M. Rafiq Islam1,2,3*
Sergio C. Garcia1,2,3
Nathu R. Sarker4Md. Ashraful Islam5
Cameron E. F. Clark1,2,3- 1Dairy Science Group, School of Life and Environmental Sciences, Faculty of Science, The University of Sydney, Camden, NSW, Australia
- 2Livestock Production and Welfare Group, School of Life and Environmental Sciences, Faculty of Science, The University of Sydney, Camden, NSW, Australia
- 3Sydney Institute of Agriculture, Faculty of Science, The University of Sydney, Camden, NSW, Australia
- 4Krishi Gobeshona Foundation, Bangladesh Agricultural Research Council Complex, Dhaka, Bangladesh
- 5Department of Dairy Science, Faculty of Animal Science and Veterinary Medicine, Patuakhali Science and Technology University, Barishal, Bangladesh
Napier grass (Pennisetum purpureum Schumach) comprises up to 80% of the cattle diet in many tropical and subtropical regions and is used primarily by smallholder farmers. Despite the grass’s high yield, resulting animal productivity from this grass is low. One of the key reasons for the low animal productivity of Napier grass is its low nutritive value under current management. Taken together, previous work has shown the current yield, crude protein (CP), and metabolisable energy (ME) of Napier grass to be 26 t dry matter (DM)/ha/year, 96 g/kg DM, and 8.7 MJ/kg DM, respectively, ranging from 2 to 86 t DM/ha/year, 9 to 257 g CP/kg DM, and 5.9 to 10.8 MJ ME/kg DM, respectively, suggesting an opportunity for significant improvement on both yield and nutritive value of this grass. The DM yield and nutritive value of this grass are inversely related, indicating a trade-off between yield and quality; however, this trade-off could be minimised by increasing sowing density and harvesting frequency. Available literature shows that this simple management strategy of increasing sowing density (50 cm × 40 cm) and harvesting frequency (11–12 harvests/year) provides 71 t DM/ha with 135 g/kg DM CP and 10.8 MJ ME/kg DM. This quality of Napier grass has the potential to increase both milk and meat production substantially in the tropics and subtropics, and the farmers will likely find this simple management acceptable due to the high yield obtained through this management. However, there is a paucity of work in this field. Therefore, management strategies to improve the nutritive value of Napier grass are required to increase milk and meat production in the tropics and subtropics and in doing so improve the food security of more than half of the global population living in these regions.
1 Introduction
Napier grass (Pennisetum purpureum Schumach) is the key diet of many elephants, and as such, is commonly known as elephant grass (Heuzé et al., 2020) but it may also be named as elephant grass due to its robust growth as opposed to other grass species. The taxon Cenchrus purpureus (Schumach) was also proposed in 2010 as a replacement for P. purpureum Schumach (Chemisquy et al., 2010). Whilst native to Sub-Saharan tropical Africa, the robust growth of this grass makes it one of the most popular and important forages for smallholder livestock farmers in the tropics and subtropics (Muktar et al., 2022). As a result, this grass has been introduced and naturalised in more than 100 tropical and subtropical countries throughout the world, particularly in Africa, Asia, and Latin America (Cook et al., 2005; Clayton et al., 2013), representing over 50% of the world’s population (Almeida, 2018). As such, Napier grass in the tropics and subtropics is as popular as perennial ryegrass (Lolium perenne) in the temperate region for animal production. The tropics is a vast area encompassing most of Central and South America, the Caribbean, Africa, India, Southeast Asia, Northern Australia, and most of the Pacific Islands. The subtropics encompass the Southern USA, the Mediterranean, Northern India, and China to the North and South Africa, Australia, and Southern Brazil to the South, where Napier grass or similar species are cultivated widely.
Napier grass is a world record holder grass for yield at 86 t dry matter (DM)/ha (Vicente-Chandler et al., 1959). This high-yielding characteristic makes it highly popular with smallholder farmers in tropical and subtropical farmers. Therefore, up to 80% of the forage ingested by cows in many tropical and subtropical countries is Napier grass (Kabirizi et al., 2015), and focus of farmers in these areas are high biomass yield (40%–59%; associated with plant height) and rapid re-growth (10%–26%). Smallholders typically harvest Napier grass when it reaches between 2 and 3 m in height (Zhang et al., 2010; Rengsirikul et al., 2013) in order to maximise yield from their small and fragmented areas of land. Under such growth priority-based current management, this grass currently provides low crude protein (CP; 70–100 g/kg DM) and metabolisable energy (ME; ~8 MJ/kg DM) for ruminant production (Cook et al., 2005), as there is a trade-off between growth and quality. Consequently, despite high yield, the low CP and ME of this grass obtained under current management cannot meet the protein and energy requirements of beef and dairy animals with consequences for both productivity (Muia et al., 2001a; Muia et al., 2001b). In addition, animals offered with such low-quality Napier grass usually require high amounts of grain-based concentrate to support milk and meat production. As such, due to the requirement of high-cost feeds (suitable for a monogastric production system), milk and meat production costs in Napier grass-growing countries are high (Roy et al., 2017) and often similar to or higher than the costs in international markets. Consequently, Napier grass-growing tropical and subtropical countries including Bangladesh are the main importers of beef and dairy products. As a result, there is insufficient consumption of animal-sourced food, and 815–821 million people in these regions suffer from hunger and remain undernourished (Islam et al., 2021). In contrast, ryegrass (L. perenne) offered to cattle in temperate countries usually contains high CP (240 g/kg DM) and ME (11 MJ/kg DM), which alone (i.e., without supplementation) can support up to 22 L of milk (Fulkerson, 2007). With such nutrient content in the grass, temperate countries are able to produce milk and meat abundantly at a low cost and are exporters of milk and meat. Fulkerson et al. (2010) reported that Kikuyu grass (Pennisetum clandestinum ex chiov), a C4 Pennisetum species similar to Napier grass, contains ~20 g CP/kg DM and ~10 MJ/kg DM at 16 days of harvest interval (HI; and 4.5 leaf stage), which could be taken as an ideal quality of Napier grass. The range of CP (45–243 g/kg DM) and ME (6.68–9.58 MJ/kg DM) reported by Habte et al. (2022) suggests that it is also possible to manage Napier grass in the tropics as high quality as ryegrass in the temperate zone, or similar to the Kikuyu grass (Fulkerson et al., 2010). Therefore, one option to reduce production costs and to increase the productivity of both milk and meat is to markedly improve the nutritive value of Napier grass to the level of ryegrass or Kikuyu grass through management such as inputs (e.g., fertiliser and water), variety, and agronomic management if tropical countries target to produce milk and meat at an internationally competitive rate and to become self-sufficient in both products. Islam et al. (2021) in a review reported that there is an immense opportunity to at least double the levels of ruminant food production through simple changes in Napier grass management from the same land area to improve food security and reduce malnutrition across vast tropical areas. Under this context, investigation and development of management strategies are needed to improve both yield and quality simultaneously to derive a feed that optimises animal production and health whilst minimising overall feed costs.
The main aim of this review is to identify and investigate different management factors to optimise Napier grass yield and nutritive value for animal production in subtropical/tropical regions. This review will cover yield and nutritive value from Napier grass under current management, identify gaps, and investigate ways to develop best management practice (BMP) to improve both yield and quality of this grass so that millions of smallholders living in hundreds of countries in the tropics and subtropics find ways to increase milk and meat from their animals.
2 Morphology and habitat of Napier grass
Napier is a C4 perennial grass in the Poaceae family. It can grow up to 7.5 m in height, and its extensive root system can penetrate up to 4.5 m, which makes it a highly drought-tolerant grass (Cook et al., 2005) and potentially important in carbon sequestration (Yang et al., 2019). It has a thick stem near the base (3-cm diameter) with long (up to 120 cm) and wide leaf blades (up to 5 cm). It has vigorous tillering, large leaf area, high solar radiation interception and radiation use efficiency, tall canopy (Kubota et al., 1994), and high photosynthetic rate and can maintain radiation use efficiency for a long time as compared to other C4 plants (Ito and Inaga, 1988). The average tiller per plant is 35 (Amin et al., 2016) to 100, depending on season and variety (Macoon et al., 2002). Napier’s leaf-to-stem ratio (L:S) is 0.57–1.63 (Halim et al., 2013), and dwarf varieties contain more leaves compared to stems. It grows well in full sunlight (Anderson et al., 2008) but can also grow under partial shade (Francis, 2004). Napier grass has all the fundamental factors for high productivity such as vigorous tillering, large leaf area, high photosynthetic rate, and tall canopy and has greater growth potential than maize (Ito and Inaga, 1988; Matsuda et al., 1991).
The common name “Napier grass” comprises approximately 140 species; over 300 accessions are available in various gene banks around the world (Negawo et al., 2017). It grows in a wide range of soil and climatic conditions ranging from low fertility acid soils to slightly alkaline soils (Hanna et al., 2004). However, it grows well on rich, deep, and well-drained loamy soils under a pH range of 4.5 to 8.2 (Duke, 1983; Cook et al., 2005). It spreads by rhizomes, and farmers propagate it vegetatively mainly by stem cuttings, as this grass cannot produce many effective seeds for propagation (Singh et al., 2013). Napier grass grows from sea level to 2,000 m of altitude and in rainfall ranging from 200 to 4,000 mm but grows best between 750 and 2,500 mm of rainfall per annum (Negawo et al., 2017). However, it does not tolerate prolonged waterlogging conditions lasting for more than 3 days (Nelson, 2005). It thrives in highlands and arid environments of Africa (Kabirizi et al., 2015; Kebede et al., 2017) mainly because of its extensive root system, and the grass grows well in saline conditions (Rahman and Talukder, 2015). The optimum temperature for its growth is 33°C during the day and 28°C during the night (Ferraris et al., 1986) and grows well in temperatures between 25°C and 40°C (Duke, 1983). Napier grass is highly popular with smallholder farmers because of its high yield, fast regrowth, drought tolerance, and suitability for cut-and-carry systems and is easy to establish. Napier grass can supply forage year-round for more than 8 years once established (Sollenburger et al., 1989); thus, it is a low-maintenance grass for smallholder tropical and subtropical farmers.
3 Current Napier grass production systems
Napier grass yield varies widely from 2 (Bogdan, 1977) to 86 t DM/ha/year (Vicente-Chandler et al., 1959) with a mean of 28 t DM/ha/year (Table 1). More than 50 t DM/ha/year from this grass is reported in many countries around the world (Table 1). High yield under experimental plot-level studies was recorded in the USA (78 t DM/ha; Goorahoo et al., 2005), China (74 t DM/ha; Zhang et al., 2010), Thailand (71 t DM/ha; Wijitphan et al., 2009), and Australia (50 t DM/ha; Ferraris, 1980). The maximum yield (86 t DM/ha; Vicente-Chandler et al., 1959) of this grass recorded is ~3 times greater than the maximum recorded yield of Kikuyu grass (30 t DM; 600 kg N/ha; Henzell, 1968) and perennial ryegrass (28 t DM/ha; Neal et al., 2010), which is widely used in the temperate region for successful commercial animal production system. Record high yield for Napier grass usually with non-limiting inputs is not surprising, as Garcia et al. (2014) estimated that the maximum theoretical and potential yields of C4 plants based on their highest photosynthesis are 259 and 191 t DM/ha/year, respectively. Yield of Napier grass at smallholder farmer (n = 33 farms) level was 57 t DM/ha/year (fresh yield, 314.5 t/ha/year, considering 180 g DM/kg; Roy et al., 2016), which is 66% of the recorded highest yield (86 t DM/ha/year; Vicente-Chandler et al., 1959).
Table 1 Available research (1980 to date) on Napier grass management and its yield and nutritive value1.
Despite high yield, the nutritional quality of Napier grass is low, which cannot often maintain the productivity of livestock. It contains low CP (95 g/kg DM) and ME (8.6 MJ/kg DM) but high acid detergent fibre (ADF; 388 g/kg DM) and neutral detergent fibre (NDF; 641 g/kg DM) (Table 1; Cook et al., 2005). However, there is a wide range of variation in nutritive value; for instance, CP (9–257 g/kg DM), ADF (256–645 g/kg DM), NDF (479–791 g/kg DM), and ME (5.9–10.8 MJ/kg DM) (Table 1). These wide ranges of nutritive value suggest that there is an opportunity to increase its quality to a considerable extent when managed properly. Therefore, it is necessary to understand different management factors that contribute to high or low yield and their impact on the nutritive value of this grass. Many factors such as inputs (nitrogen and water), variety, harvest management, and maturity affect the yield and nutritive value of grasses.
3.1 Nitrogen fertiliser
Napier, being a C4 grass, requires a high amount of fertiliser to achieve high yields. It requires 600 kg N/ha (Lotero et al., 1969) to 2,223 kg N/ha (Vicente-Chandler et al., 1959) to produce from 50 to 86 t DM/ha/year (Table 2). Goorahoo et al. (2005) recorded 78 t DM/ha/year by applying 542 kg N/ha but found that N uptake by this grass was 1,210 kg/ha. The estimated nitrogen use efficiency (NUE) of these top yielders ranged from 28 kg DM/kg N (Ferraris, 1980) to 144 kg DM/kg N (Goorahoo et al., 2005) (Table 3). These reports on N application and NUE suggest that the application of such a high amount of N fertiliser to Napier grass is worthy, as the highest NUE of Napier grass (Goorahoo et al., 2005; Table 3) was ~5 times greater than the highest NUE of Kikuyu grass (30 kg DM/kg N; Garcia et al., 2008). The mechanisms of how N fertiliser impacts N fixation and soil properties (Hu et al., 2021) including yield and forage quality (Delevatti et al., 2019) of C4 tropical grasses other than Napier grass have been discussed elsewhere. Overall, high yields and high NUE of Napier grass were generally achieved by using N fertiliser of 600 to 2,223 kg N/ha (depending on regions). This amount of N application is high, but Roy et al. (2016) reported that smallholder farmers in southern Bangladesh apply 1,128 kg N/ha/year to achieve 57 t DM/ha of Napier grass.
Table 2 Management practices of some highest- and lowest-yielding Napier grass in the literature.
Table 3 Nutrient use efficiency of some top-yielding Napier grass.
Nitrogen fertiliser also impacts the nutritive value of Napier grass. Several authors (Sarwar et al., 1999; Zewdu et al., 2002) reported that N fertiliser increased CP content, but Zewdu et al. (2002) did not observe any effect of N fertiliser on ash, ADF, NDF, cellulose, hemicellulose, calcium (Ca), phosphorous (P), in vitro DM digestibility (IVDMD), or ME content.
Nitrate nitrogen (NO3–N) and oxalate content of Napier grass have significant impacts on animal nutrition. Napier grass, on average, contains 0.5 g/kg DM NO3–N (0.1–0.8 g/kg DM; Table 1). It appears that the NO3–N content of this grass is at the safe level for animals, as Burrows and Tyrl (1989) reported that the safe limit of NO3–N is 2.5 g/kg DM and that forages exceeding 4.5 g/kg DM are highly toxic to animals. Adams et al. (2019) also suggested that the NO3–N content of forages causing acute toxicity generally ranges from 2.3 to 6.8 g/kg DM. Although there is no information on the impact of N fertiliser on the NO3–N content of this grass, Marais et al. (1987) reported Kikuyu grass applied with high N fertiliser (ammonium nitrate, 500 kg N/ha/year) at four leaf stages contained NO3–N 5.9 g/kg DM in the leaves and 8.8 g/kg DM in the whole plant. However, Kikuyu grass ad libitum in association with grain or concentrates had no issues when offered to lactating dairy cows over a long period of time (Fariña et al., 2011; Clark et al., 2015).
Napier grass usually contains 1–39 g/kg DM total oxalate and 53–60 g/kg DM silica (Table 1). Oxalate is known to have a negative impact on the body condition score (BCS), Ca, and P balance of cattle (Das et al., 2010; Rahman et al., 2014b). McKenzie et al. (1988) reported that plants containing 20 g/kg DM or more soluble oxalate may cause acute toxicity in ruminants. Rahman et al. (2010) reported a high total oxalate content (32–39 g/kg DM) and soluble oxalate (25–34 g/kg DM) in this grass, although oxalates were not affected by N (150 to 600 kg/ha) or potassium (K; 150 to 600 kg/ha) fertilisers. However, they (Rahman et al., 2010) grew Napier grass (cv. dwarf-late) in pots filled with sandy soils, which is likely to be attributed to the high oxalate content in this grass. Although rumen bacteria can adapt to a high level of soluble oxalate in the diet (Allison et al., 1977), sometimes, acute toxicity occurs even in adapted ruminants in diets containing relatively low oxalate (4–24 g/kg DM) concentrations (Marais, 2001). Huque et al. (2006) reported farmers complain that feeding fresh Napier grass results in weakness and poor BCS despite increased daily milk production. Das et al. (2010) reported that this weakness and poor BCS may be caused by the drainage of Ca in the form of calcium oxalate through the urine and faeces at a high rate (25 g/day). They reported that oxalate content reduces Ca and P balance in bulls, increases urinary excretion, and reduces water content in faeces. Rahman et al. (2014b) suggested supplementation of Ca source to optimise Ca balance and to improve the BCS of dairy cows. Nonetheless, they (Das et al., 2010; Rahman et al., 2014b) including Rao et al. (1993) reported positive Ca and P balance when Napier grass/silage was offered with concentrates or offered alone.
There is a paucity of data on the effect of N application (>300 kg N/ha) nutritive value, NO3–N, and oxalate content and their interactions with Napier grass. Further research is required on the impact of graded N fertiliser on the yield and nutritive value of this grass to optimise its yield and nutritive value.
3.2 Water
Napier grass requires a high amount of water for its growth. Habte et al. (2022) in a large study conducted in Ethiopia with 84 varieties reported varying yields of this grass between varieties, ranging from 2.7 (cv. 18662) to 68.1 (cv. 16791) t/ha/year (mean, 34.1 t/ha/year), but there was little yield difference within varieties due to water stress. For example, the yield of cv. 18662 was 2.7 and 2.9 t/ha and that of cv. 16791 was 67.4 and 68.1 t/ha under severe and moderate stress conditions. Severe and moderate water stress conditions were defined as 10 and 20% volumetric water content imposed in the dry season from November to May, but rainfed conditions prevailed in other seasons in both groups. Goorahoo et al. (2005) in a field experiment at Fresno, California, reported that drip irrigation at either 80% or 120% of daily measured reference evapotranspiration (ET) applied on 8-day intervals had no effect on yield. The average annual ET at Fresno is 1,264 mm (Almond Board of California, 2016), which indicates that 1,011 mm of water (80% of ET) is sufficient to optimise yield under drip irrigation. Thus, the water use efficiency (WUE) of this grass under drip irrigation is high, which is 6.7 t DM/megalitre (ML) water, even greater than the WUE of maize (4.3 t DM/ML water; Neal et al., 2011a, b). The estimated WUE of this grass was also high under farm conditions (3.8 t DM/ML water, calculated from Roy et al., 2016; mean annual rainfall, 1,422 mm, and estimated irrigation 84 mm per year; based on Meherpur Climate Bangladesh, 2023 climate data). This WUE of Napier grass on the farm is ~2–3 times greater than the WUE of Kikuyu grass (Garcia et al., 2008; 1.26–2.73 t DM/ML water). Therefore, Napier grass is a highly efficient grass in terms of its WUE both under experimental and on farm conditions.
Thus, Napier grass yields >50 t DM/ha/year with non-limiting N fertiliser (usually with >500 kg N/ha) and water (>1,100 mm) in many areas/regions of the tropics and subtropics (Table 3). Smallholder farmers who have access to such inputs or live in >1,100 mm rainfall zone should be able to optimise their land use by growing 50 t DM/ha/year or more compared to growing 2–10 t DM/ha/year (Bogdan, 1977) with low input in the same size of land. Thus, land-constraint smallholder farmers may increase land use efficiency, as they may grow more on the same land given that they have access to inputs.
Water also affects the quality of Napier grass varieties (Habte et al., 2022). These authors reported that Napier grass NDF, ADF, and lignin decreased but CP and ME increased under water stress conditions. The CP content was 139 and 121 g/kg DM and ME content was 8.15 and 7.65 MJ/kg DM for severe water stress and wet (rainfed plus 10%–20% water applied during the dry season from November to May) conditions, respectively. Water stress generally improves quality at the expense of yield, as water cannot serve as a carrier of nutrients required for plant growth (Islam et al., 2012).
3.3 Variety
Selecting the right variety can make a huge difference in increasing yield. Yield (t DM/ha) of different varieties under the same management condition ranged from 2.7 to 68.1 t (n = 84; Habte et al., 2022) in Ethiopia, 13 to 42 t (n = 80, Schneider et al., 2018) in Brazil, 17 to 42 t (n = 22, Kabirizi et al., 2015) in Uganda, 19 to 34 t (n = 3, Kabirizi et al., 2015) in Kenya, 13 to 34 t (n = 6, Khairani et al., 2013) in Japan, and 8 to 74 t (n = 18, Zhang et al., 2010) in China. This literature demonstrates that yield can simply be multiplied up to 25 times (Habte et al., 2022) by selecting the right variety. Napier grass varieties differ in plant height, leaf number, tiller number, L:S, and leaf area index (LAI; Ito et al., 1989; Zhang et al., 2010; Wangchuk et al., 2015), which impact both yield and nutritive value. Khairani et al. (2013) reported that the yield of varieties differed from 13 (cv. dwarf late heading) to 34 (cv. Wruk Wona) t DM/ha/year and also differed in plant height and LAI ranging from 160 to 429 cm and 2.5 to 8.5, respectively, and usually greater yield was associated with greater plant height. However, Gomide et al. (2015) reported that shorter varieties had a greater proportion of leaves compared to taller varieties. Zhang et al. (2010) in an experiment with 18 varieties reported that taller varieties contained a greater proportion of stem (including greater stem diameter) but fewer tillers as compared to the shorter varieties. As a result, the taller varieties (351-cm plant height) had seven times greater yield (60.6 t DM/ha/year; lines 033, 112, 121, and CK) as compared to the shorter varieties (107 cm; 8.3 t DM/ha/year; line 048), although shorter varieties contained a greater proportion of L:S (1.43:1) as compared to the taller varieties (0.35:1). Altogether, this indicates that the yield of shorter varieties is substantially lower compared to that of taller varieties, but shorter varieties are likely to be high in nutritive value as compared to the taller varieties because of their greater proportion of leaf. Land-constrained livestock farmers in the tropics likely to grow as much as possible for their livestock by compromising nutritive value unless a suitable variety that has a greater yield with a higher proportion of leaf is available.
Rengsirikul et al. (2013) conducted an experiment with eight varieties and reported wide differences in nutritive value between varieties. They reported differences in CP (62–125 g/kg DM), ash (77–116 g/kg DM), cellulose (354–473 g/kg DM), lignin (56–123 g/kg DM), and gross energy (GE, 15.0–16.4 MJ/kg DM) amongst eight varieties. Sileshi et al. (1996) also reported differences in CP (122–145 g/kg DM), ash (184–212 g/kg DM), NDF (563–642 g/kg DM), ADF (354–366 g/kg DM), lignin (48–52 g/kg DM), and IVDMD (714–748 g/kg) between three varieties (ILCA 14983, 14984, and X). Similarly, Amin et al. (2016) using four varieties (BLRI 4, Wruk Wona, hybrid Japan, and Mark Eron) reported differences in CP (104–137 g/kg DM), ash (91–116 g/kg DM), ADF (357–386 g/kg DM), total oxalate (1–8 g/kg DM), and ME (9.1–9.8 MJ/kg DM) between varieties. These data suggest that there are wide differences in yield and nutritive value between varieties and that farmers are likely to benefit by selecting the right varieties.
3.4 Harvest interval and maturity
The current harvest management of Napier grass is based on harvesting at different time intervals (weekly or monthly). Four to six harvests (cut and carry) per year are common (Kabirizi et al., 2015) to a maximum of 11 harvests at the experimental level (Wijitphan et al., 2009) available in the literature. All research on Napier grass in the literature showed increased yield with increased HI. Tessema et al. (2010) reported a 100% increase in yield (from 16 to 32 t DM/ha/year) when HI increased from 60 to 120 days and when plant height increased from 1 to 3 m, indicating that both yield and plant height increase with the increase in HI, and the increase in yield with increased HI is directly associated with the increased plant height. Wangchuk et al. (2015) also reported an increase in yield from 0.24 to 0.83 kg DM/plant with an increase in HI from 40 to 80 days when plant height increased from 1.5 to 2.6 m. However, this increased yield due to increased HI was associated with an 81% decrease in the proportion of leaf, which decreased from 5:1 to 0.9:1 (Wangchuk et al., 2015), indicating a substantial likely loss in quality with increased HI.
Although increased HI increases yield, researchers (Sileshi et al., 1996; Goorahoo et al., 2005) reported that increased HI (maturity) decreases both CP and energy (by increasing fibre) content of Napier grass (Table 4). MaChado et al. (2008) reported that organic matter digestibility (OMD) decreases from 75% to 55% with increasing maturity from 33 to 93 days. Similarly, Sarwar et al. (1999) also reported that younger Napier grass contained greater CP, dry matter digestibility (DMD) in vivo, and NDF digestibility (NDFD) in situ compared to older grasses. This reduction in nutritive value with increased maturity has an impact on animal production. Peyraud and Delagarde (2013) reported that any reductions in OMD of grass on offer will likely result in a reduction of milk yield and that a 1% reduction of OMD on grass offered involves a reduction of 1 kg milk/day. It appears that the greatest decrease (>50%) in CP (Figure 1) and ME and the increase in fibre occur within 56 days (from 14 to 56 days) of HI (Table 4). After that (from 56 to 70 days of HI), CP (Figure 1) and NDF decreased or increased at a slower rate (2%–7%), although ADF and lignin contents may increase 14%–27% with little or no change in the ME content of this grass. This is possible because the growth threshold diminishes at this stage (~56 days), and probably farmers, through their experiences, understand this growth threshold of Napier grass and thus harvest 6–7 times/year (i.e., 60 days of HI). Data from Tessema et al. (2010) indicate an increase in ADF (14%) and lignin (18%) and a decrease in 34% CP, which led to a decrease in digestibility in vitro by 11% with an increased HI from 60 to 120 days. These researchers did not find any substantial increase in NDF content or any differences in NDF and ADF digestibility in vitro with increased HI from 60 to 90 days, although CP decreased with increased HI. These data corroborate with others in the literature (Sileshi et al., 1996; Goorahoo et al., 2005) who found that NDF and ME do not change substantially, although ADF (0%–14%) and lignin (27%) increase and CP decreases (3%–7%) with increased HI from 56 to 70 days. This suggests that increasing HI from 60 to 120 days may change chemical composition at a slower rate compared to HI from 14 to 56 days in Napier grass. The sharp decline in CP from 14 (or 28) to 56 days of HI is likely due to the mobilisation of N [and water-soluble carbohydrate (WSC)] from the leaf for plant development (Islam et al., 2012) or regrowth (Islam et al., 2020), which ultimately increases the fibre and reduces ME content. These results suggest that a better harvest management strategy is required to optimise the nutritive value of this grass for milk or meat production.
Table 4 Impact of harvest interval on nutritive value of Napier grass.
Figure 1 Relationship between harvest interval and crude protein content of Napier grass.
Soluble oxalate content in Napier grass is usually reduced with increased HI, affected by location, and generally, the leaf contains a greater amount of oxalate than the stem (Table 5; Pathmasiri et al., 2014). Nitrate–N content in young (0.7 g/kg DM) Napier grass (age not defined) was greater compared to that in mature (0.5 g/kg DM) Napier grass and was greater in the stem compared to the leaf (Sidhu et al., 2011), but these values were within the safe range for animals (Adams et al., 2019). However, Pathmasiri et al. (2014) reported high NO3–N content in Napier grass particularly in the stem (15–24 g/kg DM) at 14 days of HI, although its leaf contains ~3 times lower NO3–N (6–7 g/kg DM) than the stem (Table 5). These levels of NO3–N in Napier grass at 14 days of HI (Pathmasiri et al., 2014) are above its recommended level in forages (2.3–6.8 g/kg DM), causing acute toxicity in animals. However, Pathmasiri et al. (2014) found that NO3–N content reduces dramatically at 28 days of HI and falls far below the safe level, particularly in the leaf fraction (0.3 g/kg DM). This suggests that Napier grass to be offered before 28 days of HI should be subjected to careful monitoring of NO3–N.
Table 5 Impact of harvest interval and site of growth on nitrate–N and soluble oxalate in Napier grass plant fractions.
However, harvesting based on fixed weekly (or daily) intervals (i.e., HI) may not be a good option due to differences in the seasonal influence of growth on Napier grass, as growth is slow in winter and high in summer. Similarly, harvesting based on plant height may also be misleading, as height is subject to change due to differences in input, management, and environmental factors. Therefore, a management strategy regarding the timing of harvest for Napier grass is required, similar to that for Kikuyu (Fulkerson and Donaghy, 2001; Garcia et al., 2014) and perennial ryegrass (Fulkerson et al., 1998) in order to maintain both yield and quality of this grass. Fulkerson and Donaghy (2001) developed the timing of harvest/grazing of grasses based on the number of leaves and reported that an ideal timing of harvesting Kikuyu and perennial ryegrass is 4.5 and 3 leaf stages, respectively, to maintain their yield and quality for animal production purposes. Fariña et al. (2011) reported that HI (or grazing interval) at these leaf stages were 26, 42, 21, and 18 days for autumn, winter, spring, and summer, respectively, for Kikuyu grass. Based on this leaf stage principle, Fariña et al. (2011) recorded 21–24 t DM/ha/year from Kikuyu grass containing 220–240 g CP/kg DM and 9.0–10.7 MJ ME/kg DM. Therefore, investigation on the impact of leaf stage-based frequent cut and carry on regrowth on Napier grass is essential to maintain both yield and quality of this grass. In addition, information on the impact of defoliation height (plant height at harvest) and severity (height from ground level at which plants are cut) of this grass is essential, as they affect subsequent regrowth (Islam et al., 2020). Moreover, research to quantify how much trade-off between leaf and stem (or yield and quality) is also required, as there is no information on this issue for Napier grass. Once this information is available, there will be opportunities to increase the yield of this grass under better management for the smallholder farmers of the tropics and subtropics provided that inputs and conditions are adequate. Therefore, it is necessary to develop a BMP for Napier grass so that the land-constrained smallholder farmers in the vast tropics and subtropics can grow more in their small patch of land for animal production and to increase milk and meat.
3.5 Plant density
Wijitphan et al. (2009) demonstrated an increased planting density from 50 cm × 100 cm to 40 cm × 50 cm increased yield substantially from 56 to 71 t DM/ha/year when harvested at 35 days of HI. They reported that greater plant density ensured greater tiller number per unit area and possibly greater radiation use, which helped to increase yield. Such increased frequency of harvesting (i.e., 10–11 times/year when harvested at 35 days of HI) has the potential not only to supply year-round grass for farmers but also to increase quality compared to the current four to six harvests. In addition, because of harvesting at 35 days of HI, they (Wijitphan et al., 2009) also achieved a relatively high CP (135 g/kg DM) and ME (calculated, 10.8 MJ/kg DM; IVDMD 75.5%) in both density treatments. It is likely that increasing plant density compensates for yield (which is currently obtained by plant height or HI) and that frequent harvesting compensates for quality (particularly CP and energy). This suggests that a management strategy of increased plant density and HI can increase both yield and quality.
4 Potential in saline and temperate zone
4.1 Salinity
Salinity is one of the leading threats in the agricultural system. Irrigated lands, which produce one-third of the world’s food, are particularly prone to salinity, and 20%–50% of the world’s irrigation schemes are salt affected (Munns, 2011). As such, over 6% of the land in the world is salt affected, and this is increasing through agricultural practices (Bromham and Bennet, 2014). However, grasses particularly, C4 grasses, are more salt tolerant compared to cereal crops or C3 grasses. Bromham and Bennet (2014) in an extensive experiment reported that C4 grasses are more salt tolerant compared to C3 grasses. They reported that greater water use efficiency of C4 photosynthesis lowers the flux of water and salts through the plant per growth unit and reduces the ionic stress through decreasing transpiration rates, which can reduce the amount of salt in C4 grasses. Napier grass as a high water use-efficient C4 grass grows well in saline areas (Rahman and Talukder, 2015). Rahman and Talukder (2015) reported a maximum of 45.5 t DM/ha/year (204 t fresh/ha, 22.3% DM) when grown between 5 and 10 deci-Siemens/m saline areas of coastal Bangladesh and harvested at 40–45 days of HI. As the WUE of Napier grass is greater than many C4 grasses (Section 3.2), there is great potential for this grass in the coastal areas for livestock production.
4.2 Temperate region
High yield from this grass can be achieved in temperate regions through strategic management. Ito and Inaga (1988) compared the yield of Napier grass between temperate Tokyo and tropical Miyazaki in Japan and reported that 39 t DM/ha/year can be achieved in Tokyo during summer months compared to 52 t DM/ha/year in Miyazaki. They reported lower temperature and radiation and shorter day lengths in Tokyo in winter compared to Miyazaki, but temperatures were similar between the sites in summer. Despite similar temperatures between sites in summer, plant growth rate owing to their increased LAI was greater in summer in Tokyo than in Miyazaki (Ito et al., 1989).
However, Napier grass is winter dormant and sensitive to frost, so little growth occurs at <15°C, and its growth ceases at 10°C (Duke, 1983). Therefore, there is a shortage of grass for the smallholder farmers in dry winter seasons particularly during September–October months, but excessive growth occurs in wet and rainy seasons (Njarui et al., 2010) in the tropics. We observed farmers in Bangladesh and found that taller varieties grow better in winter than shorter varieties, as shorter varieties start flowering at shorter heights in winter. Thus, farmers do not obtain sufficient grass from shorter varieties for their livestock in dry winter months when there is a shortage of grass. Research is required to select breeds or varieties that perform well at low temperatures, contain a greater proportion of leaf for quality but do not compromise yield (or less compromising), and make hay or silage from this grass at the time of excess growth.
5 Best management practice
This review identified two simple best management practices that have the potential to minimise the trade-off between yield and nutritive value for Napier grass. These are increasing plant density and harvesting frequency. With these two simple management practices, it was possible to achieve 71 t DM/ha with the potential to supply year-round forage (10–11 harvests/year; Wijitphan et al., 2009). In addition to yield, Napier grass under these management conditions contained CP 135 g/kg DM and 10.8 ME MJ/kg DM compared to 70–80 g/kg DM CP and <8 MJ/kg DM ME obtained under traditional management practices. Fariña et al. (2011), using a C4 grass, Kikuyu (Pennisetum spp.), reported that when grass and forages contained 205 g CP/kg DM and 10.2 MJ ME/kg DM and yielded 26 t DM/ha, Holstein cows were able to produce 27,835 L milk/ha. Napier grass through increased plant density and harvesting frequency maintains greater yield and quality similar to that of Kikuyu grass required for high milk yield. Therefore, more research is required to investigate Napier grass yield and quality using various inputs, varieties, and management in association with plant density and harvesting frequency.
6 Knowledge gaps
The following knowledge gaps were identified:
6.1 Inputs
There is no information on the impact of N fertiliser (>300 kg/ha) and water on major nutrients such as CP, energy, fibre, and critical nutrients such as nitrate–N, oxalate, and minerals, e.g., sodium, calcium, and phosphorous of this grass.
6.2 Variety
Varieties differ widely in yield, nutritive value, plant height, leaf-to-stem ratio, and nutritive value. There is no information on what characteristics should be considered to obtain both yield and quality and which varieties can overcome seasonal growth limitations, particularly in winter to ensure a year-round supply of quality forages.
6.3 Harvest interval and yield and nutritive value trade-off
Smallholder farmers obtain high yields from Napier grass through increased harvest interval and at the expense of high maturity under current management, which usually limits quality. A compromise between yield and nutritive value is required to obtain high nutritive value grass to support the production of different classes of animals. However, there is little or no information on management strategies on how to increase both yield and nutritive value together of this grass by identifying the ideal time of harvesting such as leaf stage, frequency of harvest, defoliation height and severity, nitrogen, or soluble carbohydrate in the stubble for regrowth.
6.4 Plant density management
A recent experimental plot work reported that high yield and relatively high quality of Napier grass can be obtained by increasing plant density and harvest frequency. More research is required both on the station and on the farm to optimise both yield and quality for different classes of animals.
6.5 Potential in saline and temperate zones
Limited evidence shows that Napier grass can be grown with relatively high yield in moderate saline areas and temperate areas during summer. More research is required in these areas.
Little or no attention has been paid to improving Napier grass’s nutritive value or to simultaneously improve yield and nutritive value. With this focus, the yield of Napier grass has increased through time at the expense of quality. Consequently, Napier grass has been portrayed as poor-quality grass, and alongside this is the inability of this grass to maintain milk or meat production. However, research on C4 grass conducted in Australia and elsewhere showed that both yield and quality of C4 grass can be improved through strategic management. Through simple changes in management such as increasing plant density and harvesting frequency (Wijitphan et al., 2009), we propose a new best management practice for Napier grass that has the potential to increase both yield and quality. This new management focused on both quality and yield has the potential to increase both milk and meat production substantially across the vast tropical and subtropical countries around the world.
7 Conclusions
Our review identified that Napier grass is abundant and widely popular amongst smallholder farmers in the tropics and subtropics mainly for its high biomass yield, but its quality is poor under current management, which cannot support milk or meat production of different classes of animals. Its nutritive value for animal production has been overlooked because of the complex trade-off between yield and quality. There is a lack of information on management strategies on how to increase both the yield and nutritive value of this grass. Thus, a better management strategy is required to obtain both high yield and nutritive value. All the evidence gathered in this review indicates that Napier grass’s yield and nutritive value may be improved by two simple management: increasing plant density and harvesting frequency. However, there is only one study that reported full season data on this management strategy of increased plant density and that harvesting at 35 days of harvest interval that provides 71 t DM/ha with 135 g/kg DM CP and 10.8 MJ ME/kg DM may be tested for milk and meat production. Therefore, more research on this strategy of increased plant density and harvest interval is required as to whether CP content can be increased to 170-180 g/kg DM required for lactating animals. Thus, research on the development of the “Best Management System” of Napier grass is required to optimise its yield and quality in order to optimise smallholder animal production in the tropics and subtropics, which may play a significant role in the food security of these vast areas in the world. Emphasis on developing management guidelines should be given on maximising/optimising yield and nutritive value without compromising each other. This is important, as it is hard for the land-constrained smallholder farmers to sacrifice yield. If a compromise is required, it needs to be quantified to obtain quality grass to increase milk and meat yield.
Author contributions
MI: Conceptualization, Data curation, Formal Analysis, Funding acquisition, Investigation, Methodology, Project administration, Resources, Validation, Visualization, Writing – original draft. SG: Conceptualization, Funding acquisition, Investigation, Methodology, Project administration, Resources, Supervision, Validation, Writing – review & editing. NS: Writing – review & editing. MI: Writing – review & editing. CC: Conceptualization, Data curation, Formal Analysis, Funding acquisition, Investigation, Methodology, Project administration, Resources, Software, Supervision, Validation, Visualization, Writing – review & editing.
Funding
The author(s) declare that no financial support was received for the research, authorship, and/or publication of this article.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
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References
Adams, R. S., McCarty, T. R., Hutchinson, L. J. (2019) Prevention and control of nitrate toxicity in cattle. DAS 92-107, The Pennsylvania State University. Available at: https://extension.psu.edu/prevention-and-control-of-nitrate-toxicity-in-cattle (Accessed August 25, 2023).
Aganga, A. A., Omphile, U. J., Thema, T., Baitshotlhi, J. C. (2005). Chemical composition of Napier grass (Pennisetum purpureum) at different stages of growth and Napier grass silages with additives. J. Biol. Sci. 5 (4), 493–496. doi: 10.3923/JBS.2005.493.496
Allison, M. J., Littledike, E. T., James, L. F. (1977). Changes in ruminal oxalate degradation rates associated with adaptation of oxalate ingestion. J. Anim. Sci. 45, 1173–1179. doi: 10.2527/jas1977.4551173x
Almeida, A. M. (2018). Improving animal production and health in the tropics—the challenge of humankind. Trop. Anim. Hlth Prod. 50, 1177–1179. doi: 10.1007/s11250-018-1647-y
Almond Board of California (2016) Irrigation scheduling using evapotranspiration. California almonds. Almond Board of California, Modesto, CA, USA. Available at: https://www.almonds.com/sites/default/files/irrigation_scheduling_using_et%5B1%5D.pdf (Accessed August 28, 2023).
Amin, R., Sarker, N. R., Ali, M. Y., Hashem, M. A., Khatun, M. (2016). Study on cutting intervals on biomass yield, nutritive value and their oxalate content of different high yielding napier (P. purpureum) cultivars. Asian Australas. J. Biosci. Biotechnol. 1 (1), 100–107. doi: 10.3329/aajbb.v1i1.61542
Anderson, W. F., Dien, B. S., Bradson, S. K., Peterson, J. D. (2008). Assessment of Bermuda grass and bunch grasses as feed stocks for conversion of ethanol. Appl. Biochem. Biotechnol. 145, 13–21. doi: 10.1007/s12010-007-8041-y
Anindo, D. O., Potter, H. L. (1994). Seasonal variation in productivity and nutritive value of Napier grass at Muguga, Kenya. East Afr. Agric. Forest. J. 59 (3), 177–185. doi: 10.1080/00128325.1994.11663194
Aroeira, L. J. M., Lopes, F. C. F., Deresz, F., Verneque, R. S., Dayrell, M. S., de Matos, L. L., et al. (1999). Pasture availability and dry matter intake of lactating crossbred cows grazing elephant grass (Pennisetum purpureum, Schum.). Anim. Feed Sci. Technol. 78, 313–324. doi: 10.1016/S0377-8401(98)00270-3
Aswanimiyuni, A., Mohamad Noor, I., Haryani, H., Norfadzrin, F., Nurzillah, M. (2018). A comparison of feed intake and growth performance of goats fed Guinea grass and Napier grass. Malay. J. Vet. Res. 9 (2), 13–18. https://www.cabdirect.org/cabdirect/abstract/20193004775
Bogdan, A. V. (1977). Tropical pasture and fodder plants (grasses and legumes). Longman 1977 London New York p, 475. Available at: https://www.cambridge.org/core/journals/experimental-agriculture/article/tropical-pasture-and-fodder-plants-grasses-and-legumes-by-a-v-bogdan-london-longman-1977-pp-475-1200/E8390D14E1C9DB84C78F74412791996A
Bromham, L., Bennet, T. H. (2014). Salt tolerance evolves more frequently in C4 grass lineages. J. Evol. Biol. 27, 653–659. doi: 10.1111/jeb.12320
Brown, D., Salim, M., Chavalimu, E., Fitzhugh, H. (1988). Intake, selection, apparent digestibility and chemical composition of Pennisetum purpureum and Cajanus cajan foliage as utilized by lactating goats. Small Rum. Res. 1, 59–65. doi: 10.1016/0921-4488(88)90044-2
Bureenok, S., Yuangklang, C., Vasupen, K., Schonewille, J. T., Kawamoto, Y. (2012). The effects of additives in Napier grass silages on chemical composition, feed intake, nutrient digestibility and rumen fermentation. Asian-Aust. J. Anim. Sci. 25 (9), 1248–1254. doi: 10.5713/ajas.2012.12081
Burrows, G. E., Tyrl, R. J. (1989). Plants causing sudden death in livestock. Vet. Clin. North Am. Food Anim. Pract. 5, 263–289. doi: 10.1016/S0749-0720(15)30976-2
Castillo, M. S., Sollenberger, L. E., Vendramini, J. M. B., Woodard, K. R., O’Connor, G. A., Newman, Y. C., et al. (2010). Municipal biosolids as an alternative nutrient source for bioenergy crops: I. Elephant grass biomass production and soil responses. Agron. J. 102, 1308–1313. doi: 10.2134/agronj2010.0106
Chemisquy, A., Giussani, L. M., Scataglini, M. A., Kellogg, E. A., Morrone, O. (2010). Phylogenetic studies favour the unification of Pennisetum, Cenchrus and Odontelytum (Poaceae): a combined nuclear, plastid and morphological analysis, and nomenclatural combinations in. Ann. Bot. 106 (1), 107–130. doi: 10.1093/aob/mcq090
Chen, C. S., Wang, S. M., Hsu, J. T. (2006). Factors affecting in vitro true digestibility of Napiergrass. Asian-Aust. J. Anim. Sci. 19 (4), 507–513. doi: 10.5713/ajas.2006.507
Clark, C. E. F., Farina, S. R., Garcia, S. C., Islam, M. R., Kerrisk, K., Fulkerson, W. J. (2015). A comparison of conventional and automatic milking system pasture utilization and pre-and post-grazing pasture mass. Grass Forage Sci. 71, 153–159. doi: 10.1111/gfs.12171
Clayton, W. D., Govaerts, R., Harman, K. T., Williamson, H., Vorontsova, M. (2013). World checklist of Poaceae (Richmond, UK: Royal Botanic Gardens, Kew).
Cook, B. G., Pengelly, B. C., Brown, S. D., Donnelly, J. L., Eagles, D. A., Franco, M. A., et al. (2005). Tropical forages. CSIRO, DPI&F (Qld), CIAT and ILRI, Brisbane, Australia. https://www.feedipedia.org/node/1689
Danes, M. A. C., Chagas, L. J., Pedroso, A. M., Santos, F. A. P. (2013). Effect of protein supplementation on milk production and metabolism of dairy cows grazing tropical grass. J. Dairy Sci. 96, 407–419. doi: 10.3168/jds.2012-5607
Das, N. G., Huque, K. S., Alam, M. R., Sultana, N., Amanullah, S. M. (2010). Effects of oxalate intake on calcium and phosphorus balance in bulls fed Napier silage (Pennisetum purpureum). Bang. J. Anim. Sci. 39, 58–66. doi: 10.1021/acssuschemeng.9b06637
Delevatti, L. M., Cardoso, A. S., Barbero, R. P., Leite, R. G., Romanzini, E. P., Ruggieri, A. C., et al. (2019). Effect of nitrogen application rate on yield, forage quality, and animal performance in a tropical pasture. Sci. Rep. 9, 7596. doi: 10.1038/s41598-019-44138-x
Duke, J. A. (1983) Handbook of Energy Crops. The Handbook of Energy Crops exists only as an electronic publication on the New CROPS web site. Available at: https://www.hort.purdue.edu/newcrop/duke_energy/dukeindex.html (Accessed 12 July 2023).
Fariña, S. R., Garcia, S. C., Fulkerson, W. J. (2011). A complementary forage system whole-farm study: forage utilisation and milk production. Anim. Prod. Sci. 51, 460–470. doi: 10.1071/AN10242
Ferraris, R. (1980). Effect of harvest interval, nitrogen rates and application times on pennisetum purpureum grown as an agro-industrial crop. Field Crops Res. 3, 109–120. doi: 10.1016/0378-4290(80)90016-7
Ferraris, R., Mahony, M. J., Wood, J. T. (1986). Effect of temperature and solar radiation on the development of dry matter and attributes of Elephant grass (Pennisetun purpureum Schum.). Aust. J. Agric. Res. 37, 621–632. doi: 10.1071/AR9860621
Ferreira, D. J., Lana, R. P., Zanine, A. M., Santos, E. M., Veloso, C. M., Ribeiro, G. A. (2013). Silage fermentation and chemical composition of elephant grass inoculated with rumen strains of Streptococcus bovis. Anim. Feed Sci. Technol. 183, 22–28. doi: 10.1016/j.anifeedsci.2013.04.020
Filho, J. C. M. N., Fondevila, M., Urdaneta, A. B., Ronquillo, M. G. (2000). In vitro microbial fermentation of tropical grasses at an advanced maturity stage. Anim. Feed Sci. Technol. 83, 145–157. doi: 10.1016/S0377-8401(99)00123-6
Francis, J. K. (2004). “Pennisetum purpureum schumacher,” in Wildland shrub of the United States and its Territories: thamnic descriptions: volume 1. Gen. Tech. Rep. IITF-GTR-26. Ed. Francis, J. K. (USDA Forest Service, International Institute of Tropical Forestry), 830 p. https://www.feedipedia.org/node/20066
Fulkerson, B., Griffiths, N., Sinclair, K., Beale, P. (2010). Milk production from kikuyu grass based pastures. Primefact 1068. Primefact at: https://www.dpi.nsw.gov.au/primefacts
Fulkerson, W. J. (2007). Perennial ryegrass (Lolium perenne) (FutureDairy, The University of Sydney: Technote).
Fulkerson, W. J., Donaghy, D. J. (2001). Plant-soluble carbohydrate reserves and senescence- key criteria for developing an effective grazing management system for ryegrass-based pastures: a review. Aust. J. Exp. Agric. 41, 261–275. doi: 10.1071/EA00062
Fulkerson, W. J., Slack, K., Hennessy, D. W., Hough, G. M. (1998). Nutrients in ryegrass (Lolium spp), white clover (Trifolium repens) and kikuyu (Pennisetum clandestinum) pastures in relation to season and stage of re-growth in subtropical environment. Aust. J. Exp. Agric. 38, 227–240. doi: 10.1071/EA97161
Garcez, B. S., Morais, S. C. M., MaChado, F. A., Nicolini, C., Macedo, E. O., AO, Ó. (2018). Ruminal degradation of elephant grass silages added with faveira pods. Acta Scient. Anim. Sci. v. 40, e39946. doi: 10.4025/actascianimsci.v40i1.39946
Garcia, S. C., Fulkerson, W. J., Brookes, S. U. (2008). Dry matter production, nutritive value and efficiency of nutrient utilisation of a complementary forage rotation compared to a grass pasture system. Grass Forage Sci. 63, 284–300. doi: 10.1111/j.1365-2494.2008.00636.x
Garcia, S. C., Islam, M. R., Clark, C. E. F., Marin, P. (2014). Kikuyu based pasture for dairy production: a review. Crop Pasture Sci. 65, 787–797. doi: 10.1071/CP13414
Gomide, C. A.M., Chaves, C. S., Ribeiro, K. G., Sollenberger, L. E., Paciullo, D. S. C., Pereira, T. P., et al. (2015). Structural traits of elephant grass (Pennisetum purpureum Schum.) genotypes under rotational stocking strategies. Afric. J. Range Forage Sci. 32, 51–57. doi: 10.2989/10220119.2014.930929
Goorahoo, D., Cassel, F. S., Adhikari, D., Rothberg, M. (2005). “Update on elephant grass research and its potential as a forage crop,” in Proceedings, California Alfalfa and Forage Symposium, 12-14 December 2005, Visalia, CA, UC Cooperative Extension, Agronomy Research and Extension Center, Plant Sciences Department, University of California, Davis 95616. https://www.researchgate.net/publication/237416127_UPDATE_ON_ELEPHANT_GRASS_RESEARCH_AND_ITS_POTENTIAL_AS_A_FORAGE_CROP
Gusmao, J. O., Danes, M. A. C., Casagrande, D. R., Bernardes, T. F. (2018). Total mixed ration silage containing elephant grass for small-scale dairy farms. Grass Forage Sci. 73, 717–726. doi: 10.1111/gfs.12357
Gwayumba, W., Christensen, D. A., McKinnon, J. J., Yu, P. (2002). dry matter intake, digestibility and milk yield by Friesian cows fed two Napier grass varieties. Asian-Aust. J. Anim. Sci. 15 (4), 516–521. doi: 10.5713/ajas.2002.516
Habte, E., Teshome, A., Muktar, M. S., Assefa, Y., Negawo, A. T., MaChado, J. C., et al. (2022). Productivity and feed quality performance of napier grass (Cenchrus purpureus) genotypes growing under different soil moisture levels. Plants 11, 2549. doi: 10.3390/plants11192549
Halim, R. A., Shampazuraini, S., Idris, A. B. (2013). Yield and nutritive quality of nine Napier grass varieties in Malaysia. Mal. J. Anim. Sci. 16 (2), 37–44. https://www.cabdirect.org/cabdirect/abstract/20143084258
Hanna, W. W., Chaparro, C., Mathews, B., Burns, J. C., Sollenberger, L. E., Carpenter, J. R. (2004). “Perennial pennisetums,” in Warm-season (C4) grasses. Madison: ASA/CSSA/ SSSA, vol. 2004 . Eds. Moser, L. E., Byron, L. B., Sollenberger, L. E., 503–535.
Heuzé, V., Tran, G., Giger-Reverdin, S., Lebas, F. (2020). Available at: https://www.feedipedia.org/node/395.
Hu, J., Richwine, J. D., Keyser, P. D., Li, L., Yao, F., Jagadamma, S., et al. (2021). Nitrogen fertilization and native C4 grass species alter abundance, activity, and diversity of soil diazotrophic communities. Front. Microbiol. 12. doi: 10.3389/fmicb.2021.675693
Huque, K. S., Amanullah, S. M., Islam, M. M. (2006). Impacts of fodder crop introduction into farming systems of selected areas on smallholder dairy development in Bangladesh. Annu. Rep. Bangladesh Livestock Res. Institute Savar Dhaka 1341, 107–109.
Huque, K. S., Rahman, M. M., Talukder, A. I. (2001). Study on forage crop production on sloping land in Bangladesh. Asian-Aust. J. Anim. Sci. 14 (7), 956–959. doi: 10.5713/ajas.2001.956
Islam, M. R., Garcia, S. C., Horadagoda, A. (2012). Effects of irrigation and rates and timing of nitrogen fertilizer on dry matter yield, proportions of plant fractions of maize and nutritive value and in vitro gas production characteristics of whole crop maize silage. Anim. Feed Sci. Technol. 172, 125–135. doi: 10.1016/j.anifeedsci.2011.11.013
Islam, M. R., Garcia, S. C., Horadagoda, A., Kerrisk, K., Clark, C. E. F. (2020). Management strategies for forage rape (Brassica napus L. cv Goliath): Impact on dry matter yield, plant reserves, morphology and nutritive value. Grass Forage Sci. 75 (1), 96–110. doi: 10.1111/gfs.12462
Islam, M. R., Garcia, S. C., Sarker, N. R., Roy, B. K., Sultana, N., Clark, C. (2021). “The role of napier grass (Pennisetum purpureum schumach) for improving ruminant production efficiency and human nutrition in the tropics,” in Climate Change and Livestock Production: Recent Advances and Future Perspectives. Eds. Sejian, V., Chauhan, S., Devaraj, C., Malik, K., Bhatta, R. (Singapore: Springer). doi: 10.1007/978-981-16-9836-1_13
Islam, M. R., Saha, C. K., Sarker, N. R., Jalil, M. A., Hasanuzzaman, M. (2003). Effect of Variety on proportion of botanical fractions and nutritive value of different Napiergrass (Pennisetum purpureum) and relationship between botanical fractions and nutritive value. Asian-Aust. J. Anim. Sci. 16 (6), 837–842. doi: 10.5713/ajas.2003.837
Ito, K., Inaga, S. (1988). Studies on dry matter production of napiergrass. IlI. Areas and light-photosynthesis relations in single leaves from different positions on a stem at Tokyo and Miyazaki. Jpn. J. Crop Sci. 57, 431–437. doi: 10.1626/jcs.57.431
Ito, K., Murata, Y., Inanaga, S., Ohkubo, T. (1988). Studies on the dry matter production of Napiergrass II. Dry matter productivities at six sites in southern area of Japan. Japan J. Crop Sci. 57 (3), 424–430. doi: 10.1626/JCS.57.424
Ito, K., Takaki, K., Misumi, M. (1989). Relations between leaf area index and crop growth rate of napiergrasses (Pennisetum purpureum Schumach) under different planting densities. J. Jpn. Grassl. Sci. 34, 257–263. doi: 10.14941/grass.34.257
Kabirizi, J., Muyekho, F., Mulaa, M., Msangi, R., Pallangyo, B., Kawube, G., et al. (2015). Napier grass feed resource: production, constraints and implications for smallholder farmers in Eastern and Central Africa., 1–173. Available at: https://www.researchgate.net/publication/281556114_NAPIER_GRASS_FEED_RESOURCE_PRODUCTION_CONSTRAINTS_AND_IMPLICATIONS_FOR_SMALLHOLDER_FARMERS_IN_EAST_AND_CENTRAL_AFRICA
Kaitho, R. J., Kariuki, J. N. (1998). Effects of Desmodium, Sesbania and Calliandra supplementation on growth of dairy heifers fed Napier grass basal diet. Asian-Aust. J. Anim. Sci. 11 (6), 680–684. doi: 10.5713/ajas.1998.680
Kariuki, J. N., Gachuiri, C. K., G.K. Gitau, G. K., Tamminga, S., Van Bruchem, J., Muia, J. M. K., et al. (1998). Effect of feeding napier grass, lucerne and sweet potato vines as sole diets to dairy heifers on nutrient intake, weight gain and rumen degradation. Livest. Prod. Sci. 55, 13–20. doi: 10.1016/S0301-6226(98)00127-4
Kariuki, J. N., Gitau, G. K., Gachuiri, C. K., Tamminga, S., Muia, J. M. K. (1999). Effect of supplementing napier grass with desmodium and lucerne on DM, CP and NDF intake and weight gains in dairy heifers. Livest. Prod. Sci. 60, 81–88. doi: 10.1016/S0301-6226(99)00035-4
Kebede, G., Feyissa, F., Assefa, G., Alemayehu, M., Mengistu, A., Kehaliew, A., et al. (2017). Agronomic performance, dry matter yield stability and herbage quality of Napier grass (Pennisetum purpureum (L.) Schumach) accessions in different agro-ecological zones of Ethiopia. J. Agric. Crop Res. 5 (4), 49–65. Available at: http://sciencewebpublishing.net/jacr/archive/2017/October/Abstract/Kebede%20et%20al.htm
Khairani, L., Ishii, Y., Idota, S., Utamy, R. F., Nishiwaki, A. (2013). Variation in growth attributes, dry matter yield and quality among 6 genotypes of Napier grass for biomass in year of establishment in southern Kyushu, Japan. Asian J. Agric. Res. 7 (1), 15–25. doi: 10.3923/AJAR.2013.15.25
Khota, W., Pholsen, S., Higgs, D., Cai, Y. (2018). Comparative analysis of silage fermentation and in vitro digestibility of tropical grass prepared with Acremonium and Tricoderma species producing cellulases. Asian-Australas. J. Anim. Sci. 31 (12), 1913–1922. doi: 10.5713/ajas.18.0083
Knoll, J. E., Anderson, W. F., Malik, R., Hubbard, R. K., Strickland, T. C. (2013). Production of Napiergrass as a bioenergy feedstock under organic versus inorganic fertilization in the Southeast USA. Bioenerg. Res. 6, 974–983. doi: 10.1007/s12155-013-9328-1
Kozloski, G. V., Perottoni, J., Ciocca, M. L. S., Rocha, J. B. T., Raiser, A. G., Sanchez, L. M. B. (2003). Potential nutritional assessment of dwarf elephant grass (Pennisetum purpureum Schum. cv. Mott) by chemical composition, digestion and net portal flux of oxygen in cattle. Anim. Feed Sci. Technol. 104, 29–40. doi: 10.1016/S0377-8401(02)00328-0
Kozloski, G. V., Perottoni, J., Sanchez, L. M. B. (2005). Influence of regrowth age on the nutritive value of dwarf elephant grass hay (Pennisetum purpureum Schum. cv. Mott) consumed by lambs. Anim. Feed Sci. Technol. 119, 1–11. doi: 10.1016/j.anifeedsci.2004.12.012
Kubota, F., Matsuda, Y., Agata, W., Nada, K. (1994). The relationship between canopy structure and high productivity in Napier grass, Pennisetum purpureum Schumach. Field Crops Res. 38, 105–1l0. doi: 10.1016/0378-4290(94)90004-3
Lotero, J. C., Ramirez, A. P., Herrera, G. P. (1969). Fuentes, dosis y motodos de aplicacion de nitrogeno en pasto elefante. Revta Inst. Colomb. Agropec. 4(3), 147–157. https://eurekamag.com/research/014/678/014678410.php
Lounglawan, P., Lounglawan, W., Suksombat, W. (2014). Effect of cutting interval and cutting height on yield and chemical composition of king Napier grass (Pennisetum purpureum x Pennisetum americanum). APCBEE Proc. 8, 27–31. doi: 10.1016/j.apcbee.2014.01.075
MaChado, P. A. S., Valadares Filho, S., de, C., Valadares, R. F. D., Detmann, E., Paixao, M. L., et al. (2008). Nutritional evaluation of elephantgrass at different regrowth ages. Rev. Bras. Zootec. 37 (6), 1121–1128. doi: 10.1590/S1516-35982008000600024
Macoon, B., Sollenberger, L. E., Moore, J. E. (2002). Defoliation effects on persistence and productivity of four Pennisetum spp. genotypes. Agron. J. 94, 541–548. doi: 10.2134/agronj2002.5410
Magalhães, K. A., Valadares Filho, S. C., Detmann, E., Diniz, L. L., Pina, D. S., Azevedo, J. A. G., et al. (2010). Evaluation of indirect methods to estimate the nutritional value of tropical feeds for ruminants. Anim. Feed Sci. Technol. 155, 44–54. doi: 10.1016/j.anifeedsci.2009.10.004
Manyawu, G. J., Chakoma, C., Sibanda, S., Mutisi, C., Chakoma., I. C. (2003c). The effect of harvesting interval on herbage yield and nutritive value of Napier grass and hybrid Pennisetums. Asian-Aust. J. Anim. Sci. 16 (7), 996–1002. doi: 10.5713/ajas.2003.996
Manyawu, G. J., Sibanda, S., Chakoma., I. C., Mutisi, C., Ndiweni, P. N. B. (2003a). The Intake and palatability of four different types of Napier grass (Pennisetum purpureum) silage fed to sheep. Asian-Aust. J. Anim. Sci. 16 (6), 823–829. doi: 10.5713/ajas.2003.823
Manyawu, G. J., Sibanda, S., Mutisi, C., Chakoma, C., Chakoma., I. C., Ndiweni, P. N. B. (2003b). The Effect of pre-wilting and incorporation of maize meal on the fermentation of Bana grass silage. Asian-Aust. J. Anim. Sci. 16 (6), 843–851. doi: 10.5713/ajas.2003.843
Marais, J. P. (2001). Factors affecting the nutritive values of kikuyu grass (Pennisetum purpureum) - a review. Trop. Grassl. 35, 65–84. https://www.cabdirect.org/cabdirect/abstract/20013080632
Marais, J. P., Figenschou, D. L., Dennison, C. (1987). The accumulation of nitrate in Kikuyu grass (Pennisetum clandestinum Hochst). South Afric. J. Plant Soil. 4 (2), 82–88. doi: 10.1080/02571862.1987.10634946
Matsuda, Y., Kubota, F., Agata, W., Ito, K. (1991). Analytical study on high productivity in napier grass (Pennisetum purpureum SCHUMACH.) 1. Comparison of the characteristics of dry matter production between napier grass and corn plants. J. Japan. Grassl. Sci. 37 (1), 150–156. Available at: https://www.semanticscholar.org/paper/Analytical-Study-on-High-Productivity-in-Napier-%3A-Yoshinobu-%E7%BE%A9%E4%BF%A1/de428b223e3feeb4d987f03c8ab3d8d2b5ffa1ee
McKenzie, R. A., Bell, A. M., Storie, G. J., Keenan, F. J., Cornack, K. M., Grant, S. G. (1988). Acute oxalate poisoning of sheep by buffelgrass (Cenchrus ciliaris). Aust. Vet. J. 65, 26. doi: 10.1111/j.1751-0813.1988.tb14926.x
Meherpur Climate Bangladesh (2023) Data and graphs for weather and climate in Meherpur. Available at: https://en.climate-data.org/asia/Bangladesh/khulna-division/meherpur-59282 (Accessed 28 August, 2023).
Muia, J. M. K., Tamminga, S., Mbunga, P. N., Kariuki, J. N. (2001a). Effect of supplementing Napier Grass (Pennisetum purpureum) with poultry litter and sunflower meal based concentrates on feed intake and rumen fermentation in Friesian steers. Anim. Feed Sci. Technol. 92, 113–126. doi: 10.1016/S0377-8401(01)00221-8
Muia, J. M. K., Tamminga, S., Mbunga, P. N., Kariuki, J. N. (2001b). Rumen degradation and estimation of microbial protein yield and intestinal digestion of Napier Grass (Pennisetum purpureum) and various concentrates. Anim. Feed Sci. Technol. 93, 177–192. doi: 10.1016/S0377-8401(01)00282-6
Muinga, R. W., Thorpe, W., Topps, J. H. (1992). Voluntary food intake, live-weight change and lactation performance of crossbred dairy cows given ad libitum Pennisetum purpureum (Napier grass var. Bana) supplemented with leucaena forage in the lowland semi-humid tropics. Anim. Prod. 55 (3), 331–337. doi: 10.1017/S0003356100021024
Muinga, R. W., Thorpe, W., Topps, J. H. (1993). Lactational performance of Jersey cows given napier fodder (Pennisetum purpureum) with and without protein concentrates in the semihumid tropics. Trop. Anim. Hlth Prod. 25, 118–128. doi: 10.1007/BF02236519
Muktar, M. S., Habte, E., Teshome, A., Assefa, Y., Negawo, A. T., Lee, K.-W., et al. (2022). Insights into the genetic architecture of complex traits in Napier Grass (Cenchrus purpureus) and QTL regions governing forage biomass yield, water use efficiency and feed quality traits. Front. Plant Sci. 12. doi: 10.3389/fpls.2021.678862
Munns, R. (2011). Plant adaptations to salt and water stress: differences and commonalities. Plant responses to drought and salinity stress: developments in a post-genomic era. Adv. Bot. Res. 57, 1–32. doi: 10.1016/B978-0-12-387692-8.00001-1
Muyekho, F. N., Munyasi, J. W., Mwendia, S., Auma, E. O., Ngode, L., Ajanga, S., et al. (2015). “Evaluation of Napier stunt and smut tolerant napier grass clones and alternative fodder grasses for forage yield in Kenya,” in Napier grass feed resource: production, constraints and implications for smallholder farmers in Eastern and Central Africa. Ed. Kabirizi, J., et al, 2015 75–77. Available at: https://www.researchgate.net/publication/281556114_NAPIER_GRASS_FEED_RESOURCE_PRODUCTION_CONSTRAINTS_AND_IMPLICATIONS_FOR_SMALLHOLDER_FARMERS_IN_EAST_AND_CENTRAL_AFRICA
Neal, J. S., Fulkerson, W. J., Campbell, L. C. (2010). Differences in yield among annual forages used by the dairy industry under optimal and deficit irrigation. Crop Past. Sci. 61, 625–638. doi: 10.1071/CP092161836-0947/10/080625
Neal, J. S., Fulkerson, W. J., Hacker, R. B. (2011a). Differences in water use efficiency among annual forages used by the dairy industry under optimum and deficit irrigation. Agric. Water Managem. 98, 759–774. doi: 10.1016/j.agwat.2010.11.011
Neal, J. S., Fulkerson, W. J., Sutton, B. G. (2011b). Differences in water-use efficiency among perennial forages used by the dairy industry under optimum and deficit irrigation. Irrig. Sci. 29, 213–232. doi: 10.1007/s00271-010-0229-1
Negawo, A. T., Teshome, A., Kumar, A., Hanson, J., Jones, C. S. (2017). Opportunities for Napier grass (Pennisetum purpureum) improvement using molecular genetics. Agronomy 7, 28. doi: 10.3390/agronomy7020028
Nelson, J. (2005). Response to organic and inorganic fertilization, model development and evaluation for Napier grass (Pennisetum purpureum, Schum.) (The University of Edinburgh: PhD Thesis).
Njarui, D. M. G., Gatheru, M., Wambua, J. M., Nguluu, S. N., Mwangi, D. M., Keya, G. A. (2010). Challenges in milk processing and marketing among dairies in the semi-arid tropical Kenya. Livest. Res. Rural Dev. 22 (2), 2010. Available at: https://www.researchgate.net/publication/297812008_Challenges_in_milk_processing_and_marketing_among_dairies_in_the_semi-arid_tropical_Kenya
Nsahlai, I. V., Osuji, P. O., Umunna, N. N. (2000). Effect of form and of quality of feed on the concentrations of purine derivatives in urinary spot samples, daily microbial N supply and predictability of intake. Anim. Feed Sci. Technol. 85, 223–238. doi: 10.1016/S0377-8401(00)00138-3
Parsons, D., Van, N. H., Malau-Aduli, A. E. O., Ba, N. X., Phung, L. D., Lane, P. A., et al. (2012). Evaluation of a nutrition model in predicting performance of Vietnamese cattle. Asian-Aust. J. Anim. Sci. 25 (9), 1237–1247. doi: 10.5713/ajas.2012.12036
Pathmasiri, P. G. R. P., Premalal, G. C. C., Nayananjalie, W. A. D. (2014). Accumulation of oxalate and nitrate in hybrid Napier var. CO -3 (Pennisetum perpureum X P. americarnum) and Wild Guinea grass (Panicum maximum). Rajarata Univ. J. 2, 27–32. Available at: http://repository.rjt.ac.lk/handle/123456789/30
Pieterse, P. A., Rethman, N. F. G. (2002). The influence of nitrogen fertilisation and soil pH on the dry matter yield and forage quality of Pennisetum purpureum and P. purpureum×P. glaucum hybrids. Trop. Grassl. 36, 83–89. https://www.tropicalgrasslands.info/public/journals/4/Historic/Tropical%20Grasslands%20Journal%20archive/PDFs/Vol_36_2002/Vol_36_02_02_pp83_89.pdf
Peyraud, J. L., Delagarde, R. (2013). Managing variations in dairy cow nutrient supply under grazing. Animal 7 (s1), 57–67. doi: 10.1017/S1751731111002394
Rahman, M. M., Abdullah, R. B., Khadijah, W. E. W., Nakagawa, T., Akashi, R. (2013). Effect of palm kernel cake as protein source in a concentrate diet on intake, digestibility and live weight gain of goats fed Napier grass. Trop. Anim. Health Prod. 45, 873–878. doi: 10.1007/s11250-012-0300-4
Rahman, M. M., Abdullah, R. B., Wan Khadijah, W. E., Nakagawa, T., Akashi, R. (2014a). Feed intake and growth performance of goats offered Napier grass (Pennisetum purpureum) supplemented with concentrate pellet and soya waste. Sains Malays. 43, 967–971. doi: 10.1080/09712119.2014.963095
Rahman, M. Z., Ali, M. Y., Huque, K. S., Talukder, M. A. I. (2014b). Effect of di-calcium phosphate on calcium balance and body condition score of dairy cows fed Napier grass. Bang. J. Anim. Sci. 43 (3), 197–201. doi: 10.3329/bjas.v43i3.21648
Rahman, M. M., Ishii, Y., Niimi, M., Kawamura, O. (2010). Interactive effects of nitrogen and potassium fertilization on oxalate content in Napiergrass (Pennisetum purpureum). Asian-Aust. J. Anim. Sci. 23 (6), 719–723. doi: 10.5713/ajas.2010.90541
Rahman, M. M., Rahman, M. R., Nakagawa, T., Abdullah, R. B., Wan Khadijaha, W. E., Akashi, R. (2015). Effects of wet soya waste supplementation on the intake, growth and reproduction of goats fed Napier grass. Anim. Feed Sci. Technol. 199, 104–112. doi: 10.1016/j.anifeedsci.2014.11.0070377-8401
Rahman, M. Z., Talukder, M. A. I. (2015). Production and nutritional quality of high yielding fodders in the coastal areas for ruminant. Agriculturists. 13 (1), 1–8. doi: 10.3329/agric.v13i1.26541
Ramadhan, A., Njunie, M. N., Lewa, K. K. (2015). Effect of planting material and variety on productivity and survival of Napier Grass (Pennisetum purpureum schumach) in the coastal lowlands of Kenya. East Afric. Agric. Forest. J. 8 (1), 40–45. doi: 10.1080/00128325.2015.1040647
Rao, B. V., Parthasarathy, M., Krishna, N. (1993). Effect of supplementation with tree leaves on intake and digestibility of hybrid napier (NB-21) grass in Nellore Brown sheep. Anim. Feed Sci. Technol. 44, 265–274. doi: 10.1016/0377-8401(93)90052-L
Rengsirikul, K., Ishii, Y., Kangvansaichol, K., Sripichitt, P., Punsuvon, V., Vaithanomsat, P., et al. (2013). Biomass yield, chemical composition and potential ethanol yields of 8 cultivars of Napiergrass (Pennisetum purpureum Schumach.) harvested 3-monthly in central Thailand. J. Sust. Bioenergy Syst. 3, 107–112. doi: 10.4236/jsbs.2013.32015
Roy, B. K., Haque, K. S., Huda, N. (2017). Comparative meat production performance evaluation of buffalo with cattle at different ages. J. Buffalo Sci. 6(3), 66–73. doi: 10.6000/1927-520X.2017.06.03.1
Roy, B. K., Sarker, N. R., Alam, M. K., Huque, K. S. (2016). Existing production and marketing system of fodder under Meherpur district as livelihood activity. Bang. J. Livest. Res. 19 (1-2), 24–32. doi: 10.3329/bjlr.v19i1-2.26424
Ruiz, T. M., Sanchez, W. K., Staples, C. R. (1992). Comparison of 'Matt' dwarf Elephantgrass silage and corn silage for lactating dairy cows. J. Dairy Sci. 75, 533–543. doi: 10.3168/jds.S0022-0302(92)77790-X
Sarwar, M., Khan, M. N., Saeed, M. N. (1999). Influence of nitrogen fertilization and stage of maturity of mottgrass (Pennisetum purpureum) on its composition, dry matter intake, ruminal characteristics and digestion kinetics in cannulated buffalo bulls. Anim. Feed Sci. Technol. 82, 121–130. doi: 10.1016/S0377-8401(99)00087-5
Schank, S. C., Chynoweth, D. P., Turick, C. E., Mendoza, P. E. (1993). Napiergrass genotypes and plant parts for biomass energy. Biom. Bioenergy 4 (1), 1–7. doi: 10.1016/0961-9534(93)90021-U
Schneider, L. S. A., Daher, R. F., Menezes, B. R. S., Freitas, R. S., Sousa, L. B., Silva, V. B., et al. (2018). Selection of Elephant-Grass genotypes for forage production. J. Agric. Sci. 10 (12), 148–156. doi: 10.5539/jas.v10n12p148
Shem, M. N., Mtengeti, E. J., Luaga, M., Ichinohe, T., Fujihara, T. (2003). Feeding value of wild Napier grass (Pennisetum macrourum) for cattle supplemented with protein and/or energy rich supplements. Anim. Feed Sci. Technol. 108, 15–24. doi: 10.1016/S0377-8401(03)00167-6
Sidhu, P. K., Bedi, G. K., Mahajan, V., Sharma, S., Sandhu, K. S., Gupta, M. P. (2011). Evaluation of factors contributing to excessive nitrate accumulation in fodder crops leading to ill-health in dairy animals. Toxicol. Int. 18 (1), 22–26. doi: 10.4103/0971-6580.75848
Sileshi, Z., Owen, E., Dhanoa, M. S., Theodorou, M. K. (1996). Prediction of in situ rumen dry matter disappearance of Ethiopian forages from an in vitro gas production technique using a pressure transducer, chemical analyses or in vitro digestibility. Anim. Feed Sci. Technol. 61, 73–87. doi: 10.1016/0377-8401(96)00948-0
Singh, B. P., Singh, H. P., Obeng, E. (2013). “Elephant grass,” in Biofuel Crops: Production, Physiology and Genetics, vol. 2013 . Ed. Singh, B. P. (Fort Valley, GA, USA: CAB International: Fort Valley State University), 271–291.
Skerman, P. J., Riveros, F. (1990). Tropical grasses. Food and Agriculture Organisation, 1990. Forage Plants, pp. 163. https://books.google.com.au/books/about/Tropical_Grasses.html?id=tCydcW6MK60C&redir_esc=y
Sollenburger, L. E., Prine, G. M., Ocumpaugh, W. R., Hanna, W. W., Jones, C. S., Jr., Schank, S. C., et al. (1989). Registration of 'mott' dwarf elephant grass. Crop Sci. 29, 827–828. doi: 10.2135/cropsci1989.0011183X002900030062x
Tamada, J., Yokot, a H., Ohshima, M., Tamaki, M. (1999). Effects of additives, storage temperature and regional difference of ensiling on the fermentation quality of Napier grass (Pennisetum purpureum Schum.) silage. Asian-Aust. J. Anim. Sci. 12 (1), 28–35. doi: 10.5713/ajas.1999.28
Tessema, Z. (2008). Effect of plant density on morphological characteristics, yield and chemical composition of Napier grass (Pennisetum purpureum (L.) Schumach). East Afr. J. Sci. 2, 55–61. doi: 10.4314/eajsci.v2i1.40365
Tessema, Z., Baars, R. M. T. (2004). Chemical composition, in vitro dry matter digestibility and ruminal degradation of Napier grass (Pennisetum purpureum (L.) Schumach.) mixed with different levels of Sesbania sesban (L.) Merr. Anim. Feed Sci. Technol. 117, 29–41. doi: 10.1016/j.anifeedsci.2004.08.001
Tessema, Z. K., Mihret, J., Solomon, M. (2010). Effect of defoliation frequency and cutting height on growth, dry-matter yield and nutritive value of Napier grass (Pennisetum purpureum (L.) Schumach). Grass Forage Sci. 65, 421–430. doi: 10.1111/j.1365-2494.2010.00761.x
Vicente-Chandler, J., Silva, S., Figarella, J. (1959). The effect of nitrogen fertilization and frequency of cutting on the yield and composition of three tropical grasses. Agron. J. 51, 202–206. doi: 10.2134/agronj1959.00021962005100040006x
Vieira, R. A.M., Pereira, J. C., Malafaia, P. A. M., de Queiroz, A. C. (1997). The influence of elephant-grass (Pennisetum purpureum Schum., Mineiro variety) growth on the nutrient kinetics in the rumen. Anim. Feed Sci. Technol. 67, 151–161. doi: 10.1016/S0377-8401(96)01130-3
Wamalwa, N. I. E., Midega, C. A. O., Ajanga, S., Omukunda, N. E., Ochieno, M. W. D., Muyekho, F. N., et al. (2015). “Screening Napier accessions for resistance/tolerance to NSD using the loop mediated isothermal amplification of DNA (LAMP),” in Napier grass feed resource: production, constraints and implications for smallholder farmers in Eastern and Central Africa. Ed. Kabirizi, J., et al, 2015 78–93. https://www.researchgate.net/publication/281556114_NAPIER_GRASS_FEED_RESOURCE_PRODUCTION_CONSTRAINTS_AND_IMPLICATIONS_FOR_SMALLHOLDER_FARMERS_IN_EAST_AND_CENTRAL_AFRICA
Wangchuk, K., Rai, K., Nirola, H., Thukten, Dendup, C., Mongar, D. (2015). Forage growth, yield and quality responses of Napier hybrid grass cultivars to three cutting intervals in the Himalayan foothills. Trop. Grassl. – Forrajes Tropicales. 3, 142–150. doi: 10.17138/TGFT(3)142-150
Wijitphan, S., Lorwilai, P., Arkaseang, C. (2009). Effects of plant spacing on yields and nutritive values of Napier grass (Pennisetum purpureum Schum.) under intensive management of nitrogen fertilizer and irrigation. Pak. J. Nutr. 8 (8), 1240–1243. doi: 10.3923/PJN.2009.1240.1243
Woodard, K. R., Prine, G. M. (1993). Dry matter accumulation of elephantgrass, energycane, and elephant millet in a subtropical climate. Crop Sci. 33, 818–824. doi: 10.2135/cropsci1993.0011183X003300040038x
Yammeun-art, S., Somrak, P., Phatsara, C. (2017). Effect of the ratio of maize cob and husk to Napier Pakchong 1 silage on nutritive value and in vitro gas production of rumen fluid of Thai native cattle. Anim. Prod. Sci. 57, 1603–1606. doi: 10.1071/AN15692_CO
Yang, Y., Tilman, D., Furey, G., Lehman, C. (2019). Soil carbon sequestration accelerated by restoration of grassland biodiversity. Nat. Commun. 10, 718. doi: 10.1038/s41467-019-08636-w
Yokota, H., Fujii, Y., Ohshima, M. (1998). Nutritional quality of Napier grass (Pennisetum purpureum Schum.) silage supplemented with molasses and rice bran by goats. Asian-Aust. J. Anim. Sci. 11 (6), 697–701. doi: 10.5713/AJAS.1998.697
Zewdu, T., Baars, R. M. T., Yami, A. (2002). Effect of plant height at cutting, source and level of fertiliser on yield and nutritional quality of Napier grass (Pennisetum purpureum (L.) Schumach.). Afric. J. Range Forage Sci. 19, 123–128. doi: 10.2989/10220110209485783
Zhang, X., Gu, H., Ding, C., Zhong, X., Zhang, J., Xu, N. (2010). Path coefficient and cluster analyses of yield and morphological traits in Pennisetum purpureum. Trop. Grassl. 44, 95–102.
Keywords: smallholder farmers, elephant grass, sowing density, harvesting frequency, food security, best management practice
Citation: Islam MR, Garcia SC, Sarker NR, Islam MA and Clark CEF (2023) Napier grass (Pennisetum purpureum Schum) management strategies for dairy and meat production in the tropics and subtropics: yield and nutritive value. Front. Plant Sci. 14:1269976. doi: 10.3389/fpls.2023.1269976
Received: 31 July 2023; Accepted: 11 October 2023;
Published: 14 November 2023.
Edited by:
Abhishek Kumar Dwivedy, Banaras Hindu University, IndiaReviewed by:
Vipin Kumar Singh, Banaras Hindu University, IndiaAbhishek K. Bhardwaj, Amity University, Gwalior, India
Akhilesh Kumar Pandey, Invertis University, India
Copyright © 2023 Islam, Garcia, Sarker, Islam and Clark. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: M. Rafiq Islam, md.islam@sydney.edu.au