m side per 
plot. Each sample was separated into the live leaf blade, dead leaf blade, and live stem and dead stem. These 
components were weighed, dried in a forced draught oven at 65°C to constant weight, and reweighed. With 
these data, the forage mass was calculated, as well as their morphological composition. The volumetric 
densities of the total forage mass and its morphological components were obtained by dividing the forage 
masses by the height of the cut stratum in the canopies. 

The number of vegetative and reproductive tillers was quantified using a 0.25 × 0.5 m rectangle, 
which was fixed to the soil, to count the tillers contained therein. Tiller was considered vegetative when it 
did not have the inflorescence nor the flag leaf, and reproductive when it was present. 

Data were subjected to analysis of variance at p < 0.05 using the MIXED procedure (mixed models) 
of SAS, version 9.2 (SAS Institute, Cary, NC, USA). The assumption of homogeneity of variances and normality 
was tested for each ANOVA. The models included the treatment (T), year (Y), and the treatment × year (T*Y) 
interaction as described below: 

Yij = m + Ti +Yj + (T * Y) + eijk 
 
3. Results 

A summary of the statistical analysis, with the factor’s significance (p value) for each variable 
response, is presented in Table 1. For all the variables analyzed, the same response pattern was observed in 
the two years of the research: the amount of cut vegetal residue on the plants did not influence the forage 
production and the structural characteristics of marandu palisadegrass. Additionally, no variable response 
was affected by the interaction treatment (amount of vegetal residue on the plants) × year of evaluation 
(Table 1).  

 



Bioscience Journal  |  2022  |  vol. 38, e38023  |  https://doi.org/10.14393/BJ-v38n0a2022-54109 

 

 
4 

Does amount of cut vegetal residue on the canopy influence growth and the structural characteristics of marandu palisadegrass? 

Table 1. Summary of the statistical analysis, with the factor’s significance (p value) for each variable 
response. 

Variable response 
Factor 

Treatment Year Treatment x Year 

Forage production rate 0.9006 0.1053 0.8768 

 Morphological composition in the produced forage (%) 

Live leaf blade 0.9682 0.1870 0.8071 
Dead leaf blade 0.6509 0.0071* 0.0539 

Live stem 0.5556 0.2000 0.4689 
Dead stem 0.2615 0.0807 0.6583 

 Volumetric density (kg cm-1 ha-1) 
Total forage 0.6200 0.0051* 0.7477 

Live leaf blade 0.6668 0.0001* 0.8990 
Dead leaf blade 0.6811 0.0010* 0.3638 

Live stem 0.9413 0.2034 0.9924 
Dead stem 0.4906 0.1878 0.8693 

 Tiller m-² 
Vegetative 0.9630 0.0504 0.4938 

Reproductive 0.2562 0.0699 0.6200 

*Statistical difference (p < 0.05). 

 
The year of evaluation had an effect on the dead leaf blade percentage and on the volumetric 

densities of total forage, leave leaf blade, and dead leaf blade (Table 1). The values of dead leaf blade 
percentage (6.9 and 3.5%), volumetric densities of total forage (163 and 142 kg/ha.cm), leave leaf blade (133 
and 123 kg/ha.cm) and dead leaf blade (15 and 6 kg/ha.cm) were greater in year 2 (2015/2016) than year 1 
(2014/2015). 

The average values of response variables were forage production rate = 46 kg.ha-1.day-1 of dry matter; 
live leaf blade percentage = 84.2%; live stem percentage = 8.7%; dead stem percentage = 1.9%; volumetric 
density of live stem = 12 kg/cm.ha; volumetric density of dead stem = 3 kg/cm.ha; number of vegetative tiller 
= 653 tiller/m2; and number of reproductive tiller = 5 tiller.m-2. 

 
4. Discussion 

The mean heights of pre-cut marandu-grass remained similar in the two experimental years (24.8 cm 
in the first year and 25.7 cm in the second year) since all plants were managed with the same criterion: 
lowered from 25 to 15 cm. This cut management was based on Trindade et al. (2007), who verified that the 
management characterized by the pre-grazing height corresponding to the interception of 95% of the light 
(25 cm) and the post-grazing height of 15 cm resulted in greater intake by cattle of live leaf blade than stems 
or dead material. Additionally, Giacomini et al. (2009) worked in the same experimental area as Trindade et 
al. (2007) and concluded that this pasture management resulted in the most favorable crop growth rate, 
relative growth rate, and net assimilation rate, particularly during the transition period between winter and 
spring. 

In the two experimental years, the structural characteristics of forage canopies were similar, 
regardless of the amount of cut vegetal residue on the plants. Again, this occurred due to the same 
management adopted in the pre- and post-cut conditions. The management of defoliation based on canopy 
height has been shown to be efficient in controlling and maintaining the structural characteristics of several 
tropical forage types of grass within the same time of year, being one of the main advantages and reasons 
for the recommendation of this grazing management criterion. In part, this occurs because, when the canopy 
height is controlled, its stage of development is controlled concomitantly, a process that is responsible for 
the generation of the plant structure (Araújo et al. 2015; Silveira et al. 2016; Pedreira et al. 2017).  

Thus, the forage produced was composed of a high percentage of live leaf blades (84.2%) in relation 
to the other plant morphological components (8.7 % of the live stem and 71% dead material). With the 
canopy cutting at 25 cm height, there is greater leaf growth, but low stem lengthening, and reduced leaf 
senescence, due to the fact that there is less light competition inside the canopy (Giacomini et al. 2009). 



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5 

SILVA, G.F., et al. 

The adequate canopy structure during spring and summer was possible due to the elimination of the 
old forage with the mowing in the late winter. When mowing is not carried out, it is probable that the old 
forage from winter would remain mixed with the new forage, from regrowth from spring. As a result, the 
structure of forage canopies is damaged. In this sense, Souza et al. (2015) evaluated in early summer the 
marandu palisadegrass structure after its mowing in the late winter, compared to pasture submitted only to 
grazing with sheep in continuous stocking (without mowing). These authors verified that mowing marandu 
palisadegrass in late winter maintained the pasture with a younger vegetative tiller population in the early 
summer. The presence of vegetative and young tillers can increase the forage production of the pasture 
because this category of tiller has greater tissue flow (Paiva et al. 2011). In addition, young tillers have better 
morphology (Santos et al. 2019) and nutritional value (Santos et al. 2006) than older tillers. 

Due to the low pre-cut height adopted (25 cm), the flowering of the plants became controlled, which 
had a low appearance of reproductive tillers. With this management, the plants were prevented from 
reaching greater heights and, consequently, greater development stages. When the inflorescence began to 
develop at the apex of the tillers, it was cut. So, the flowering did not manifest itself intensely. The reduced 
flowering can also be attributed to the flowering season of the marandu palisadegrass, which occurs in late 
summer, in February and March (Valle et al. 2010), when the evaluations were already finished. 

In both experimental years, the forage production rate was also not influenced by the amounts of 
cut vegetal residue. This indicates that the cut vegetal residue on the plants does not reduce the population 
density of tillers and forage production. A possible explanation for this result may be related to the reserve 
compounds accumulated in the plant. In low-growing conditions, such as in winter, the energy demand for 
the expansion and formation of new plant tissues is reduced, allowing photo-assimilates to be stored in 
reserve structures (da Silva et al. 2014). In this context, it is possible that marandu palisadegrass stocked the 
reserve compounds during winter and those used after lowering to 15 cm for the development of new tillers. 
This process may have been stimulated by the elimination of the apical meristem of the tiller after cutting. 
Therefore, the apical dominance of the tiller was eliminated and, consequently, many buds that previously 
had their activity inhibited have developed into tillers (Taiz and Zeiger 2013). 

Even without impair the number of tillers and forage production, the mowing of the forage canopy 
results in an increase in the cost of production, because it depends on machinery, fuel, and labor. Thus, as 
far as possible, it is important to manage the pastures so that, in late winter, they are low and do not need 
to be mowed to stimulate their regrowth and improve their structure from spring. Indeed, Santana et al. 
(2014), studying B. decumbens cv. Basilisk found that deferred and lower pasture in late winter had a greater 
appearance tiller rate in the spring when compared to higher pastures in late winter. 

The differences between the values of dead leaf blade percentage and volumetric densities of total 
forage, leave leaf blade and dead leaf blade between the years of evaluation may have been due to 
differences in the climatic conditions of these years. From October 2015 to March 2016, the rainfall was 34% 
higher than the rainfall of the same period of the previous year. The minimum air temperature also was 
13,2% greater in the first year than the second year (Figure 1).  

We hypothesized that the high amount of cut vegetal residues on the plants in late winter causes a 
decrease in forage production and modifies the structural characteristics of the marandu palisadegrass 
during the spring and summer. However, based on our results, we reject this hypothesis. 
 
5. Conclusions 

The amount of cut vegetal residue up to 8000 kg.ha-1 of natural matter on the plants in late winter 
does not affect the forage production neither modifies the structural characteristics of Brachiaria brizantha 
syn. Urochloa brizantha cv. Marandu during the following spring and summer. 
 
Authors' Contributions: SILVA, G.F.: acquisition of data, analysis and interpretation of data; FERNANDES, W.B.: acquisition of data, analysis and 
interpretation of data; ROCHA, G.O.: acquisition of data, analysis and interpretation of data, and critical review of important intellectual content; 
VAN CLEEF, F.O.S.: acquisition of data, analysis and interpretation of data; CARVALHO, B.H.E.: acquisition of data, analysis and interpretation of 
data, and critical review of important intellectual content; SANTOS, M.E.R.: conception and design, analysis and interpretation of data, drafting 
the article. All authors have read and approved the final version of the manuscript. 
 
Conflicts of Interest: The authors declare no conflicts of interest. 
 



Bioscience Journal  |  2022  |  vol. 38, e38023  |  https://doi.org/10.14393/BJ-v38n0a2022-54109 

 

 
6 

Does amount of cut vegetal residue on the canopy influence growth and the structural characteristics of marandu palisadegrass? 

Ethics Approval: Not applicable. 
 
Acknowledgments: The authors would like to thank the members of Grupo de Teste de Hipóteses em Forragicultura (TESTHFOR) of Universidade 
Federal de Uberlândia (UFU), for their contributions during the field trial setup. 
 

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Received: 24 April 2020 | Accepted: 2 March 2021 | Published: 31 March 2022 

 

 

 

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distribution, and reproduction in any medium, provided the original work is properly cited. 

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