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Organic Management of ‘Maradol’ Papaya (Carica papaya L.) Crops: Effects on the Sensorial and Physicochemical Characteristics of Fruits

OthersByron Kevin Magolo posted the article • 0 comments • 33 views • 2019-11-03 10:35 • came from similar tags

Instituto de Biociencias, Universidad Autónoma de Chiapas, Boulevard Príncipe Akishino sin Número, Colonia Solidaridad 2000, C.P. 30798 Tapachula, Chiapas, Mexico
 Author to whom correspondence should be addressed.
Received: 24 September 2019 / Accepted: 28 October 2019 / Published: 1 November 2019
Abstract: The Maradol Papaya (Carica papaya L.) is a fleshy berry produced in the tropics; it is highly appreciated around the world for its high nutritional and medicinal value, as well as its attractive sensory properties. Evaluating the physiological, chemical, and sensory characteristics of ‘Maradol’ papaya fruits from organically managed crops was the primary objective of this study. Four treatments (T1–T4) were evaluated, all of which were fertilized using the same organic management practices. In addition, plant extracts were applied regularly to T1–T3 as pest control, and single (T2) and double (T1) rows of trap plants (roselle) were used. T4 did not receive additional treatment. Fruits under conventional agriculture outside the experimental site were included for comparative purposes (controls). The organic management of the plants did not negatively influence the physiological traits of postharvest ripening. Among the organic treatments, T1 fruits had the highest total soluble solids, vitamin C, and reducing sugars, as well as the lowest weight loss, which significantly improved the quality of the fruit, compared to conventionally produced fruits. In addition, sensory evaluation performed by trained judges, revealed that fruits from the organically managed plots (T1–T4) were the softest and juiciest, and had a higher score in fruit and papaya aroma, in contrast to the conventionally produced fruits, which turned out to be sour, more astringent, and less soft and juicy. The results show that the exclusively organic management of ‘Maradol’ papaya crops improves several post-harvest traits of the fruits, compared to those that can be purchased commercially and are conventionally grown.

Keywords: organic agriculture; trained judges; biofertilizers; fruits quality
 

 ]onlinereading[/url]
 
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Instituto de Biociencias, Universidad Autónoma de Chiapas, Boulevard Príncipe Akishino sin Número, Colonia Solidaridad 2000, C.P. 30798 Tapachula, Chiapas, Mexico
 Author to whom correspondence should be addressed.
Received: 24 September 2019 / Accepted: 28 October 2019 / Published: 1 November 2019
Abstract: The Maradol Papaya (Carica papaya L.) is a fleshy berry produced in the tropics; it is highly appreciated around the world for its high nutritional and medicinal value, as well as its attractive sensory properties. Evaluating the physiological, chemical, and sensory characteristics of ‘Maradol’ papaya fruits from organically managed crops was the primary objective of this study. Four treatments (T1–T4) were evaluated, all of which were fertilized using the same organic management practices. In addition, plant extracts were applied regularly to T1–T3 as pest control, and single (T2) and double (T1) rows of trap plants (roselle) were used. T4 did not receive additional treatment. Fruits under conventional agriculture outside the experimental site were included for comparative purposes (controls). The organic management of the plants did not negatively influence the physiological traits of postharvest ripening. Among the organic treatments, T1 fruits had the highest total soluble solids, vitamin C, and reducing sugars, as well as the lowest weight loss, which significantly improved the quality of the fruit, compared to conventionally produced fruits. In addition, sensory evaluation performed by trained judges, revealed that fruits from the organically managed plots (T1–T4) were the softest and juiciest, and had a higher score in fruit and papaya aroma, in contrast to the conventionally produced fruits, which turned out to be sour, more astringent, and less soft and juicy. The results show that the exclusively organic management of ‘Maradol’ papaya crops improves several post-harvest traits of the fruits, compared to those that can be purchased commercially and are conventionally grown.

Keywords: organic agriculture; trained judges; biofertilizers; fruits quality
 

 ]onlinereading[/url]
 
 
33
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How This Guy Made the World's Hottest Peppers |PuckerButt Pepper Company founder Ed Currie is on a mission to create the world's hottest peppers.

VideosByron Kevin Magolo posted the article • 0 comments • 33 views • 2019-11-03 09:59 • came from similar tags

PuckerButt Pepper Company founder Ed Currie is on a mission to create the world's hottest peppers. Ed is the evil genius who brought the world the Carolina Reaper, one of the hottest hot peppers in existence; but he's not stopping there.
 
 
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PuckerButt Pepper Company founder Ed Currie is on a mission to create the world's hottest peppers. Ed is the evil genius who brought the world the Carolina Reaper, one of the hottest hot peppers in existence; but he's not stopping there.
 
 
 


36
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The Factors Affecting Farmers’ Soybean Planting Behavior in Heilongjiang Province, China

OthersByron Kevin Magolo posted the article • 0 comments • 36 views • 2019-10-17 15:34 • came from similar tags

]download pdf file or read it online[/url]
 
 Shiwei Liu 1,2 , Pingyu Zhang 2, Ben Marley 3 and Wenxin Liu 2,*


Correspondence: [email protected]; Tel.: +86-431-8554-2228 Received: 1 August 2019; Accepted: 28 August 2019; Published: 1 September 2019School of Geographical Sciences, Southwest University, Chongqing 400715, ChinaNortheast Institute of Geography and Agroecology, Chinese Academy of Sciences, Changchun 130102, China Department of Sociology, Michigan State University, East Lansing, MI 48824-1111, USA




Abstract:

Under the threat of food insecurity, the Chinese government has created plans and policies to stimulate soybean production. Despite government efforts to stimulate production, based on predictions, planned targets for soybean production are unlikely. Consequently, the predictions raise questions about farmers’ intentions to increase soybean cultivating area. In other words, farmers may not be willing to increase soybean. However, few researchers have studied soybean farmers’ intention and behavior. With these concerns in mind, this study analyzed the intention and factors that influence farmers’ choice of increasing soybean production as well as evaluating the differences in the decision making between commercial and subsistence farmers. This study collected data from 155 randomly selected families in 23 villages in the major soybean area in Heilongjiang Province. Results showed that 42.6% of the farmers expressed that they would expand soybean planting area, while the rest would insist on previous planting habits. The capacity to increase soybean production confronted many constraints. Farmers’ age, farm income, land topography, and ease of selling all positively influence farmers’ behavior. A significant difference in decision making between subsistence and commercial farmers was found. Subsistence farmers were more affected by land topography, agricultural insurance status, and satisfaction of soybean subsidies, whereas commercial farmers were more affected by farming experience and farm income. As a result, soybean policies should focus on increasing farmers’ income, promoting large-scale planting, training young farmers, innovation of agricultural insurance, and strengthening construction of agricultural infrastructure.




Keywords: soybean; farmer’s behavior; soybean planting; affecting factors; Heilongjiang province
 
 
]download pdf file or read it online[/url] view all
]download pdf file or read it online[/url]
 
 Shiwei Liu 1,2 , Pingyu Zhang 2, Ben Marley 3 and Wenxin Liu 2,*


  • Correspondence: [email protected]; Tel.: +86-431-8554-2228 Received: 1 August 2019; Accepted: 28 August 2019; Published: 1 September 2019
  • School of Geographical Sciences, Southwest University, Chongqing 400715, China
  • Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Changchun 130102, China Department of Sociology, Michigan State University, East Lansing, MI 48824-1111, USA





Abstract:

Under the threat of food insecurity, the Chinese government has created plans and policies to stimulate soybean production. Despite government efforts to stimulate production, based on predictions, planned targets for soybean production are unlikely. Consequently, the predictions raise questions about farmers’ intentions to increase soybean cultivating area. In other words, farmers may not be willing to increase soybean. However, few researchers have studied soybean farmers’ intention and behavior. With these concerns in mind, this study analyzed the intention and factors that influence farmers’ choice of increasing soybean production as well as evaluating the differences in the decision making between commercial and subsistence farmers. This study collected data from 155 randomly selected families in 23 villages in the major soybean area in Heilongjiang Province. Results showed that 42.6% of the farmers expressed that they would expand soybean planting area, while the rest would insist on previous planting habits. The capacity to increase soybean production confronted many constraints. Farmers’ age, farm income, land topography, and ease of selling all positively influence farmers’ behavior. A significant difference in decision making between subsistence and commercial farmers was found. Subsistence farmers were more affected by land topography, agricultural insurance status, and satisfaction of soybean subsidies, whereas commercial farmers were more affected by farming experience and farm income. As a result, soybean policies should focus on increasing farmers’ income, promoting large-scale planting, training young farmers, innovation of agricultural insurance, and strengthening construction of agricultural infrastructure.




Keywords: soybean; farmer’s behavior; soybean planting; affecting factors; Heilongjiang province
 
 
]download pdf file or read it online[/url]
38
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Micro-Spatial Analysis of Maize Yield Gap Variability and Production Factors on Smallholder Farms

OthersByron Kevin Magolo posted the article • 0 comments • 38 views • 2019-10-17 14:39 • came from similar tags

]download pdf file or read it online[/url]
 
https://xordrive.io/%3Fp%3Dope ... fff3d
 
Munialo Sussy 1,*, Hall Ola 2, Francisca Archila Bustos Maria 2, Boke-Olén Niklas 3, Onyango M. Cecilia 1, Oluoch-Kosura Willis 4, Marstorp Håkan 5 and Göran Djurfeldt 2

[email protected] (G.D.)
3  Centre for Environmental and Climate research (CEC), Lund University, 22100 Lund, Sweden, [email protected]
4  Department of Agricultural Economics, University of Nairobi, Nairobi P.O. Box 29053-00625, Kenya; [email protected]
5  Department of Soil and Environment, Swedish University of Agricultural Sciences, S-75007 Uppsala, Sweden; [email protected]


* Correspondence: [email protected]; Tel.: +254-7105-81953
Received: 30 July 2019; Accepted: 6 September 2019; Published: 11 October 2019

Abstract: Site-specific land management practice taking into account variability in maize yield gaps (the difference between yields in the 90th percentiles and other yields on smallholder farmers’ fields) could improve resource use efficiency and enhance yields. However, the applicability of the practice is constrained by inability to identify patterns of resource utilization to target application of resources to more responsive fields. The study focus was to map yield gaps on smallholder fields based on identified spatial arrangements differentiated by distance from the smallholder homestead and understand field-specific utilization of production factors. This was aimed at understanding field variability based on yield gap mapping patterns in order to enhance resource use efficiency on smallholder farms. The study was done in two villages, Mukuyu and Shikomoli, with high and low agroecology regarding soil fertility in Western Kenya. Identification of spatial arrangements at 40 m, 80 m, 150 m and 300 m distance from the homestead on smallholder farms for 70 households was done. The spatial arrangements were then classified into near house, mid farm and far farm basing on distance from the homestead. For each spatial arrangement, Landsat sensors acquired via satellite imagery were processed to generate yield gap maps. The focal statistics analysis method using the neighborhoods function was then applied to generate yield gap maps at the different spatial arrangements identified above. Socio-economic, management and biophysical factors were determined, and maize yields estimated at each spatial arrangement. Heterogeneous patterns of high, average and low yield gaps were found in spatial arrangements at the 40 m and 80 m distances. Nearly homogenous patterns tending towards median yield gap values were found in spatial arrangements that were located at the 150 m and 300 m. These patterns correspondingly depicted field-specific utilization of management and socio-economic factors. Field level management practices and socio-economic factors such as application of inorganic fertilizer, high frequency of weed control, early land preparation, high proportion of hired and family labor use and allocation of large land sizes were utilized in spatial arrangements at 150 and 300 m distances. High proportions of organic fertilizer and family labor use were utilized in spatial arrangements at 40 and 80 m distances. The findings thus show that smallholder farmers preferentially manage the application of socio-economic and management factors in spatial arrangements further from the homestead compared to fields closer to the homestead which could be exacerbating maize yield

Agriculture 2019, 9, 219; doi:10.3390/agriculture9100219 www.mdpi.com/journal/agriculture

Agriculture 2019, 9, 219 2 of 24

gaps. Delineating management zones based on yield gap patterns at the different spatial arrangements on smallholder farms could contribute to site-specific land management and enhance yields. Investigating the value smallholder farmers attach to each spatial arrangement is further needed to enhance the spatial understanding of yield gap variation on smallholder farms.

Keywords: spatial arrangements; heterogeneous farms; yield gap patterns; site-specific; land management; unequal resource


 
  view all
]download pdf file or read it online[/url]
 
https://xordrive.io/%3Fp%3Dope ... fff3d
 
Munialo Sussy 1,*, Hall Ola 2, Francisca Archila Bustos Maria 2, Boke-Olén Niklas 3, Onyango M. Cecilia 1, Oluoch-Kosura Willis 4, Marstorp Håkan 5 and Göran Djurfeldt 2

[email protected] (G.D.)
3  Centre for Environmental and Climate research (CEC), Lund University, 22100 Lund, Sweden, [email protected]
4  Department of Agricultural Economics, University of Nairobi, Nairobi P.O. Box 29053-00625, Kenya; [email protected]
5  Department of Soil and Environment, Swedish University of Agricultural Sciences, S-75007 Uppsala, Sweden; [email protected]


* Correspondence: [email protected]; Tel.: +254-7105-81953
Received: 30 July 2019; Accepted: 6 September 2019; Published: 11 October 2019

Abstract: Site-specific land management practice taking into account variability in maize yield gaps (the difference between yields in the 90th percentiles and other yields on smallholder farmers’ fields) could improve resource use efficiency and enhance yields. However, the applicability of the practice is constrained by inability to identify patterns of resource utilization to target application of resources to more responsive fields. The study focus was to map yield gaps on smallholder fields based on identified spatial arrangements differentiated by distance from the smallholder homestead and understand field-specific utilization of production factors. This was aimed at understanding field variability based on yield gap mapping patterns in order to enhance resource use efficiency on smallholder farms. The study was done in two villages, Mukuyu and Shikomoli, with high and low agroecology regarding soil fertility in Western Kenya. Identification of spatial arrangements at 40 m, 80 m, 150 m and 300 m distance from the homestead on smallholder farms for 70 households was done. The spatial arrangements were then classified into near house, mid farm and far farm basing on distance from the homestead. For each spatial arrangement, Landsat sensors acquired via satellite imagery were processed to generate yield gap maps. The focal statistics analysis method using the neighborhoods function was then applied to generate yield gap maps at the different spatial arrangements identified above. Socio-economic, management and biophysical factors were determined, and maize yields estimated at each spatial arrangement. Heterogeneous patterns of high, average and low yield gaps were found in spatial arrangements at the 40 m and 80 m distances. Nearly homogenous patterns tending towards median yield gap values were found in spatial arrangements that were located at the 150 m and 300 m. These patterns correspondingly depicted field-specific utilization of management and socio-economic factors. Field level management practices and socio-economic factors such as application of inorganic fertilizer, high frequency of weed control, early land preparation, high proportion of hired and family labor use and allocation of large land sizes were utilized in spatial arrangements at 150 and 300 m distances. High proportions of organic fertilizer and family labor use were utilized in spatial arrangements at 40 and 80 m distances. The findings thus show that smallholder farmers preferentially manage the application of socio-economic and management factors in spatial arrangements further from the homestead compared to fields closer to the homestead which could be exacerbating maize yield

Agriculture 2019, 9, 219; doi:10.3390/agriculture9100219 www.mdpi.com/journal/agriculture

Agriculture 2019, 9, 219 2 of 24

gaps. Delineating management zones based on yield gap patterns at the different spatial arrangements on smallholder farms could contribute to site-specific land management and enhance yields. Investigating the value smallholder farmers attach to each spatial arrangement is further needed to enhance the spatial understanding of yield gap variation on smallholder farms.

Keywords: spatial arrangements; heterogeneous farms; yield gap patterns; site-specific; land management; unequal resource


 
 
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A Review of Kudzu’s Use and Characteristics as Potential Feedstock

OthersByron Kevin Magolo posted the article • 0 comments • 37 views • 2019-10-17 12:27 • came from similar tags

by Joseph P. Gulizia * and  Kevin M. Downs 

School of Agriculture, Middle Tennessee State University, Murfreesboro, TN 37132, USA

*

Author to whom correspondence should be addressed.

Received: 23 August 2019 / Accepted: 8 October 2019 / Published: 11 October 2019

Abstract: This review assesses the potential use of kudzu (Pueraria montana var. lobata) as a feedstock for livestock. Kudzu in the United States is a recognized invasive plant species that has continued to cause problems for the environment and land owners. In kudzu’s native countries, it has continued to have beneficial uses beyond being an adequate form of soil erosion control. Never the less, kudzu is a rampant weed that causes harm to many environments. In the United States, local farm owners have used ruminant species as a form of biological control to prevent the spread of kudzu and provide their animals with a high nutrition feed supplement. However, there are few reports that assess ruminal degradability in ruminants and kudzu quality. There is great potential for kudzu as a feed supplement for livestock species. Furthermore, using kudzu as a feed supplement for livestock species serves a dual-purpose of biologically controlling the spread of kudzu while providing those animals with a high-quality feedstuff.

Keywords: kudzu; feedstock; livestock; biological control; invasive species




1. Introduction

During its active growing season, kudzu (Pueraria montana var. lobata) rapidly engulfs many woody and herbaceous areas in the Southeastern United States. It is an invasive plant species that has persistently evaded a definitive control method, and, as such, has created land management problems for many land owners. A major problem that land owners face is the destruction occurring from kudzu on their desired forages for agricultural production. Biological control using ruminants, specifically browsers, however, can be a beneficial control method for both the owner of the land and the animals. Kudzu is known to have a high nutritive content that can benefit animals. There is, however, limited data on kudzu’s ruminal degradability in ruminants. This review will focus on kudzu’s characteristics, uses, and qualities and assess its use as a potential feedstock for livestock species.

2. History of Kudzu

There are 17 species of kudzu in the genus Pueraria throughout the world (Table 1), all of which are native to China, Taiwan, Japan, and India [1,2,3].

These cultures have implemented various uses of kudzu, including medicinal purposes or making it into cloth and paper [2]. Kudzu was first introduced into the United States from Japan in 1876 as a display at the first official World’s Fair in Philadelphia, Pennsylvania in the Plant Exhibition section [2,4]. During the late 19th century, kudzu’s broad leaves and dense growth was initially used as shade for porches and courtyards in the Southern United States. Kudzu quickly became popular and more common among Southern U.S. farmers for its advertised multi-purpose uses, including as soil erosion control, a cheap forage for livestock, and various practical uses around their homes [2]. In the 1930s, the U.S. Natural Resource Conservation Service (NRCS) oversaw combating soil erosion from improper agricultural practices [2]. They dispersed 85 million kudzu seedlings to Southern U.S. farmers to establish kudzu plots for soil erosion control and land revitalization [2]. Kudzu use in soil erosion control was optimal due to its rapid growth of vines that drop roots every few feet which grips and prevents excess soil movement [5]. Land revitalization came through kudzu’s property of being a soil nitrogen fixer, which refilled overused, nitrogen deficit soils. In the 1930s, the U.S. government offered an $8 per acre incentive to plant kudzu seedlings. By 1946, there were approximately 1.21 million hectares of kudzu in the Southeastern United States [2].

Kudzu began gaining negative attention by the early 1950s, as it spread rampantly throughout the Southern U.S., causing problems for farmland owners [2]. It was destructive in killing trees, collapsing buildings, and destroying utility poles by aggressively traveling up these structures and forming a dense mass that would strain their integrity [6]. The climate of the Southeastern United States was ideal for kudzu to thrive, leading to it being placed on the United States Department of Agriculture (USDA) common weed list in 1970 [2]. Kudzu became an invasive plant species in the United States because it had no natural competitors in the environment to regulate its growth, as it would in its native Asian countries. In 1997, the U.S. Congress voted to place kudzu on the Federal Noxious Weed List. There is now an estimated 2.83 million hectares of land in the Southeastern United States that has been engulfed with this invasive plant species [2].

3. Characteristics of Kudzu

Kudzu (P. montana), the species that is predominately found in the Southern U.S., is a large, trifoliate-leaved, semi-woody, perennial vine that belongs to the legume family [2,5,6]. Plant species of the legume family are known for being soil nitrogen fixers. Kudzu vines can grow up to 0.3 m per day in early summer and as much as 18 m total during the growing season (May–October) [2,5,7]. It spreads from the root crown in any direction and will root at the vine nodes every few feet to establish new growths [2,5]. The spread rate of kudzu can be accelerated by small vines of other plants because kudzu can consistently twine around smaller vines more swiftly than large tree trunks [5,8]. Its tuberous roots (descended at the nodes) help maintain a heavy carbon reserve. Roots can reach a depth of 4 m and weigh as much as 91–136 kg in older kudzu patches [2,5,9]. The taproot is enlarged and beneficial in that it aids the plant in survival during drought periods [4,5].

Asexual regeneration is a frequent and common method by which kudzu multiplies. This occurs every few feet where nodes (the areas on the vine where leaves and roots branch) will send down roots establishing new root crowns [5]. There are few fruiting pods that develop viable seeds during the optimal growing season, but its vegetative reproduction continually takes place as the nodes establish roots [6]. During kudzu’s third growing season after germination, seed production will initiate by producing a purple flower in late July to September in the U.S., if in full sun [5,6]. When seedpods are produced there are only 1–2 viable seeds, and these seed pods are only found on climbing vines [2,5]. A prolonged exposure to high summer temperatures and increased soil temperatures will accelerate seed germination by affecting seed coat permeability [5,10]. Attempts to eradicate kudzu by burning may also promote seed germination, where potential new growth would emerge after the burning attempt [5,10].

Kudzu is found in many places in the United States and can grow in a wide range of soil types, including sandy soils, acid soils, lime soils, lowlands with high water tables, in over-heavy subsoil, and in areas where winter soil temperatures do not drop below −32 °C [2,11]. Kudzu can be found in open fields, road sides, and near forest edges, but its spread is at its peak in open fields [5]. The widespread distribution of kudzu in the United States is shown in Figure 1.

This map shows that kudzu has spread from the Southern U.S. and has acquired a level of hardiness to endure colder and dryer climates. Kudzu can endure drought and high temperatures, but will not thrive in wet soils and young vegetative growth will die in low temperatures [6]. When reaching temperatures between 30 °C and 35 °C, the efficiency of photosynthesis will be affected by increasing heat [5]. Kudzu will grow in many different soils, but the optimal soil type is a deep, loamy soil [2,4,5,6]. The most aggressive plots of kudzu are in the Southeastern U.S., with its optimal climates where winters are mild, summer temperatures rise above 27 °C, annual precipitation exceeds 102 cm, and sandy loam soils are widespread [4,5].

Other factors that can affect growth of kudzu is light availability and the previous existing native plant life. As kudzu starts to encounter shade, growth will dwindle, whereas in direct sunlight the growth rate can increase 3-fold [5]. Kudzu contains a high leaf surface area, especially when climbing trees, which enhances the photosynthetic competition for light [5]. Kudzu is considered heavily shade intolerant in having the highest light requirement out of five native (Rhus radicans, Clematis virginiana, Smilax rotundifolia, Vitis vulpina, and Parthenocissus quinque-folia) and three exotic (Pueraria lobata, Lonicera japonica, and Hedera helix) vine species in the Southeast U.S. [5,13].

Kudzu differs among species around the world. American kudzu, compared to the Japanese counterpart, is distinctly different in how it overwinters. Kudzu is considered a semi-woody perennial because of its overwintering ability [5]. Overwintering is a process where vines develop thick bark, accumulate annual rings of vascular tissue, and attain a desirable stem diameter, usually around 2 cm [5,14]. American kudzu will produce these overwintering stems only on the vigorous, climbing plants, whereas the Japanese strain will produce the overwintering stems on the portions that lie just above the ground [5,14]. An additional difference with the North American cultivars of kudzu is that they have limited seed production and are less likely to thrive outside the Southeast U.S. [5].

4. Uses of Kudzu

In China and Japan, kudzu roots are dried and used for medicinal purposes to cure an array of common ailments [15]. Japan, during the 1700s, also attempted to utilize fiber from stems to make grass-like cloth and paper, and also grinding kudzu into flour for use in baking [2,15]. Asian grocery and health food stores still import kudzu flour to sell in the U.S. [9]. Other traditional uses of kudzu are as fiber to stuff cushions and chairs, as a mosquito repellent when burned, and to produce a palatable honey [15]. During the initial years that kudzu was introduced in the U.S., it was used as an ornamental vine (which was appreciated for its grape-like fragrance) to shade many southern U.S. homes [2].

As previously discussed, kudzu (P. montana) was first introduced to the United States as a means for erosion control, but was eventually considered a rampantly unstoppable vegetation that would start to take over the Southeastern United States. Kudzu continues to be an efficient method of soil erosion control on steep embankments, but there are more noninvasive species (e.g., tall fescue and bahiagrass) used now to address this issue [7,15]. Being a legume, kudzu has a dual-purpose of hosting nitrogen fixing bacteria that enrich the soil and is also a good source of nutrients when fed to herbivorous livestock [15].

5. Kudzu Nutrient Composition and Degradability

Kudzu (P. montana) is often compared to alfalfa. Kudzu leaves have a high nutritive value comparable to that of alfalfa (Medicago sativa), a common flowering plant used for grazing, hay, and silage for ruminants and other domestic herbivores [16,17,18] (Table 2).

As noted in Table 3, kudzu (P. montana) (kudzu aerial part (fresh), kudzu leaves (fresh), and kudzu hay) is a high quality legume feedstuff. Kudzu fed as an aerial part (fresh), leaves (fresh), or hay can satisfy most nutrient requirements for various ruminant species (Table 4). Kudzu silage has a high nutrient composition that would satisfy nutrient requirements for many ruminants (20.15% dry matter (DM), 92.01% organic matter (OM), 20.09% crude protein (CP), 8.14% Ash, 57.10% neutral detergent fiber (NDF), 38.32% acid detergent fiber (ADF), 8.25% Lignin) [21]. Kudzu leaves are higher quality than alternative kudzu feed sources, and satisfies nutrient requirements for most domestic ruminants [22]. Additionally, based on National Research Council’s TDN criteria, kudzu leaves are considered a high quality legume forage [22]. Nutrient composition data indicates that kudzu has substantial potential as a feedstock for ruminant livestock species.

In situ dry matter rumen degradation data provided by Corley et al. [20] separates kudzu into soluble, degradable, and indigestible fractions between leaf/stem and tuber (roots) (Table 5).

Legumes, such as kudzu and alfalfa, have a high rate of degradability due to a low concentration of water-soluble carbohydrates [34]. Corley et al. [20] provided data that kudzu contains 17.5% CP in leaves, similar to alfalfa at 18.7% CP (Table 2). Kudzu leaves contain a high concentration of CP, making it a potential feed for growing ruminants [20]. The stem and tuber portions of kudzu do not have the same potential in regard to providing optimal nutrients to the ruminant. Moreover, kudzu leaves contain a significantly higher CP level than stems; however, kudzu leaves contain significantly lower ADF (a common predictor of energy level in forages) [22]. Corley et al. [20] found a 5–7% lower CP level in stems than leaves (Table 6). In addition, Corley et al. [20] observed that kudzu tuber contained 8.6% CP (Table 6). Zhao et al. [35] reported that kudzu roots contain a range of CP from 3.18–4.58%. As growth time of kudzu root increases, CP tends to decrease to levels below 4.58%. In contrast, lipid content of kudzu root increases with an extended growth period to levels above 32.2 g/kg [35].

Additionally, Gulizia et al. [36] observed that kudzu from two different growing seasons contained a higher concentration of nutrients than in previous reports (Table 7). This study also observed that early season kudzu dry matter degradability was 84%, and late season kudzu degradability was 79% over a 72 h incubation period. Gulizia et al. [36] concluded that kudzu (regardless of growing season) was highly degradable over a 72 h incubation period in ruminants, and has potential as a feedstock.

In comparison, alfalfa is a high-quality forage characterized by high digestibility and swift ruminal degradation [37]. Alfalfa and kudzu leaf and stem have similar in situ rumen degradation, with alfalfa having an average rate of 73.35% and kudzu having 78% maximum degradability [20,38]. Alfalfa leaf and stem have an average soluble fraction of 34.8% and an average degradable fraction of 38.6%, whereas kudzu leaf and stem are 29.1% and 48.6%, respectively (Table). This data can potentially predict that alfalfa leaf and stem contain more starch, sugars, and protein than kudzu leaf and stem, but less concentrations of cellulose and hemicellulose. Coblentz et al. [38] allowed alfalfa to ferment in the rumen for 96 hours, whereas Corley et al. [20] only allowed 24 hours of fermentation for kudzu. In situ dry matter disappearance for whole plant alfalfa was found to be 76.6, 79.6, 79.2, and 81.91% in four studies [38,39,40,41]. It is common for alfalfa to have high nitrogen levels that are highly degradable. High degradability of nitrogen in alfalfa can lead to poor utilization of available nitrogen in lactating dairy cows [38].

6. Anti-Quality and Anti-Nutritional Factors of Kudzu

Kudzu contains a variety of secondary metabolites. Table 8 summarizes a qualitative analysis of some common secondary metabolites found in tropical kudzu. Data is limited on quantitative analysis of many secondary metabolites in kudzu leaf and vine. These secondary metabolites can act as anti-nutritional or anti-qualitative factors [42,43]. Legumes, such as kudzu, are beneficial in nitrogen fixation and improvement of animal diets. Secondary metabolites in kudzu, however, can interfere with nutrient intake, absorption, and utilization [42,43].

There are both toxic (i.e., alkaloids, saponins, isoflavones, etc.) and nontoxic (i.e., tannins, cutin, biogenic silica, etc.) secondary metabolites in plant materials [43,44]. Alkaloids, cyanogenic glycosides, toxic amino acids, saponins, and isoflavones are toxic compounds present in low concentrations [43,44]. These compounds at concentrations less than 20 g/kg can have negative effects when absorbed by an animal, including neurological problems, reproductive failure, gangrene, and potential fatalities [43,44]. Lignin, tannin, cutin, biogenic silica, and volatile terpenoids make up the non-toxic compounds present in high concentrations. These compounds at concentrations greater than 20 g/kg can result in decreased digestibility and palatability [43,44].

Saponins are in high concentrations in tropical kudzu (Pueraria phaseoloides), causing tympanism (accumulation of gas), reduced rumen microbial fermentation, and hepatic photosensitivity [43]. Saponins also create stable foam in water and impart a bitter flavor to forages, thus decreasing the likelihood of intake by the animal [43]. Saponins are major anti-nutritional and anti-qualitative factors, but tannins are the primary negative factor in legumes [43]. There are two types of tannins, hydrolysable and condensed varieties, with the latter being found in legumes, sorghum grains, and tree leaves. Tannins contain a large amount of phenolic hydroxyl groups, allowing them to create links with proteins and other molecules [45]. A main concern with tannins in feedstuffs is their negative effects on the ruminant digestive system through protein interactions [45]. Tannins will affect the nutritive value of plant dry matter, reducing the palatability by precipitating salivary proteins and nutrient digestibility by diminishing the permeability of the rumen wall through interactions with the outer cellular layer of the digestive tract. Tannins consumed at >50 g/kg of dry matter concentration will cause ruminants to reject feedstuffs, while consumption <50 g/kg seems to not affect voluntary feed intake [46,47,48,49]. Digestive enzyme activity may also decrease from tannins’ ability as a potent inhibitor. Tannins have the potential to cause negative effects to an animal, including impaired ruminal digestion; low milk yield; toxic degenerative changes in the intestine, liver, spleen, and kidney; and constipation [45]. Both saponins and tannins cause negative effects, but the positive effects these secondary metabolites can have, including diminished ruminal methane production, is still being explored [43,50].

Organic acids and reducing sugars are the remaining secondary metabolites that have large concentrations in kudzu. Organic acids can bring about precipitation of calcium ions in the blood, leading to muscle weakness, nephritis, kidney stones, gastrointestinal irritation, and hypocalcemia syndrome in grazing ruminants and horses [43]. In large concentrations, reducing sugars can be problematic for equines [43,51]. Equines fed a high concentrate diet will produce excess lactic acid, resulting in water retention and decreased pH values in the lumen of the digestive tract [43,51]. This risks the possibility of digestive disorders, including osmotic diarrhea and colic [43,51]. Additional secondary metabolites, such as coumarin by-products, depsides and depsidones, alkaloids, steroids, triterpenoids, flavonoids, and cardiac glycosides can also cause negative effects [43]. Lastly, kudzu contains phenolic compounds that can have allelopathic advantages [52,53]. Kudzu leaves and roots contain 2–3% (DM) phenolic compounds [52,53]. Kudzu growing soils contain approximately 50 times more phenolics than soils devoid of kudzu [52,53].

7. Biological Control of Kudzu Using Animals

Plant populations are controlled naturally by their environment and by natural enemies. Invasive species are unique in disrupting an ecosystem to which it does not belong due to a lack of natural control [54]. Invasive species are the second largest cause of biodiversity (total variability within and among species of all plant organisms and their habitats) loss, behind habitat destruction [55]. The degree of invasiveness may increase with a lack of natural competitors [55,56]. Plant species that are established in an environment outside of its natural habitat may be less regulated by the native herbivores in the area, thus resulting in the rapid growth of an invasive plant species [55,56]. This leads to unwanted imbalances in an ecosystem that have potential to harm native species. These invasive plant species can be controlled by chemical or biological methods. Biological control is a method by which one organism is used to control another and can be used to restore ecosystem balance [56]. Biological control of problematic species using animals was recorded as early as 9,500 years ago when cats were domesticated to control rodents [56]. Animals used in biological control of invasive plant species can range from insects to ruminants. Therefore, land owners can manage livestock to use invasive plant species as diet supplements and not only enhance animal production, but also slowly diminish the infestation of the invasive species.

Kudzu (P. montana) must undergo constant application of some control method to yield results in lowering its occurrence. Efforts to successfully control this plant is heavily influenced by timed treatments within its life cycle [6]. Biological control using grazers and browsers can be an effective and cost-efficient method, but it is a slow process [6]. Elimination of kudzu is possible by frequent defoliation by animals over several years. By over defoliating and reducing photosynthetic carbon, hydrogen, and oxygen (CHO), kudzu will halt its metabolic processes and regrowth will be prevented [2]. Defoliation during the fall will reduce the amount of resources roots receive for survival through the winter, thus accelerating the progression of eradication [5].

Kudzu (P. montana) can be eliminated using cattle to over graze it at 80% consumption of the vegetative growth for 3–4 years [2,6]. In contrast, tropical kudzu (Pueraria phaseoloides) could be efficiently controlled using cattle on a rotational grazing system in less than 2 years [57]. However, for tropical kudzu to be eradicated in 2 years, the soil should be compact and drain poorly [57]. Vines which these animals cannot reach may be cut and fed to ensure that defoliation is effective. Remaining plant material after those 3–4 years can be spot treated with recommended herbicides [6]. Furthermore, continuous grazing and browsing of infested areas for approximately 2 months during kudzu’s growing season (May-October in the U.S.) can be effective in its eradication. Older infestations become increasingly hard to eradicate. Kudzu over 10 years old will be minimally affected by over grazing and over browsing, so herbicide application may be necessary [6,7,8]. However, kudzu’s hardy nature tends to make application of herbicides difficult due to the stockpile of starch in its tap root [58].

8. Use of Kudzu as a Feedstock

Grazers (e.g., cattle and sheep) and browsers (e.g., goats and deer) will consume kudzu (P. montana) when available, but it is easily overbrowsed or overgrazed [4]. Kudzu is known to produce a forage of high quality that contains a crude protein (CP) concentration of 15% or higher and a total digestible nutrient (TDN) value of over 60%, but the use of this plant as a feedstuff has limitations. Kudzu grows rapidly, but it produces a low forage yield of 2–4 tons of dry matter per acre per year [2]. Pairing low forage yield with a vine-like growth habit makes harvesting problematic. During dry periods, producers can harvest kudzu annually or biennially, as it retains moisture for growth deep within the roots [2]. Grazers and browsers can be enclosed on a plot of kudzu to control its growth, while also receiving a high quality source of nutrients that potentially results in increased animal performance. Lynd and Ansman [59], Miller and Edwards [60], and Rhoden et al. [61] reported that heavy grazing kudzu for 3–4 growing seasons with cattle, swine, horses, sheep, or goats in August and September could prove to be effective at starving and preventing growth of kudzu. Though data is limited, there are examples of kudzu’s use as a feedstock.

Tropical kudzu contains a high nutrient composition as shown in Table 9. Overall, P. montana and Pueraria phaseoloides tend to be similar in nutritive value. Previous research utilizing tropical kudzu determined that it is palatable and contains an adequate amount of CP for ruminants. Monteiro et al. [62] observed that dairy cows fed a diet that consisted of tropical kudzu supplemented with sorghum grain could support a milk yield of 8.1 kg milk/day.

In 1945, tropical kudzu (Pueraria phaseoloides) was introduced to a herd of Guernsey cows. Initially, few cows ate kudzu, but within days cows consumed it regularly [63]. This experiment was conducted when common pasture crops did not produce a sufficient forage. For one continuously grazing cow during the dry season, an estimated one acre of tropical kudzu was needed. Telford and Childers [63] determined that tropical kudzu should only be grazed once during the dry season. To use kudzu for grazing, it should not be grazed to the ground to preserve quality and regrowth ability. Tropical kudzu had an estimated 11,000–18,150 kg of forage production per year during these experiments. Successful grazing was also established using oxen and goats, and an adapted use for other livestock and poultry.

Kudzu has been used as a source of feed for a variety of research animals. Bhatt and Sharma [23] fed fresh kudzu-vine (Puereria thunbergiana) ad libitum to experimental Angora rabbits. In the Malagasy Republic, both Puereria thunbergiana and Pueraria phaseoloides were successfully grown as a high protein feedstuff [26,58]. Using kudzu as an alternative feed source has been successful due to its palatability and positive results have been shown when fed to beef and dairy cattle [22]. Cows utilizing kudzu as a feedstock produced milk with no color or flavor differences [22]. Piper [72] and Shurtleff and Aoyagi [73] observed that when given a choice, cattle, hogs, chickens, goats, sheep, horses, and rabbits preferred kudzu over grasses or commercial hay. Research conducted in Alabama on Angora goats observed that kudzu populations were effectively controlled with 27 animals/hm2 [52,74]. Additionally, kudzu is ideal as an emergency feed source when common sources are low [22]. Polk and Gieger [75] demonstrated that when alfalfa became limited, kudzu meal at 9% of their diet could be substituted in chick rations. Kudzu and various grasses (e.g., pará grass) can form a desirable combination (when grazing) to increase protein content and reduce the need for commercial feeds [63]. Poultry have been observed to graze kudzu and consume kudzu seeds; however, there have been no reports on potentially using poultry as a way to biologically control kudzu [52,59]. Nworgu and Egbunike [76] researched potential growth performance effects of feeding tropical kudzu (Pueraria phaseoloides) leaf meal to broilers. They concluded that, although the tropical kudzu leaf meal was rich in nutrients, tropical kudzu leaf meal should not be included in broiler diets as it led to poor growth rates. However, there are a growing number of researchers that are assessing leaf meals as an alternative protein supplement in modern poultry diets [77,78]. Thus, further research should assess the potential viability of kudzu’s use as a protein supplement in countries that have limited access to modern protein supplements (e.g., soybean meal). This would indicate that kudzu can be of real relevance for non-herbivore species such as poultry.

9. Summary and Applications

Kudzu’s high quality nutrient composition, degradability, and palatability suggest that it can be a valuable potential feedstock for livestock species. Its widespread distribution and rapid growth rate make it ideally suited as an economical feedstock, particularly in regions of scarce feedstuff availability. Producers must recognize, however, the challenges of managing kudzu for grazing and browsing species. With kudzu’s unique growth habits as a climbing vine, containing livestock species in areas of high kudzu mass can be challenging and may require considerable ingenuity. Furthermore, efforts to prevent overgrazing/overbrowsing should be highlighted. Kudzu leaf volume can be quickly depleted, effectively limiting kudzu’s use as a feedstock. Overgrazing/overbrowsing would be a preferred approach if the producer was attempting to control kudzu with livestock, but not if using as a sustainable source of nutrients.

This review has attempted to coalesce an array of information on kudzu into a comprehensive overview of its characteristics and potential significance as a feedstuff for a variety of domestic animal species. Much information, however, remains to be elicited on kudzu. Kudzu is often viewed in a negative light as an invasive weed species. Kudzu is, however, much more than that and holds significant potential as a feedstock in the United States and other countries where nutrient availability for production animals is limited.

Author Contributions

Conceptualization, J.P.G. and K.M.D.; Methodology, J.P.G. and K.M.D.; Validation, J.P.G. and K.M.D.; Formal analysis, J.P.G. and K.M.D.; Investigation, J.P.G. and K.M.D.; Writing—original draft preparation, J.P.G.; Writing—review and editing, J.P.G. and K.M.D.; Visualization, J.P.G. and K.M.D.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

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by Joseph P. Gulizia * and  Kevin M. Downs 

School of Agriculture, Middle Tennessee State University, Murfreesboro, TN 37132, USA

*

Author to whom correspondence should be addressed.

Received: 23 August 2019 / Accepted: 8 October 2019 / Published: 11 October 2019

Abstract: This review assesses the potential use of kudzu (Pueraria montana var. lobata) as a feedstock for livestock. Kudzu in the United States is a recognized invasive plant species that has continued to cause problems for the environment and land owners. In kudzu’s native countries, it has continued to have beneficial uses beyond being an adequate form of soil erosion control. Never the less, kudzu is a rampant weed that causes harm to many environments. In the United States, local farm owners have used ruminant species as a form of biological control to prevent the spread of kudzu and provide their animals with a high nutrition feed supplement. However, there are few reports that assess ruminal degradability in ruminants and kudzu quality. There is great potential for kudzu as a feed supplement for livestock species. Furthermore, using kudzu as a feed supplement for livestock species serves a dual-purpose of biologically controlling the spread of kudzu while providing those animals with a high-quality feedstuff.

Keywords: kudzu; feedstock; livestock; biological control; invasive species




1. Introduction

During its active growing season, kudzu (Pueraria montana var. lobata) rapidly engulfs many woody and herbaceous areas in the Southeastern United States. It is an invasive plant species that has persistently evaded a definitive control method, and, as such, has created land management problems for many land owners. A major problem that land owners face is the destruction occurring from kudzu on their desired forages for agricultural production. Biological control using ruminants, specifically browsers, however, can be a beneficial control method for both the owner of the land and the animals. Kudzu is known to have a high nutritive content that can benefit animals. There is, however, limited data on kudzu’s ruminal degradability in ruminants. This review will focus on kudzu’s characteristics, uses, and qualities and assess its use as a potential feedstock for livestock species.

2. History of Kudzu

There are 17 species of kudzu in the genus Pueraria throughout the world (Table 1), all of which are native to China, Taiwan, Japan, and India [1,2,3].

These cultures have implemented various uses of kudzu, including medicinal purposes or making it into cloth and paper [2]. Kudzu was first introduced into the United States from Japan in 1876 as a display at the first official World’s Fair in Philadelphia, Pennsylvania in the Plant Exhibition section [2,4]. During the late 19th century, kudzu’s broad leaves and dense growth was initially used as shade for porches and courtyards in the Southern United States. Kudzu quickly became popular and more common among Southern U.S. farmers for its advertised multi-purpose uses, including as soil erosion control, a cheap forage for livestock, and various practical uses around their homes [2]. In the 1930s, the U.S. Natural Resource Conservation Service (NRCS) oversaw combating soil erosion from improper agricultural practices [2]. They dispersed 85 million kudzu seedlings to Southern U.S. farmers to establish kudzu plots for soil erosion control and land revitalization [2]. Kudzu use in soil erosion control was optimal due to its rapid growth of vines that drop roots every few feet which grips and prevents excess soil movement [5]. Land revitalization came through kudzu’s property of being a soil nitrogen fixer, which refilled overused, nitrogen deficit soils. In the 1930s, the U.S. government offered an $8 per acre incentive to plant kudzu seedlings. By 1946, there were approximately 1.21 million hectares of kudzu in the Southeastern United States [2].

Kudzu began gaining negative attention by the early 1950s, as it spread rampantly throughout the Southern U.S., causing problems for farmland owners [2]. It was destructive in killing trees, collapsing buildings, and destroying utility poles by aggressively traveling up these structures and forming a dense mass that would strain their integrity [6]. The climate of the Southeastern United States was ideal for kudzu to thrive, leading to it being placed on the United States Department of Agriculture (USDA) common weed list in 1970 [2]. Kudzu became an invasive plant species in the United States because it had no natural competitors in the environment to regulate its growth, as it would in its native Asian countries. In 1997, the U.S. Congress voted to place kudzu on the Federal Noxious Weed List. There is now an estimated 2.83 million hectares of land in the Southeastern United States that has been engulfed with this invasive plant species [2].

3. Characteristics of Kudzu

Kudzu (P. montana), the species that is predominately found in the Southern U.S., is a large, trifoliate-leaved, semi-woody, perennial vine that belongs to the legume family [2,5,6]. Plant species of the legume family are known for being soil nitrogen fixers. Kudzu vines can grow up to 0.3 m per day in early summer and as much as 18 m total during the growing season (May–October) [2,5,7]. It spreads from the root crown in any direction and will root at the vine nodes every few feet to establish new growths [2,5]. The spread rate of kudzu can be accelerated by small vines of other plants because kudzu can consistently twine around smaller vines more swiftly than large tree trunks [5,8]. Its tuberous roots (descended at the nodes) help maintain a heavy carbon reserve. Roots can reach a depth of 4 m and weigh as much as 91–136 kg in older kudzu patches [2,5,9]. The taproot is enlarged and beneficial in that it aids the plant in survival during drought periods [4,5].

Asexual regeneration is a frequent and common method by which kudzu multiplies. This occurs every few feet where nodes (the areas on the vine where leaves and roots branch) will send down roots establishing new root crowns [5]. There are few fruiting pods that develop viable seeds during the optimal growing season, but its vegetative reproduction continually takes place as the nodes establish roots [6]. During kudzu’s third growing season after germination, seed production will initiate by producing a purple flower in late July to September in the U.S., if in full sun [5,6]. When seedpods are produced there are only 1–2 viable seeds, and these seed pods are only found on climbing vines [2,5]. A prolonged exposure to high summer temperatures and increased soil temperatures will accelerate seed germination by affecting seed coat permeability [5,10]. Attempts to eradicate kudzu by burning may also promote seed germination, where potential new growth would emerge after the burning attempt [5,10].

Kudzu is found in many places in the United States and can grow in a wide range of soil types, including sandy soils, acid soils, lime soils, lowlands with high water tables, in over-heavy subsoil, and in areas where winter soil temperatures do not drop below −32 °C [2,11]. Kudzu can be found in open fields, road sides, and near forest edges, but its spread is at its peak in open fields [5]. The widespread distribution of kudzu in the United States is shown in Figure 1.

This map shows that kudzu has spread from the Southern U.S. and has acquired a level of hardiness to endure colder and dryer climates. Kudzu can endure drought and high temperatures, but will not thrive in wet soils and young vegetative growth will die in low temperatures [6]. When reaching temperatures between 30 °C and 35 °C, the efficiency of photosynthesis will be affected by increasing heat [5]. Kudzu will grow in many different soils, but the optimal soil type is a deep, loamy soil [2,4,5,6]. The most aggressive plots of kudzu are in the Southeastern U.S., with its optimal climates where winters are mild, summer temperatures rise above 27 °C, annual precipitation exceeds 102 cm, and sandy loam soils are widespread [4,5].

Other factors that can affect growth of kudzu is light availability and the previous existing native plant life. As kudzu starts to encounter shade, growth will dwindle, whereas in direct sunlight the growth rate can increase 3-fold [5]. Kudzu contains a high leaf surface area, especially when climbing trees, which enhances the photosynthetic competition for light [5]. Kudzu is considered heavily shade intolerant in having the highest light requirement out of five native (Rhus radicans, Clematis virginiana, Smilax rotundifolia, Vitis vulpina, and Parthenocissus quinque-folia) and three exotic (Pueraria lobata, Lonicera japonica, and Hedera helix) vine species in the Southeast U.S. [5,13].

Kudzu differs among species around the world. American kudzu, compared to the Japanese counterpart, is distinctly different in how it overwinters. Kudzu is considered a semi-woody perennial because of its overwintering ability [5]. Overwintering is a process where vines develop thick bark, accumulate annual rings of vascular tissue, and attain a desirable stem diameter, usually around 2 cm [5,14]. American kudzu will produce these overwintering stems only on the vigorous, climbing plants, whereas the Japanese strain will produce the overwintering stems on the portions that lie just above the ground [5,14]. An additional difference with the North American cultivars of kudzu is that they have limited seed production and are less likely to thrive outside the Southeast U.S. [5].

4. Uses of Kudzu

In China and Japan, kudzu roots are dried and used for medicinal purposes to cure an array of common ailments [15]. Japan, during the 1700s, also attempted to utilize fiber from stems to make grass-like cloth and paper, and also grinding kudzu into flour for use in baking [2,15]. Asian grocery and health food stores still import kudzu flour to sell in the U.S. [9]. Other traditional uses of kudzu are as fiber to stuff cushions and chairs, as a mosquito repellent when burned, and to produce a palatable honey [15]. During the initial years that kudzu was introduced in the U.S., it was used as an ornamental vine (which was appreciated for its grape-like fragrance) to shade many southern U.S. homes [2].

As previously discussed, kudzu (P. montana) was first introduced to the United States as a means for erosion control, but was eventually considered a rampantly unstoppable vegetation that would start to take over the Southeastern United States. Kudzu continues to be an efficient method of soil erosion control on steep embankments, but there are more noninvasive species (e.g., tall fescue and bahiagrass) used now to address this issue [7,15]. Being a legume, kudzu has a dual-purpose of hosting nitrogen fixing bacteria that enrich the soil and is also a good source of nutrients when fed to herbivorous livestock [15].

5. Kudzu Nutrient Composition and Degradability

Kudzu (P. montana) is often compared to alfalfa. Kudzu leaves have a high nutritive value comparable to that of alfalfa (Medicago sativa), a common flowering plant used for grazing, hay, and silage for ruminants and other domestic herbivores [16,17,18] (Table 2).

As noted in Table 3, kudzu (P. montana) (kudzu aerial part (fresh), kudzu leaves (fresh), and kudzu hay) is a high quality legume feedstuff. Kudzu fed as an aerial part (fresh), leaves (fresh), or hay can satisfy most nutrient requirements for various ruminant species (Table 4). Kudzu silage has a high nutrient composition that would satisfy nutrient requirements for many ruminants (20.15% dry matter (DM), 92.01% organic matter (OM), 20.09% crude protein (CP), 8.14% Ash, 57.10% neutral detergent fiber (NDF), 38.32% acid detergent fiber (ADF), 8.25% Lignin) [21]. Kudzu leaves are higher quality than alternative kudzu feed sources, and satisfies nutrient requirements for most domestic ruminants [22]. Additionally, based on National Research Council’s TDN criteria, kudzu leaves are considered a high quality legume forage [22]. Nutrient composition data indicates that kudzu has substantial potential as a feedstock for ruminant livestock species.

In situ dry matter rumen degradation data provided by Corley et al. [20] separates kudzu into soluble, degradable, and indigestible fractions between leaf/stem and tuber (roots) (Table 5).

Legumes, such as kudzu and alfalfa, have a high rate of degradability due to a low concentration of water-soluble carbohydrates [34]. Corley et al. [20] provided data that kudzu contains 17.5% CP in leaves, similar to alfalfa at 18.7% CP (Table 2). Kudzu leaves contain a high concentration of CP, making it a potential feed for growing ruminants [20]. The stem and tuber portions of kudzu do not have the same potential in regard to providing optimal nutrients to the ruminant. Moreover, kudzu leaves contain a significantly higher CP level than stems; however, kudzu leaves contain significantly lower ADF (a common predictor of energy level in forages) [22]. Corley et al. [20] found a 5–7% lower CP level in stems than leaves (Table 6). In addition, Corley et al. [20] observed that kudzu tuber contained 8.6% CP (Table 6). Zhao et al. [35] reported that kudzu roots contain a range of CP from 3.18–4.58%. As growth time of kudzu root increases, CP tends to decrease to levels below 4.58%. In contrast, lipid content of kudzu root increases with an extended growth period to levels above 32.2 g/kg [35].

Additionally, Gulizia et al. [36] observed that kudzu from two different growing seasons contained a higher concentration of nutrients than in previous reports (Table 7). This study also observed that early season kudzu dry matter degradability was 84%, and late season kudzu degradability was 79% over a 72 h incubation period. Gulizia et al. [36] concluded that kudzu (regardless of growing season) was highly degradable over a 72 h incubation period in ruminants, and has potential as a feedstock.

In comparison, alfalfa is a high-quality forage characterized by high digestibility and swift ruminal degradation [37]. Alfalfa and kudzu leaf and stem have similar in situ rumen degradation, with alfalfa having an average rate of 73.35% and kudzu having 78% maximum degradability [20,38]. Alfalfa leaf and stem have an average soluble fraction of 34.8% and an average degradable fraction of 38.6%, whereas kudzu leaf and stem are 29.1% and 48.6%, respectively (Table). This data can potentially predict that alfalfa leaf and stem contain more starch, sugars, and protein than kudzu leaf and stem, but less concentrations of cellulose and hemicellulose. Coblentz et al. [38] allowed alfalfa to ferment in the rumen for 96 hours, whereas Corley et al. [20] only allowed 24 hours of fermentation for kudzu. In situ dry matter disappearance for whole plant alfalfa was found to be 76.6, 79.6, 79.2, and 81.91% in four studies [38,39,40,41]. It is common for alfalfa to have high nitrogen levels that are highly degradable. High degradability of nitrogen in alfalfa can lead to poor utilization of available nitrogen in lactating dairy cows [38].

6. Anti-Quality and Anti-Nutritional Factors of Kudzu

Kudzu contains a variety of secondary metabolites. Table 8 summarizes a qualitative analysis of some common secondary metabolites found in tropical kudzu. Data is limited on quantitative analysis of many secondary metabolites in kudzu leaf and vine. These secondary metabolites can act as anti-nutritional or anti-qualitative factors [42,43]. Legumes, such as kudzu, are beneficial in nitrogen fixation and improvement of animal diets. Secondary metabolites in kudzu, however, can interfere with nutrient intake, absorption, and utilization [42,43].

There are both toxic (i.e., alkaloids, saponins, isoflavones, etc.) and nontoxic (i.e., tannins, cutin, biogenic silica, etc.) secondary metabolites in plant materials [43,44]. Alkaloids, cyanogenic glycosides, toxic amino acids, saponins, and isoflavones are toxic compounds present in low concentrations [43,44]. These compounds at concentrations less than 20 g/kg can have negative effects when absorbed by an animal, including neurological problems, reproductive failure, gangrene, and potential fatalities [43,44]. Lignin, tannin, cutin, biogenic silica, and volatile terpenoids make up the non-toxic compounds present in high concentrations. These compounds at concentrations greater than 20 g/kg can result in decreased digestibility and palatability [43,44].

Saponins are in high concentrations in tropical kudzu (Pueraria phaseoloides), causing tympanism (accumulation of gas), reduced rumen microbial fermentation, and hepatic photosensitivity [43]. Saponins also create stable foam in water and impart a bitter flavor to forages, thus decreasing the likelihood of intake by the animal [43]. Saponins are major anti-nutritional and anti-qualitative factors, but tannins are the primary negative factor in legumes [43]. There are two types of tannins, hydrolysable and condensed varieties, with the latter being found in legumes, sorghum grains, and tree leaves. Tannins contain a large amount of phenolic hydroxyl groups, allowing them to create links with proteins and other molecules [45]. A main concern with tannins in feedstuffs is their negative effects on the ruminant digestive system through protein interactions [45]. Tannins will affect the nutritive value of plant dry matter, reducing the palatability by precipitating salivary proteins and nutrient digestibility by diminishing the permeability of the rumen wall through interactions with the outer cellular layer of the digestive tract. Tannins consumed at >50 g/kg of dry matter concentration will cause ruminants to reject feedstuffs, while consumption <50 g/kg seems to not affect voluntary feed intake [46,47,48,49]. Digestive enzyme activity may also decrease from tannins’ ability as a potent inhibitor. Tannins have the potential to cause negative effects to an animal, including impaired ruminal digestion; low milk yield; toxic degenerative changes in the intestine, liver, spleen, and kidney; and constipation [45]. Both saponins and tannins cause negative effects, but the positive effects these secondary metabolites can have, including diminished ruminal methane production, is still being explored [43,50].

Organic acids and reducing sugars are the remaining secondary metabolites that have large concentrations in kudzu. Organic acids can bring about precipitation of calcium ions in the blood, leading to muscle weakness, nephritis, kidney stones, gastrointestinal irritation, and hypocalcemia syndrome in grazing ruminants and horses [43]. In large concentrations, reducing sugars can be problematic for equines [43,51]. Equines fed a high concentrate diet will produce excess lactic acid, resulting in water retention and decreased pH values in the lumen of the digestive tract [43,51]. This risks the possibility of digestive disorders, including osmotic diarrhea and colic [43,51]. Additional secondary metabolites, such as coumarin by-products, depsides and depsidones, alkaloids, steroids, triterpenoids, flavonoids, and cardiac glycosides can also cause negative effects [43]. Lastly, kudzu contains phenolic compounds that can have allelopathic advantages [52,53]. Kudzu leaves and roots contain 2–3% (DM) phenolic compounds [52,53]. Kudzu growing soils contain approximately 50 times more phenolics than soils devoid of kudzu [52,53].

7. Biological Control of Kudzu Using Animals

Plant populations are controlled naturally by their environment and by natural enemies. Invasive species are unique in disrupting an ecosystem to which it does not belong due to a lack of natural control [54]. Invasive species are the second largest cause of biodiversity (total variability within and among species of all plant organisms and their habitats) loss, behind habitat destruction [55]. The degree of invasiveness may increase with a lack of natural competitors [55,56]. Plant species that are established in an environment outside of its natural habitat may be less regulated by the native herbivores in the area, thus resulting in the rapid growth of an invasive plant species [55,56]. This leads to unwanted imbalances in an ecosystem that have potential to harm native species. These invasive plant species can be controlled by chemical or biological methods. Biological control is a method by which one organism is used to control another and can be used to restore ecosystem balance [56]. Biological control of problematic species using animals was recorded as early as 9,500 years ago when cats were domesticated to control rodents [56]. Animals used in biological control of invasive plant species can range from insects to ruminants. Therefore, land owners can manage livestock to use invasive plant species as diet supplements and not only enhance animal production, but also slowly diminish the infestation of the invasive species.

Kudzu (P. montana) must undergo constant application of some control method to yield results in lowering its occurrence. Efforts to successfully control this plant is heavily influenced by timed treatments within its life cycle [6]. Biological control using grazers and browsers can be an effective and cost-efficient method, but it is a slow process [6]. Elimination of kudzu is possible by frequent defoliation by animals over several years. By over defoliating and reducing photosynthetic carbon, hydrogen, and oxygen (CHO), kudzu will halt its metabolic processes and regrowth will be prevented [2]. Defoliation during the fall will reduce the amount of resources roots receive for survival through the winter, thus accelerating the progression of eradication [5].

Kudzu (P. montana) can be eliminated using cattle to over graze it at 80% consumption of the vegetative growth for 3–4 years [2,6]. In contrast, tropical kudzu (Pueraria phaseoloides) could be efficiently controlled using cattle on a rotational grazing system in less than 2 years [57]. However, for tropical kudzu to be eradicated in 2 years, the soil should be compact and drain poorly [57]. Vines which these animals cannot reach may be cut and fed to ensure that defoliation is effective. Remaining plant material after those 3–4 years can be spot treated with recommended herbicides [6]. Furthermore, continuous grazing and browsing of infested areas for approximately 2 months during kudzu’s growing season (May-October in the U.S.) can be effective in its eradication. Older infestations become increasingly hard to eradicate. Kudzu over 10 years old will be minimally affected by over grazing and over browsing, so herbicide application may be necessary [6,7,8]. However, kudzu’s hardy nature tends to make application of herbicides difficult due to the stockpile of starch in its tap root [58].

8. Use of Kudzu as a Feedstock

Grazers (e.g., cattle and sheep) and browsers (e.g., goats and deer) will consume kudzu (P. montana) when available, but it is easily overbrowsed or overgrazed [4]. Kudzu is known to produce a forage of high quality that contains a crude protein (CP) concentration of 15% or higher and a total digestible nutrient (TDN) value of over 60%, but the use of this plant as a feedstuff has limitations. Kudzu grows rapidly, but it produces a low forage yield of 2–4 tons of dry matter per acre per year [2]. Pairing low forage yield with a vine-like growth habit makes harvesting problematic. During dry periods, producers can harvest kudzu annually or biennially, as it retains moisture for growth deep within the roots [2]. Grazers and browsers can be enclosed on a plot of kudzu to control its growth, while also receiving a high quality source of nutrients that potentially results in increased animal performance. Lynd and Ansman [59], Miller and Edwards [60], and Rhoden et al. [61] reported that heavy grazing kudzu for 3–4 growing seasons with cattle, swine, horses, sheep, or goats in August and September could prove to be effective at starving and preventing growth of kudzu. Though data is limited, there are examples of kudzu’s use as a feedstock.

Tropical kudzu contains a high nutrient composition as shown in Table 9. Overall, P. montana and Pueraria phaseoloides tend to be similar in nutritive value. Previous research utilizing tropical kudzu determined that it is palatable and contains an adequate amount of CP for ruminants. Monteiro et al. [62] observed that dairy cows fed a diet that consisted of tropical kudzu supplemented with sorghum grain could support a milk yield of 8.1 kg milk/day.

In 1945, tropical kudzu (Pueraria phaseoloides) was introduced to a herd of Guernsey cows. Initially, few cows ate kudzu, but within days cows consumed it regularly [63]. This experiment was conducted when common pasture crops did not produce a sufficient forage. For one continuously grazing cow during the dry season, an estimated one acre of tropical kudzu was needed. Telford and Childers [63] determined that tropical kudzu should only be grazed once during the dry season. To use kudzu for grazing, it should not be grazed to the ground to preserve quality and regrowth ability. Tropical kudzu had an estimated 11,000–18,150 kg of forage production per year during these experiments. Successful grazing was also established using oxen and goats, and an adapted use for other livestock and poultry.

Kudzu has been used as a source of feed for a variety of research animals. Bhatt and Sharma [23] fed fresh kudzu-vine (Puereria thunbergiana) ad libitum to experimental Angora rabbits. In the Malagasy Republic, both Puereria thunbergiana and Pueraria phaseoloides were successfully grown as a high protein feedstuff [26,58]. Using kudzu as an alternative feed source has been successful due to its palatability and positive results have been shown when fed to beef and dairy cattle [22]. Cows utilizing kudzu as a feedstock produced milk with no color or flavor differences [22]. Piper [72] and Shurtleff and Aoyagi [73] observed that when given a choice, cattle, hogs, chickens, goats, sheep, horses, and rabbits preferred kudzu over grasses or commercial hay. Research conducted in Alabama on Angora goats observed that kudzu populations were effectively controlled with 27 animals/hm2 [52,74]. Additionally, kudzu is ideal as an emergency feed source when common sources are low [22]. Polk and Gieger [75] demonstrated that when alfalfa became limited, kudzu meal at 9% of their diet could be substituted in chick rations. Kudzu and various grasses (e.g., pará grass) can form a desirable combination (when grazing) to increase protein content and reduce the need for commercial feeds [63]. Poultry have been observed to graze kudzu and consume kudzu seeds; however, there have been no reports on potentially using poultry as a way to biologically control kudzu [52,59]. Nworgu and Egbunike [76] researched potential growth performance effects of feeding tropical kudzu (Pueraria phaseoloides) leaf meal to broilers. They concluded that, although the tropical kudzu leaf meal was rich in nutrients, tropical kudzu leaf meal should not be included in broiler diets as it led to poor growth rates. However, there are a growing number of researchers that are assessing leaf meals as an alternative protein supplement in modern poultry diets [77,78]. Thus, further research should assess the potential viability of kudzu’s use as a protein supplement in countries that have limited access to modern protein supplements (e.g., soybean meal). This would indicate that kudzu can be of real relevance for non-herbivore species such as poultry.

9. Summary and Applications

Kudzu’s high quality nutrient composition, degradability, and palatability suggest that it can be a valuable potential feedstock for livestock species. Its widespread distribution and rapid growth rate make it ideally suited as an economical feedstock, particularly in regions of scarce feedstuff availability. Producers must recognize, however, the challenges of managing kudzu for grazing and browsing species. With kudzu’s unique growth habits as a climbing vine, containing livestock species in areas of high kudzu mass can be challenging and may require considerable ingenuity. Furthermore, efforts to prevent overgrazing/overbrowsing should be highlighted. Kudzu leaf volume can be quickly depleted, effectively limiting kudzu’s use as a feedstock. Overgrazing/overbrowsing would be a preferred approach if the producer was attempting to control kudzu with livestock, but not if using as a sustainable source of nutrients.

This review has attempted to coalesce an array of information on kudzu into a comprehensive overview of its characteristics and potential significance as a feedstuff for a variety of domestic animal species. Much information, however, remains to be elicited on kudzu. Kudzu is often viewed in a negative light as an invasive weed species. Kudzu is, however, much more than that and holds significant potential as a feedstock in the United States and other countries where nutrient availability for production animals is limited.

Author Contributions

Conceptualization, J.P.G. and K.M.D.; Methodology, J.P.G. and K.M.D.; Validation, J.P.G. and K.M.D.; Formal analysis, J.P.G. and K.M.D.; Investigation, J.P.G. and K.M.D.; Writing—original draft preparation, J.P.G.; Writing—review and editing, J.P.G. and K.M.D.; Visualization, J.P.G. and K.M.D.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

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41
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How I Make Spruce and Fir Tip Syrup | Easy and Economical

Videosgith345 posted the article • 0 comments • 41 views • 2019-10-07 16:14 • came from similar tags

 
 
 
 
 
 
 
 


38
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Farm VLOG | Making a Willow Trellis with Kate

Videosgith345 posted the article • 0 comments • 38 views • 2019-10-07 16:12 • came from similar tags

 
 
I have been wanting to make a trellis for my Clematis and with Kate's help I finally got it done.
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I have been wanting to make a trellis for my Clematis and with Kate's help I finally got it done.
 


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41
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Today I wanted to give you a little update on what's been happening around here this summer and introduce you to some of the puppies.

Videosgith345 posted the article • 0 comments • 41 views • 2019-10-07 16:10 • came from similar tags

 
 
 
 
 
 
 
 


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How to Grow Amazing Broccoli | Tips, Tricks and Troubleshooting

Videosgith345 posted the article • 0 comments • 38 views • 2019-10-07 16:09 • came from similar tags

I've been asked about how I grow my broccoli so today I share with you everything I've learned about growing it. I hope you find it helpful.
 
 
 
 

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I've been asked about how I grow my broccoli so today I share with you everything I've learned about growing it. I hope you find it helpful.
 
 
 
 


 
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Come Join Us in the Garden | Large Family Harvest | Eating a 10 Month Old Cabbage

Videosgith345 posted the article • 0 comments • 42 views • 2019-10-07 16:07 • came from similar tags

 
Today I'd like to invite you to join us in the garden for our first large harvest of the 2019 year! I also fill you in on the root cellar cabbage experiment.
 
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Today I'd like to invite you to join us in the garden for our first large harvest of the 2019 year! I also fill you in on the root cellar cabbage experiment.
 
 


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Large Family Garden Haul | Root Cellar Food Storage Tips

Videosgith345 posted the article • 0 comments • 38 views • 2019-10-07 16:06 • came from similar tags

 
We spent the day out in the garden and got some harvesting done before the frost comes, which is just around the corner now.
 

 
 
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We spent the day out in the garden and got some harvesting done before the frost comes, which is just around the corner now.
 


 
 
 
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FULL September Garden Tour | Large Family Northern Garden | Zone 3

Videosgith345 posted the article • 0 comments • 39 views • 2019-10-07 16:05 • came from similar tags

 
 
 
 
 
 
 
 
 
 
 
 


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Large Family Giant Squash Harvest | Winter Squash Storage Tips

Videosgith345 posted the article • 0 comments • 34 views • 2019-10-07 16:04 • came from similar tags

 
Today we went out to the garden and started harvesting our squash. So far we're at 137 squash, with a few more yet to go. Thanks for joining us
 
  view all
 
Today we went out to the garden and started harvesting our squash. So far we're at 137 squash, with a few more yet to go. Thanks for joining us
 
 


37
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Large Family Giant Squash Harvest | Winter Squash Storage Tips

Videosgith345 posted the article • 0 comments • 37 views • 2019-10-07 16:04 • came from similar tags

 
Today we went out to the garden and started harvesting our squash. So far we're at 137 squash, with a few more yet to go. Thanks for joining us
 
  view all
 
Today we went out to the garden and started harvesting our squash. So far we're at 137 squash, with a few more yet to go. Thanks for joining us
 
 


40
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Canadian Farm VLOG | Meet the Animals | Homemade Tomato Soup

Videosgith345 posted the article • 0 comments • 40 views • 2019-10-07 16:03 • came from similar tags

I had big plans today, but as sometimes happens, the best laid plans don't always work out. I changed gears mid morning and thankfully, I was still be able to get some things done. I hope you enjoy coming along with me for the morning.
 
 
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I had big plans today, but as sometimes happens, the best laid plans don't always work out. I changed gears mid morning and thankfully, I was still be able to get some things done. I hope you enjoy coming along with me for the morning.
 
 
 


42
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September 2019 Garden Harvest | Do We Pay Our Kids to do Chores?

Videosgith345 posted the article • 0 comments • 42 views • 2019-10-07 16:01 • came from similar tags

 
Hey friends! Today is the last day of the 2019 gardening season for LMR. I'm usually really ready for the end of the season, but this year I'm already missing my garden. It has been an awesome gardening season and I am so thankful that the garden produced so well this year. Today we need to get up the carrots and maybe a few parsnips. Thanks for coming along.
 

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Hey friends! Today is the last day of the 2019 gardening season for LMR. I'm usually really ready for the end of the season, but this year I'm already missing my garden. It has been an awesome gardening season and I am so thankful that the garden produced so well this year. Today we need to get up the carrots and maybe a few parsnips. Thanks for coming along.
 


 
42
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Final Large Family Garden Haul | Getting Ready for Winter | Bluebell had Her Calf

Videosgith345 posted the article • 0 comments • 42 views • 2019-10-07 15:59 • came from similar tags

 
 
 
 
 
 
 
 


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The favorite soup of food lovers, all tastes in one jar—Fo tiao qiang

VideosLiziqi posted the article • 0 comments • 62 views • 2019-09-17 11:53 • came from similar tags

 

 
1.The ingredients to make Fo tiao qiang must be fresh, so the first step is blanching chicken, old duck, ribs、trotter、pork tripe、duck gizzard(some people also put chicken feet and soaked cuttlefish) in, then add ginger and spring onion and boil all that for 6 hours on a small flame. 
2.Soak abalone and sea cucumber for one or two days. The soaking time is depending on the temperature, remember to change water during the process. 
3.Better soak tendons and fish maw with oil. Put cold oil in a cold pot, let them get soaked and turn the fire on after some time. Let the temperature raise up slowly.After that, the tendons can be soaked with warm water, this is called a water-oil immersion. 
4.The component of yellow wine depends on yourself, if you like it, you can put more in. If no then less. 
5.The actual shark fin is only thin cartilage, which is cut while the shark is alive. Unable to swim effectively, sharks sink to the bottom of the ocean and die of suffocation. I strongly suggest people to use the man made shark fins that you can buy everywhere instead of the real fins. Less killing for a better ecosystem. view all
 


 
1.The ingredients to make Fo tiao qiang must be fresh, so the first step is blanching chicken, old duck, ribs、trotter、pork tripe、duck gizzard(some people also put chicken feet and soaked cuttlefish) in, then add ginger and spring onion and boil all that for 6 hours on a small flame. 
2.Soak abalone and sea cucumber for one or two days. The soaking time is depending on the temperature, remember to change water during the process. 
3.Better soak tendons and fish maw with oil. Put cold oil in a cold pot, let them get soaked and turn the fire on after some time. Let the temperature raise up slowly.After that, the tendons can be soaked with warm water, this is called a water-oil immersion. 
4.The component of yellow wine depends on yourself, if you like it, you can put more in. If no then less. 
5.The actual shark fin is only thin cartilage, which is cut while the shark is alive. Unable to swim effectively, sharks sink to the bottom of the ocean and die of suffocation. I strongly suggest people to use the man made shark fins that you can buy everywhere instead of the real fins. Less killing for a better ecosystem.
48
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the delicious food from the mountain—Termitomyces mushroom oil

VideosLiziqi posted the article • 0 comments • 48 views • 2019-09-17 11:51 • came from similar tags

 
 
 

 
After the raining season, next to the termite mound Termitomyces mushroom, one food that tastes better than pine mushroom and is out of ash. Small pieces of Termitomyces, Sichuan pepper with chopped chili make the marvelous termitomyces mushroom oil. If you eat it with noodles, it tastes delicious!!! view all
 
 
 


 
After the raining season, next to the termite mound Termitomyces mushroom, one food that tastes better than pine mushroom and is out of ash. Small pieces of Termitomyces, Sichuan pepper with chopped chili make the marvelous termitomyces mushroom oil. If you eat it with noodles, it tastes delicious!!!
49
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Laba congee, the heavy fragrance will stick to the chopsticks

VideosLiziqi posted the article • 0 comments • 49 views • 2019-09-17 11:49 • came from similar tags

 


Kids kids, don’t get temped New year is coming right after Laba festival…… A year is about to be over It’s time to cook Laba congee……
  view all
 



Kids kids, don’t get temped New year is coming right after Laba festival…… A year is about to be over It’s time to cook Laba congee……
 
43
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Long, tender and fresh: bean sprouts are nutritious and pollution-free

VideosLiziqi posted the article • 0 comments • 43 views • 2019-09-17 11:48 • came from similar tags

 
 
 


When I was younger, planting bean sprouts was always part of my summer activities. Dig a hole, put some water in it, cover the hole after the green beans are in. For the rest? Time will take care of it. It’s super easy, everybody can make it, so do you want to give it a chance?
  view all
 
 
 



When I was younger, planting bean sprouts was always part of my summer activities. Dig a hole, put some water in it, cover the hole after the green beans are in. For the rest? Time will take care of it. It’s super easy, everybody can make it, so do you want to give it a chance?
 
49
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inter cuisine with great meaning—flower shaped shrimp

VideosLiziqi posted the article • 0 comments • 49 views • 2019-09-17 11:47 • came from similar tags

 

 
The must have cuisine for NYE dinner—flower shaped shrimp. The outside part of this cuisine looks like a blooming flower, which is beautiful and joyful. Other than that, shrimp is nutritious for everybody and has a Chinese meaning implying wealth and luck. Let this “wealthy flower” open on your NYE dinner table. view all
 


 
The must have cuisine for NYE dinner—flower shaped shrimp. The outside part of this cuisine looks like a blooming flower, which is beautiful and joyful. Other than that, shrimp is nutritious for everybody and has a Chinese meaning implying wealth and luck. Let this “wealthy flower” open on your NYE dinner table.
47
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Kimchi, this sweet and sour flavor food will amaze your winter

VideosLiziqi posted the article • 0 comments • 47 views • 2019-09-17 11:46 • came from similar tags

 

 
 
After the frost, it’s cloudy outside, the smog surrounds us and will not disperse! But the cold weather makes vegetables taste a lot better, so I cut up some cabbage to make kimchi.Kimchi is the traditional food from Yanbian Korean, every family makes it in a different way. For me, I stewed kimchi with some dried meat. In a sour and spicy soup with the smell from the meat, it warms up my whole winter.
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After the frost, it’s cloudy outside, the smog surrounds us and will not disperse! But the cold weather makes vegetables taste a lot better, so I cut up some cabbage to make kimchi.Kimchi is the traditional food from Yanbian Korean, every family makes it in a different way. For me, I stewed kimchi with some dried meat. In a sour and spicy soup with the smell from the meat, it warms up my whole winter.
 
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When spring comes, let’s enjoy a pot of Sichuan stew dried ribs

VideosLiziqi posted the article • 0 comments • 50 views • 2019-09-17 11:45 • came from similar tags

 

 
 
ried ribs are not completely dried, it still has the fresh taste of meat, combined with the mellow fragrance from dried meat. Warm up a bottle of wine, sit next to the stove, enjoy the soup and an amazing stew meat, what else could be better! view all
 


 
 
ried ribs are not completely dried, it still has the fresh taste of meat, combined with the mellow fragrance from dried meat. Warm up a bottle of wine, sit next to the stove, enjoy the soup and an amazing stew meat, what else could be better!
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The different tastes of steam dried meats make up new year's atmosphere

VideosLiziqi posted the article • 0 comments • 61 views • 2019-09-17 11:44 • came from similar tags

 
 

 Time flies, the three-ninth period has passed already, so I won’t have dried meat for new year if I don’t make it now! I’ve always been tempted by steamed Hunan dried meats, so I make more dried chicken and cured fish this year. Cut the dried meat into pieces, then put them on a plate to steam them, use the soup from the meat to fry vegetables … I can’t describe how amazing it is! In another video I almost have a fight with the photographer to defend my dishes, lol….
 
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 Time flies, the three-ninth period has passed already, so I won’t have dried meat for new year if I don’t make it now! I’ve always been tempted by steamed Hunan dried meats, so I make more dried chicken and cured fish this year. Cut the dried meat into pieces, then put them on a plate to steam them, use the soup from the meat to fry vegetables … I can’t describe how amazing it is! In another video I almost have a fight with the photographer to defend my dishes, lol….
 
 
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The wild jujube is ripe, it’s time to make some wild jujube cake

VideosLiziqi posted the article • 0 comments • 47 views • 2019-09-17 11:43 • came from similar tags

 

 
We called wild jujube “Biti guo” when we were younger. At the season when jujube get ripe and fall to the ground, running to the backyard to collect it is the first thing we do when we got up.Probably because not too many choices are left for snacks, nothing is better than these sweet and sour wile jujube at that time.Now? People getting in a better and better condition, so the wild jujube tastes too sour, so I just add some sugar to make wild jujube cake.
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We called wild jujube “Biti guo” when we were younger. At the season when jujube get ripe and fall to the ground, running to the backyard to collect it is the first thing we do when we got up.Probably because not too many choices are left for snacks, nothing is better than these sweet and sour wile jujube at that time.Now? People getting in a better and better condition, so the wild jujube tastes too sour, so I just add some sugar to make wild jujube cake.
 
47
Views

A multi layer sole shoes for my grandma, in memory of good old days

VideosLiziqi posted the article • 0 comments • 47 views • 2019-09-17 11:42 • came from similar tags

 

 
A multi layer sole shoes for my grandma, in memory of good old days.Probably everybody has some multi layer sole shoes with warm memories in their lives. When I was younger, I have been wearing the multi layer sole shoes all the time, which was made by grandma with old clothes.People nowadays have different kinds of beautiful shoes and.Such an out of style shoe made tedious work just appear in memories today…… view all
 


 
A multi layer sole shoes for my grandma, in memory of good old days.Probably everybody has some multi layer sole shoes with warm memories in their lives. When I was younger, I have been wearing the multi layer sole shoes all the time, which was made by grandma with old clothes.People nowadays have different kinds of beautiful shoes and.Such an out of style shoe made tedious work just appear in memories today……
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I could eat three bowls of rice with this dish even without meat

VideosLiziqi posted the article • 0 comments • 48 views • 2019-09-17 11:41 • came from similar tags

 

I could have three bowls of rice with a side of these pickles.I could live without meat but I can’t live without pickle, does anybody like me?So today I show you guys how to make the local Sichuan pickles, hope you guys will like it.Please follow my page, if you want to tell me anything, leave a comment under this video.
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I could have three bowls of rice with a side of these pickles.I could live without meat but I can’t live without pickle, does anybody like me?So today I show you guys how to make the local Sichuan pickles, hope you guys will like it.Please follow my page, if you want to tell me anything, leave a comment under this video.
 
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On the first snowy night, cook a pot of chicken with firewood to get warm

VideosLiziqi posted the article • 0 comments • 48 views • 2019-09-17 11:40 • came from similar tags

 

 

First snow in a cold night.Sit around the hearth, cook a pot of chicken with firewood.Guzzling away the meat, sipping the wine, savoring the moment.Waaaa~Who cares whatever the annoyance is Just let it be!!!
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First snow in a cold night.Sit around the hearth, cook a pot of chicken with firewood.Guzzling away the meat, sipping the wine, savoring the moment.Waaaa~Who cares whatever the annoyance is Just let it be!!!