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Article

Transformation Capability Optimization and Product Application Potential of Proteatia brevitarsis (Coleoptera: Cetoniidae) Larvae on Cotton Stalks

by
Guangjie Zhang
1,
Yeshan Xu
1,
Shuai Zhang
1,
Andong Xu
1,
Zhuo Meng
1,
Hao Ge
1,
Jing Li
1,
Yusheng Liu
2,* and
Deying Ma
1,*
1
Engineering Research Centre of Cotton, Ministry of Education, Key Laboratory of the Pest Monitoring and Safety Control on Crop and Forest, College of Agronomy, Xinjiang Agricultural University, 311 Nongda East Road, Urumqi 830052, China
2
College of Plant Protection, Shandong Agricultural University, Tai’an 271018, China
*
Authors to whom correspondence should be addressed.
Insects 2022, 13(12), 1083; https://doi.org/10.3390/insects13121083
Submission received: 30 August 2022 / Revised: 20 November 2022 / Accepted: 22 November 2022 / Published: 24 November 2022
(This article belongs to the Special Issue Insects as Food and Feed: Opportunities and Risks)
Browse Figure
Versions Notes

Abstract

:

Simple Summary

The Xinjiang Uyghur autonomous region is the most important area for cotton production in China, where recycling of cotton stalks (CS) as a useful resource should be encouraged. This article investigated the technical feasibility of CS as a feed and fertilizer based on the transformation of P. brevitarsis larvae. Decomposition inoculant, fermentation duration, and cattle manure ratio were considered the key factors affecting the transformation capability of P. brevitarsis larvae on CS. The research showed that 40–50% of cattle manure, 0.1% VT inoculant, and a fermentation duration of 25–30 days were the optimal technical parameters. The protein content of the larval body was as high as 52.49%, and the fat content was 11.7%. The organic matter content of frass (larvae dung-sand) was 54.8%, and the content of total nitrogen, phosphorus, and potassium (TNPK) was 9.04%, which is twice more than that of the organic fertilizer standard (NY525-2021, Beijing, China, TNPK ≥ 4.0%). The application of CS as feed (larval body) and fertilizer (larvae dung-sand) is feasible, promoting the utilization of both CS and cattle manure.

Abstract

Cotton stalks (CS) are a potential agricultural biomass resource. We investigated the use of CS as a feed for Proteatia brevitarsis Lewis larvae and the resulting frass (larvae dung-sand) as a fertilizer. Based on a three-factor experiment (decomposition inoculant, fermentation duration, and cattle manure ratio), the optimal parameters for the transformation of CS using P. brevitarsis larvae were determined as 40–50% of cattle manure, the use of VT inoculant and a fermentation duration of 25–30 days. Regarding the products of the transformation, the protein content of the larval body was as high as 52.49%, and the fat content was 11.7%, which is a suitable-quality insect protein source. The organic matter content of larvae dung-sand was 54.8%, and the content of total nitrogen, phosphorus, and potassium (TNPK) was 9.04%, which is twice more than that of the organic fertilizer standard (NY525-2021, Beijing, China, TNPK ≥ 4.0%), and larvae dung-sand has the potential of fertilizer application. Therefore, CS as a feed and fertilizer based on the transformation of P. brevitarsis larvae is feasible, and it is a highly efficient way to promote the utilization of both CS and cattle manure.

1. Introduction

The Xinjiang Uyghur autonomous region is the most important area for cotton (Gossypium hirsutum L.) production in China. The cotton planting area is about 2.5 million hectares, and the cotton yield exceeds 5.0 million tons [1]. This area also produces cotton stalks (CS) equivalent to five times the cotton yield. Excluding the cotton leaves and root stubble, the CS yield that can be mechanically harvested is approximately 12 million tons [2]. With the characteristics of high calorific value, prominent cellulose and lignin content, and abundant nutrients, CS is used as a renewable agricultural biomass resource for energy [3,4], industrial raw materials [5], fertilizer [6], and feed [7,8]. However, more than 80% of CS is currently crushed and returned to the field directly as fertilizer [9,10]. The fertilizer effect of CS has been diminishing due to the direct return to the field in successive years. Meanwhile, the disadvantageous effects (e.g., aggravation of cotton Verticillium wilt (Verticillium dahliae kieb), deterioration of the soil structure) on cotton growth, yield, and quality have become more apparent [11,12,13,14,15]. For this reason, the indirect return of CS to the field has been attracting increased attention. In recent years, technologies and the utilization of micro-livestock (e.g., environmental insects, earthworms) to transform organic waste (e.g., crop residues, livestock manure) into feed and fertilizer have been attracting greater attention [16,17,18,19,20,21,22,23,24,25,26]. Micro-livestock has notable advantages in reducing greenhouse gas emissions (e.g., CO2, CH4) and promoting carbon peaking and carbon neutrality strategies [27,28,29]. In particular, the application potential of Proteatia brevitarsis Lewis larvae to transform crop stalks and animal manure is outstanding [30,31].
P. brevitarsis is an insect belonging to the genus Protaetia, the family Cetoniidae, and the order Coleoptera, which is widely distributed in China, Russia, North Korea, Mongolia, and other countries [32,33]. Adults are phytophagous or saprophagous, which are harmful in nature [34]. The larvae are saprophagous, which have strong transformation capability and can transform crop stalks [35,36,37], animal manure [38,39,40], edible fungus chaff [41,42,43,44] and other organic wastes efficiently. Dry larvae are a relatively high-quality protein feed ingredient with a protein content of about 50% [45,46,47,48]. Frass (larvae dung-sand) is rich in humic acids (HAs), beneficial microorganisms and nutrient elements, and it has suitable granularity and stable properties [49,50]. Dung-sand is an excellent raw material for bio-fertilizer and has shown promising effects in the cultivation of horticultural crops [51,52,53,54]. The larvae, together with the larvae of other Scarabaeoidae (i.e., Holotrichia parallela Motschulsky), are known as grubs. As the traditional medicine and feed insects in China and Korea, grubs have functions in anticancer [55,56], antibacterial [57], antioxidant [58], and anti-inflammation [59,60]; therefore, P. brevitarsis has suitable development prospects in food and feed industries [61]. On the other hand, the genome and transcriptome sequencing of P. brevitarsis has been completed, which lays the foundation for in-depth research and development of its resource value of P. brevitarsis [62,63]. In conclusion, P. brevitarsis has potential resources in the fields of transforming organic wastes, pharmaceutical applications, feed ingredients and organic fertilizers.
Decomposition microorganisms promote pre-decomposition and humification of materials and provide assistance to carrion feeders (e.g., earthworms, dung beetles, wood-eating beetles, the black soldier fly (Hermetia illucens L.), etc.) in feeding and digesting food [64,65,66,67,68,69]. Studies have shown that fermentation of lignin- and cellulose-rich organic materials with specific microbial inoculants followed by vermicomposting or insect composting can not only improve the yield of production and nutritional value of frass but also shorten the time for organic materials to become standard organic fertilizer [70,71,72,73,74,75]. Based on the previous work, this study initially screened five decomposition inoculants suitable for the pre-treatment of organic waste from the transformation of P. brevitarsis larvae [31,40]. On the other hand, the C/N ratio is essential for material decomposition [76,77,78]. This study chose cattle manure, which is plentiful in the Xinjiang region and is a better feed for P. brevitarsis larvae, as the auxiliary material to adjust the C/N ratio of the raw materials [79]. Previous studies have shown that fermentation duration is another key factor affecting the transformation capability of P. brevitarsis larvae [37,46]. We carried out a three-factor (decomposition inoculant, fermentation duration, and cattle manure ratio) five-level orthogonal experiment to explore the best technical parameters of the transformation capability for CS using P. brevitarsis larvae and to evaluate the application potential of the larval body as a feed ingredient and larvae dung-sand as organic fertilizer. The significance of this study is to provide a method reference for improving the transformation capability of organic waste and promoting the utilization of cotton stalks and cattle manure.

2. Materials and Methods

2.1. Experimental Site

The experimental site was located in the Industrialization Research Base of Environmental Insect Transforming Organic Waste, Xinjiang Agricultural University, in Manas County (44°13′49″ N, 86°23′3″ E), Changji Prefecture, China.

2.2. Experimental Materials

Cotton stalks (CS) and cattle manure were taken from farmers or herders around the base. The larvae of P. brevitarsis were self-reproduced in the base. Materials such as decomposition inoculants (Table 1), cucumber (Cucumis sativus L.) seeds (Changchun Mithorn, Xinjiang Lianchuang Seed Co., Ltd., Urumqi, China; for the determination of the seed germination index), electronic balance (LT3002, Changshu Tianliang Instrument Co., Ltd., Changshu, China) and experimental tools were purchased or previously owned.

2.3. Experimental Methods

2.3.1. Preliminary Selection of the Optimal Combination of Decomposition Inoculant, Fermentation Duration, and Cattle Manure Ratio

CS and cattle manure were dried and crushed for use. The three-factor five-level orthogonal experiment (Table 2) of decomposition inoculant, cattle manure ratio and fermentation duration were conducted in September 2020. A total of 25 treatments were designed by IBM SPSS Statistics 23.0 (SPSS 23.0) (L25 (56) orthogonal table) and recorded as A1-5 B1-5 C1-5. The CK groups were the CS fermented for 0, 10, 15, 20, 25, and 30 days. The initial materials for every treatment were 90 kg (dry weight, the same as below). The decomposition inoculants were added at the recommended amount. The water content (WC) of the materials was adjusted to 65 (±5)%. Then, the materials were mixed and piled into a cone shape. The ambient temperature and fermentation temperature of material pile (20 cm depth) were recorded daily. Samples were taken from 20 to 30 cm below the surface of material pile (five-point sampling method) according to the days of fermentation duration for each treatment. Each sample weighed 3 kg (fresh weight) and was frozen and stored in the refrigerator. In strict accordance with the process of turning the material pile every 5 days and sampling first and then turning the pile, and the material fermentation and sampling experiments were finished after 30 days.
The samples were thawed naturally, and each culture box (1 L) was filled with 280 g of fresh material (about 80 g dry weight), 10 larvae (the 3rd instar and 15th day) of P. brevitarsis were put into the box. Thereafter, the transformation experiment was carried out for 15 days. Each treatment was repeated four times. On the 16th day, weighing larvae weight gain, feed intake and dung-sand weight, the feed utilization rate, dung-sand conversion rate and mortality were calculated by Liu (2012) [80]. The optimum technical parameters were selected by making a comprehensive comparison of the transformation capability of larvae.
Calculation formula (Mass unit/mg):
Feed utilization rate = (total feed weight − remaining feed weight)/total feed weight × 100%
Dung-sand conversion rate = Dung-sand weight/(feeding weight − dry larvae weight gain) × 100%
Mortality = number of dead larvae/number of tested larvae × 100%

2.3.2. Validation of the Optimal Technical Parameters for CS as Feed and Fertilizer

The validation experiment was carried out in May 2021. The optimal combination based on the experimental results of Section 2.3.1 was A5B4C4: VT inoculant, the ratio of cattle manure was 40%, and the fermentation duration was 25 days. The control feed (CK) was cotton stalks fermented for 25 days, and the specific operation is referred to in Section 2.3.1. Thereafter, we determined the transformation capability data of the P. brevitarsis larvae to CS and verified the feasibility of the optimal technical parameters.

2.3.3. Determination of Related Nutritional Indicators for CS Transformation Products as Feed and Fertilizer

The feed or fertilizer nutrition indicators of the raw materials (CS and cattle manure), fermented materials (fermented CS and A5B4C4 feed), and products (dry larvae and larvae dung-sand) of the optimal treatment and control were determined (refer to GB 13078-2017 and NY525-2021 standards, Beijing, China, and tested by Sichuan Weil Testing Technology Co., Ltd., Chengdu, China. The seed germination index was determined by referring to the appendix of NY525-2021, Beijing, China). To explore the application potential of CS transformation by P. brevitarsis.

2.4. Data Processing

SPSS 23.0 was used to conduct a three-factor five-level analysis of variance with repeated observations and no interaction. One-Way ANOVA was performed for the CK groups and the three factors, and Tukey’s multiple comparison analysis was performed for the differences between different treatments (p < 0.05). Microsoft Excel 2013 was used to record and organize data and draw tables. Sigma Plot 14 was used to draw graphs.

3. Results

3.1. Preliminary Selection of the Optimal Combination of Decomposition Inoculant, Fermentation Duration, and Cattle Manure Ratio

3.1.1. Effect of Fermentation Duration on Transformation Capability to CS Using P. brevitarsis Larvae

As shown in Table 3, the transformation capability of the P. brevitarsis larvae on CS was significantly different under different fermentation duration. The optimal indexes of feed intake, larvae weight gain, and feed utilization rate were 25 days after fermentation. The dung-sand weight was the best after 20 days of fermentation, but the difference was insignificant compared with 25 days of fermentation. The dung-sand conversion rate was optimal after 15 days of fermentation, which was not significantly different from that after 20 days of fermentation. The mortality of larvae was the lowest at the 15 and 25 days of fermentation duration, and there was no significant difference among all treatments. Comprehensive analysis showed that the transformation capability of the P. brevitarsis larvae on CS was the best for 25 days after fermentation.

3.1.2. Influence of Three Factors on the Fermentation Temperature of Materials

As shown in Table 4, under the fermentation cycle of every 5 days, the influence of the decomposition inoculant on the fermentation temperature of the material pile did not reach a significant difference level, and the overall situation was relatively stable. The influence of the ratio of cattle manure on the fermentation temperature of the material pile reached a significant difference level on the 10th, 20th, and 30th days. In the first 20 days, the fermentation temperature of the material pile at the 10% cattle manure group was the highest, and that of the 50% cattle manure group was lower. After 25 days, the temperature showed an opposite trend. In terms of fermentation duration, only 25 days of fermentation showed a significant difference level, which should be the inflection point of material fermentation temperature. After 30 days of fermentation, except for the CK group, the fermentation temperature of 25 treatments was above 30 °C, which was much higher than the ambient temperature on the same day. In the early stage, the temperature of the CK group was high, but the temperature dropped sharply after 20 days. The temperature of the 25 treatments only dropped significantly after 25 days of fermentation, which was related to the degree of material fermentation entering the later stage and also related to the low ambient temperature (the average temperature after 20 days was lower than 10 °C). The trend of temperature variation among different treatments showed that adding decomposition inoculant and cattle manure could maintain the temperature of the material pile in a high and stable range and then promote the fermentation of CS.

3.1.3. Differences in the Transformation Capability of the P. brevitarsis Larvae on CS Considering Three Factors

Table 5 has shown that the transformation capability of the P. brevitarsis larvae with different decomposition inoculants was significantly different in the indexes of feed intake and weight gain but not significantly different in the other four indexes, and VT inoculant was the best. As for the factor of cattle manure ratio, 40% and 50% groups showed the best performance, and the indexes of feed intake, dung-sand weight, feed utilization rate, and dung-sand conversion rate were significantly different from the 10% and 20% groups. The transformation capability of the P. brevitarsis larvae was the best at 25 days and 30 days after fermentation, and the feed intake, dung-sand weight, and feed utilization rate of the third instar larvae were significantly higher than those at 10 days after fermentation. The difference in transformation capability of the larvae under the three factors provided suitable support for optimizing the technical parameters of the transformation of CS using the P. brevitarsis.

3.1.4. Test of Inter-Subjects Effects under Three Factors

It can be seen from Table 6 that the effects of the three factors on feed intake, dung-sand weight, feed utilization rate, and dung-sand conversion rate were significantly different, while the differences in larvae weight gain and mortality were not significant. This experiment mainly analyzed four indexes with significant differences. According to the comparison of the type III sum of squares, the order of influencing factors for the feed intake was from largest to smallest: B > C > A. For the three assessment indicators of dung-sand weight, feed utilization, and dung-sand conversion rate, the order of the three effect factors was C > B > A.

3.1.5. Intuitive Analysis and Tukey Test under Three Factors

As can be seen from Figure 1, when the feed intake (a) and dung-sand weight (b) were used as the screening indicators, the optimal combination of the decomposition inoculant (A), cattle manure ratio (B), and fermentation duration (C) was: VT inoculant, 40% (50%) of cattle manure ratio, and 30 days of fermentation duration.
When the feed utilization rate (c) was used as the screening indicator, the optimal combination of the decomposition inoculant, cattle manure ratio, and fermentation duration was: VT inoculant, 40% (50%) of cattle manure ratio, and 30 days of fermentation duration. When the dung-sand conversion rate (d) was used as the screening indicator, the RW and NFK inoculant, 40% of cattle manure ratio, and 30 days (25 days) of fermentation duration were optimum.
According to the results of intuitive analysis and Tukey’s test (Figure 1), and referring to the results that the transformation capability of the P. brevitarsis larvae was the best when CS was fermented for a duration of 25 days (Table 3), the principles of minimizing cattle manure ratio, shortening fermentation duration, and reducing treatment cost were also considered. The optimal combination was A5B4-5C4-5 (0.1% VT inoculant, 40–50% of cattle manure ratio, and 25–30 days of fermentation duration), and A5B4C4 was given preference.

3.2. Validation of the Optimal Technical Parameters for the Transformation of CS Using P. brevitarsis Larvae

CS fermentation and transformation experiments were performed under the optimal combination (A5B4C4). The results are shown in Table 7.
It can be seen from Table 7 that under the optimal technology combination, the transformation capability of the P. brevitarsis larvae on the A5B4C4 feed was significantly different in feed intake, dung-sand weight, feed utilization rate, dung-sand conversion rate, and mortality with that of CK, and the feed utilization rate and dung-sand conversion rate were over 80%. Therefore, the optimal technical parameters for CS resource utilization were determined as A5B4C4: 0.1% VT inoculant, 40% of cattle manure ratio, and 25 days of fermentation duration. The fresh weight of fermentation material (A5B4C4 feed) was weighed, the water content was measured, and the yield of the material was calculated to be 62.85%. It can be concluded that 104.75 g of A5B4C4 feed can be obtained by adding 66.67 g of cattle manure for every 100 g of CS raw material. A total of 70.92 g of larvae dung-sand can be obtained by the third instar larvae of P. brevitarsis, and the weight gain of the dry larvae is 3.06 g, and 20.88 g of residue is left.

3.3. Determination of Relevant Nutritional Indicators of Raw Materials, Fermentation Materials, and Products

3.3.1. Determination of Nutritional Indicators of Raw Materials, Fermented Materials, and Insect Bodies as Feed

It can be seen from Table 8 that the protein content of fermented CS increased by 41.9%, the crude fiber content decreased slightly, the content of gross energy (GE) was slightly increased, and the contents of crude ash and water-soluble chlorides increased greatly. The crude protein (CP) content of A5B4C4 feed reached 13.18%, which was slightly lower than 14.16% of cow manure and was 1.29 and 1.84 times that of the fermented and unfermented CS. Compared to the fermented CS, the A5B4C4 feed significantly reduced crude fiber content, increased the crude ash and water-soluble chloride content, and decreased GE. The content of free gossypol (FG) in fermented materials was about 50% lower than that in raw materials. The FG in the A5B4C4 feed was not detected in the larvae of P. brevitarsis (detection limit is 20 mg/kg). The protein (52.49%) and fat (11.7%) content of the P. brevitarsis dry larvae were much higher than those of the A5B4C4 feed, while the content of crude fiber was only 6.1%, and the content of water-soluble chloride was lower than that of the A5B4C4 feed. The GE (19.20 KJ/g) was intermediate between carbohydrate (17.5 KJ/g) and protein (23.64 KJ/g). The insect-microorganism composite systems can improve the nutrition indicators of CS as a feed, and the larval body was 7.31, 19.50, and 1.16 times higher than that of CS in protein, fat, and total energy and more than 50% lower in FG, and the content of crude fiber is only 1/6 of CS.

3.3.2. Determination of Nutritional Indicators for Raw Materials, Fermentation Materials, and Larvae Dung-Sand as Organic Fertilizer

As shown in Table 9, the organic matter (OM) content of the six materials was above 54%, and the CS was the highest (67%). Their total nutrient (TNPK) content was more than 4.0%. The total nutrient (TNPK) and potassium (TK) content of the A5B4C4 feed were 9.04% and 4.44%. For the germination index (GI), the unfermented CS (47.09%) and manure (66.87%) had certain toxicity to seed germination, the GI of the remaining four materials was more than 70%, indicating that it was non-toxic to seed germination, and the GI of fermented CS was 102.88, which could promote the seed germination. The pH value of the six materials ranged from 6.6 to 9.5, and it was neutral to alkaline overall. OM decreased, HAs and GI increased first and then decreased, and TNPK, water-soluble chloride, and pH values increased in the insect-microorganism composite process from raw materials to fermentation materials and then to larvae dung-sand. In addition to pH value, two kinds of fermentation materials and two kinds of larvae dung-sand were in line with the latest standards of organic fertilizers in China in terms of OM, NPK, and GI (NY525-2021, NPK ≥ 4%, DOM ≥ 30%, GI ≥ 70%, pH 5.5–8.5).

4. Discussion

This study showed that for every 100 g of cotton stalks supplemented with 66.67 g of manure, 104.75 g of A5B4C4 feed was obtained, and 70.92 g of dung-sand was obtained after transformation by the third instar larvae of P. brevitarsis. The weight gain of the dry larvae was 3.06 g, and 20.88 g of residue remained. The larvae of the P. brevitarsis had a 27.41-fold ability to transform fermented materials (FCR = weight of feed intake/weight gained), which was nearly six times higher than that of the black soldier fly (FCR = 4.5), and had a higher feed utilization rate (80.07% ± 0.65%) and dung-sand conversion rate (84.55% ± 0.53%) [73]. Compared with other dung beetles, P. brevitarsis are more suitable to perform the ecological function of converting organic waste in concentrated agricultural and livestock areas because of their high reproductive ability and their tendency to gather to lay eggs and feed [34,46,65,81,82]. A previous study showed that the ratio of material surface/volume was positively correlated with the fermentation effect, and future work could improve the transformation capability of P. brevitarsis larvae on cotton stalks by reducing the crushing particle size and other measures [75,83]. Previous studies have only focused on the transformation efficiency of the larvae of P. brevitarsis for fermented material; this study also paid specific attention to the productivity from raw materials to fermented materials. According to the calculation results, the productivity of the A5B4C4 feed was 62.85%, which was theoretically higher than the rate of traditional organic fertilizer production methods, as judged by the 25 days required for fermentation duration [70,71,72,84,85]. The productivity of fermentation materials can provide data support for the productivity from raw materials to dry larvae and dung-sand.
Some researchers have shown that long-term feeding of excessive amounts of non-detoxified cotton by-products (e.g., cotton leaves, cottonseed meal, and cotton stalks) to vertebrates can lead to the accumulation of free gossypol (FG) in the fed animals, causing poisoning and acute respiratory distress, anorexia, fatigue, and even death [86,87,88]. This has hindered the application of cotton stalks as fodder. In this study, the contents of FG in cotton stalks, cattle manure, fermented cotton stalks, and A5B4C4 feed were 96, 114, 47, and 59 mg/kg. The decomposition of inoculant fermentation can significantly reduce the content of FG, which is consistent with the reduction of FG content in feed through fermentation in previous studies [89,90,91]. Interestingly, no FG was detected in the P. brevitarsis larvae after feeding on the A5B4C4 feed, indicating that the FG did not accumulate in the larvae, which may be related to the larvae-degrading FG through feeding and metabolism or the short feeding time. The specific reason is the direction of future research. The insect-microorganism composite systems can undoubtedly reduce the content of FG, and the study of its degradation mechanism may provide a reference for reducing the toxicity of FG in livestock feeding on cotton by-products. The protein and fat content of the larval body were 52.49% and 11.7%. It was a suitable-quality, high-protein, insect-derived feed ingredient [92,93], and the nutrient composition of the larvae of P. brevitarsis was consistent with previous studies [46,48,94]. In conclusion, it is feasible to transform cotton stalks to dry larvae feed.
Organic matter (OM) and total nutrients (TNPK) are the most commonly used indicators for evaluating organic fertilizer. This study showed that the OM and TNPK indicators of cotton stalks and manure met the Chinese organic fertilizer standards (NY525-2021, China), but they cannot be applied directly as organic fertilizers [95,96]. Therefore, the evaluation of whether the materials can be used as organic fertilizers should refer to other indicators, such as the germination index (GI), humic acids (HAs), the number of beneficial microorganisms, and so on [44,49,50,69]. Furthermore, the application effect on crops is the core criterion for evaluating the quality of an organic fertilizer [97,98,99]. The larvae dung-sand obtained in this study was much better than the Chinese organic fertilizer standard in terms of OM, TNPK, and other nutrition indicators. However, the high pH value and water-soluble chloride content may be the reason for the low GI of seeds. The quality of larvae dung-sand as organic fertilizer can be improved by adjusting pH and other measures. On the other hand, larvae dung-sand has the characteristics of regular particles and uniform texture, which is easy to process and use and can be processed into prototype flower fertilizer [31]. In cash crops, it can be applied by sowing while fertilizing or using leaching solution drip irrigation, which has the potential to be used as dung-sand-based organic fertilizer [44,54,69].

5. Conclusions

The optimum technical parameters for transforming cotton stalks using P. brevitarsis larvae were supplementation with 40–50% of cattle manure, the addition of 0.1% VT inoculant, and a fermentation duration of 25–30 days. The dry larvae are a high-protein feed ingredient from an insect-derived, which can be fed and recycled into the ecological breeding industry. The larvae dung-sand is rich in nutrition and has the potential for fertilizer application. This study preliminarily proves the feasibility of cotton stalk feeding and fertilizer dual-use technology based on the transformation of P. brevitarsis larvae. It possesses substantial significance for both theoretical and practical investigations related to boosting the recycling utilization of cotton stalks and cattle manure.

Author Contributions

Conceptualization, G.Z. and D.M.; methodology, Y.L.; validation, Y.X., S.Z. and A.X.; data curation, Z.M., H.G. and J.L.; writing—original draft preparation, G.Z.; writing—review and editing, D.M.; supervision, Y.L.; project administration, D.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Autonomous Region “Tianshan Innovation Team Plan” Project, grant number 2020D14036 and the Autonomous Region Agricultural Technology Extension and Service Project, grant number 2021-41.

Institutional Review Board Statement

Ethical review and approval were waived for this study due to environmentally friendly insect use.

Data Availability Statement

Raw data used in this study are available on request from the authors.

Acknowledgments

The authors are grateful to teachers Song Qiang and Ye-ling Wang from the University of Xinjiang Agricultural University for their care in life. Additionally, we thank the reviewers for helping us to improve our original manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

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Insects 13 01083 g001 550
Figure 1. Effect of the decomposition inoculant, cattle manure ratio, and fermentation duration on the feed intake (a), dung-sand weight (b), feed utilization rate (c), and dung-sand conversion rate (d) of the 3rd instar larvae of P. brevitarsis. Tukey’s multiple-range tests were used for the analysis. The same factor with a different letter indicated a significant difference (p < 0.05, n = 20).
Figure 1. Effect of the decomposition inoculant, cattle manure ratio, and fermentation duration on the feed intake (a), dung-sand weight (b), feed utilization rate (c), and dung-sand conversion rate (d) of the 3rd instar larvae of P. brevitarsis. Tukey’s multiple-range tests were used for the analysis. The same factor with a different letter indicated a significant difference (p < 0.05, n = 20).
Insects 13 01083 g001
Table
Table 1. Introduction and instructions for decomposition inoculants.
Table 1. Introduction and instructions for decomposition inoculants.
Decomposition InoculantsBrand and Production CompanyMain Functional BacteriaEffective Number of Viable Bacteria (100 million/g)Recommended Dosage (kg/t)
LKOrganic material decomposing inoculant, stalks type, Zhongnong Lvkang Biotechnology Co., Ltd., Beijing, ChinaBacillus, Trichoderma, and yeast80.5
LLOrganic fertilizer decomposing inoculant, Shandong Lvlong Biotechnology Co., Ltd., Zhucheng, ChinaBacillus subtilis, Bacillus licheniformis, yeast, and Trichoderma viride20010
NFK *Organic material decomposing inoculant, Henan NongFukang Biotechnology Co., Ltd., Zhengzhou, ChinaMainly Bacillus licheniformis, Candida utilis, Bacillus subtilis, Lactobacillus, and Enterococcus-like bacteria0.130
RWRW decomposing inoculant, stalks type, Hebi Renyuan Biological Co., Ltd., Hebi, ChinaBacteria (Bacillus subtilis, Bacillus licheniformis, and Bacillus jelly), filamentous fungi, and yeast10010
VTVT-1000, stalks type, Beijing VOTO Biotechnology Co., Ltd., Beijing, ChinaBacillus, actinomycetes, lactic acid bacteria, and molds2001
* Decomposition inoculants need to be activated in advance.
Table
Table 2. Orthogonal experimental factors and levels.
Table 2. Orthogonal experimental factors and levels.
LevelFactor
Decomposing Inoculants
(A)		Cattle Manure Ratio
(B/%)		Fermentation Duration (C/d)
1LK1010
2LL2015
3NFK3020
4RW4025
5VT5030
Table
Table 3. Transformation capability of the 3rd instar larvae of P. brevitarsis on CS under different fermentation durations.
Table 3. Transformation capability of the 3rd instar larvae of P. brevitarsis on CS under different fermentation durations.
Fermentation Duration (d)Feed Intake (g)Larvae Weight Gain (g)Dung-Sand Weight (g)Feed Utilization Rate (%)Dung-Sand Conversion Rate (%)Mortality (%)
048.50 ± 1.18a1.89 ± 0.09a19.16 ± 0.28d54.78 ± 1.33b41.17 ± 1.27d5.00 ± 2.89a
1037.68 ± 1.13c1.81 ± 0.10a28.32 ± 0.30c44.11 ± 1.32c79.17 ± 2.65ab2.50 ± 2.50a
1536.33 ± 0.44c1.82 ± 0.10a30.91 ± 0.31b45.14 ± 0.55c89.57 ± 0.63a0.00 ± 0.00a
2049.11 ± 0.64a2.04 ± 0.13a36.98 ± 0.60a62.83 ± 0.81a78.54 ± 0.48ab2.50 ± 2.50a
2549.24 ± 0.46a2.18 ± 0.10a35.24 ± 0.61a64.66 ± 0.60a74.86 ± 0.85c0.00 ± 0.00a
3041.58 ± 0.50b1.92 ± 0.04a32.30 ± 0.75b55.03 ± 0.67b81.45 ± 1.41b2.50 ± 2.50a
Data in the table are mean ± standard error (SE). Different letters in the same column indicate a significant difference (p < 0.05). The same is below.
Table
Table 4. Effect of the decomposition inoculant, cattle manure ratio, and fermentation duration on the fermentation temperature of the material pile.
Table 4. Effect of the decomposition inoculant, cattle manure ratio, and fermentation duration on the fermentation temperature of the material pile.
Factor and LevelTemperature (°C)
1 d5 d10 d15 d20 d25 d30 d
Decomposing inoculants (A)
LK41.80 ± 2.51a55.58 ± 3.78a48.50 ± 1.74a48.88 ± 1.31a47.72 ± 0.52a47.88 ± 1.35a43.30 ± 2.04a
LL41.04 ± 2.07a53.18 ± 2.75a48.20 ± 1.69a46.08 ± 1.64a47.86 ± 1.39a49.40 ± 1.79a43.60 ± 0.46a
NFK42.98 ± 2.74a52.68 ± 3.94a48.16 ± 1.92a48.94 ± 2.44a48.94 ± 1.85a49.24 ± 1.81a44.66 ± 1.32a
RW41.06 ± 1.89a50.24 ± 3.63a48.96 ± 2.32a46.46 ± 0.92a46.64 ± 2.11a47.26 ± 1.75a42.58 ± 1.40a
VT40.76 ± 1.22a54.82 ± 1.35a49.78 ± 2.43a48.78 ± 1.03a46.86 ± 1.34a48.52 ± 1.67a42.14 ± 2.86a
Cattle manure ratio (B/%)
1043.80 ± 2.13a58.34 ± 1.74a53.22 ± 1.70a50.36 ± 1.06a51.10 ± 1.35a50.30 ± 1.96a38.78 ± 2.00b
2040.86 ± 2.98a55.64 ± 2.89a49.50 ± 1.18ab47.76 ± 1.24a48.20 ± 0.22ab50.96 ± 1.48a45.20 ± 0.98a
3042.88 ± 1.18a50.70 ± 2.77a46.42 ± 1.71ab47.66 ± 1.13a47.24 ± 1.39ab46.76 ± 1.70a43.48 ± 1.71ab
4041.42 ± 1.80a53.98 ± 3.87a48.36 ± 1.95ab44.92 ± 2.30a45.08 ± 1.41b46.20 ± 1.07a42.98 ± 1.05ab
5038.68 ± 1.43a47.84 ± 2.38a46.10 ± 1.43b48.44 ± 1.14a46.40 ± 1.35ab48.08 ± 0.68a45.84 ± 0.78a
Fermentation duration (C/d)
1039.68 ± 1.69a51.14 ± 2.01a49.40 ± 2.21a46.30 ± 1.53a47.78 ± 0.35a48.22 ± 1.61ab43.74 ± 0.97a
1542.36 ± 2.23a52.26 ± 2.65a47.00 ± 1.60a47.98 ± 1.00a47.62 ± 0.70a45.14 ± 0.42b40.72 ± 1.47a
2041.74 ± 2.06a59.20 ± 1.40a48.92 ± 2.27a48.10 ± 2.36a48.64 ± 2.51a48.28 ± 2.01ab43.60 ± 1.77a
2540.48 ± 2.14a50.60 ± 3.50a48.88 ± 2.25a47.70 ± 1.61a46.88 ± 1.79a49.12 ± 0.75ab42.60 ± 2.58a
3043.38 ± 2.27a53.30 ± 4.41a49.40 ± 1.63a49.06 ± 1.35a47.10 ± 1.46a51.54 ± 1.53a45.62 ± 1.08a
CK48.5057.6052.9045.6040.1021.9017.30
Ambient temperature16.5015.5020.5018.5012.009.506.50
Table
Table 5. Effect of the decomposition inoculant, cattle manure ratio, and fermentation duration on the transformation capability of the 3rd instar larvae of P. brevitarsis.
Table 5. Effect of the decomposition inoculant, cattle manure ratio, and fermentation duration on the transformation capability of the 3rd instar larvae of P. brevitarsis.
Factor and LevelFeed Intake (g)Larvae Weight Gain (g)Dung-Sand
Weight (g)		Feed Utilization Rate (%)Dung-Sand Conversion Rate (%)Mortality (%)
Decomposing inoculants (A)
LK52.48 ± 2.16ab1.833 ± 0.043ab38.35 ± 1.95a72.99 ± 3.02a75.46 ± 1.37a0.50 ± 0.50a
LL54.32 ± 1.33ab1.928 ± 0.051ab40.34 ± 1.56a75.14 ± 2.57a76.78 ± 1.89a1.00 ± 0.69a
NFK54.33 ± 1.22ab1.886 ± 0.048ab40.99 ± 0.99a76.81 ± 1.78a78.19 ± 0.81a1.00 ± 0.69a
RW48.66 ± 1.69b1.753 ± 0.054b36.88 ± 1.57a69.85 ± 3.08a78.32 ± 1.07a1.50 ± 1.09a
VT55.53 ± 1.18a1.949 ± 0.051a40.81 ± 1.20a78.10 ± 1.81a76.06 ± 1.37a1.50 ± 0.82a
Cattle manure ratio (B/%)
1049.76 ± 1.50bc1.799 ± 0.060a33.58 ± 1.03c64.66 ± 2.39c70.33 ± 1.37c2.50 ± 1.23a
2047.43 ± 1.96c1.846 ± 0.058a34.43 ± 1.49c65.60 ± 2.43c75.53 ± 0.87b1.00 ± 0.69a
3053.89 ± 1.52ab1.895 ± 0.042a39.68 ± 0.95b77.80 ± 1.86b76.64 ± 1.15b1.00 ± 0.69a
4055.25 ± 0.61a1.905 ± 0.047a43.22 ± 0.79ab79.19 ± 0.63ab80.97 ± 0.90a0.50 ± 0.50a
5058.99 ± 0.71a1.904 ± 0.046a46.45 ± 0.71a85.64 ± 0.94a81.35 ± 0.63a0.50 ± 0.50a
Fermentation duration (C/d)
1046.34 ± 2.15c1.863 ± 0.068a34.60 ± 1.71b65.45 ± 3.73b77.62 ± 0.62a1.00 ± 1.00a
1551.54 ± 1.15b1.906 ± 0.040a36.77 ± 1.50b72.68 ± 2.13ab73.68 ± 1.68a1.00 ± 0.69a
2051.69 ± 1.20b1.821 ± 0.040a39.00 ± 1.23ab74.47 ± 2.18a78.16 ± 1.48a2.00 ± 0.92a
2557.05 ± 0.81a1.843 ± 0.047a43.46 ± 0.98a80.28 ± 1.28a78.58 ± 0.74a0.50 ± 0.50a
3058.70 ± 0.75a1.917 ± 0.056a43.53 ± 0.91a80.01 ± 1.12a76.78 ± 1.63a1.00 ± 0.69a
Table
Table 6. Tests of inter-subjects effects.
Table 6. Tests of inter-subjects effects.
SourceDependent VariableType III Sum of SquaresdfMean SquareFSig.
Corrected ModelFeed intake4186.996 a12348.91629.7580.000
Larval weight gain0.806 b120.0671.3530.204
Dung-sand weight3987.502 c12332.29257.9610.000
Feed utilization rate1.049 d120.08731.8560.000
Dung-sand conversion rate0.206 e120.0179.8150.000
Mortality0.009 f120.0010.6140.825
Decomposition inoculant (A)Feed intake581.0204145.25512.3880.000
Dung-sand weight256.548464.13711.1870.000
Feed utilization rate0.08540.0217.7600.000
Dung-sand conversion rate0.01340.0031.8480.127
Cattle manure ratio (B)Feed intake1940.2924485.07341.3710.000
Dung-sand weight1272.5514318.13855.4920.000
Feed utilization rate0.29840.07427.1400.000
Dung-sand conversion rate0.03140.0084.3680.003
Fermentation duration(C)Feed intake1665.6844416.42135.5160.000
Dung-sand weight2458.4034614.601107.2040.000
Feed utilization rate0.66640.16660.6660.000
Dung-sand conversion rate0.16340.04123.2300.000
ErrorFeed intake1020.0768711.725
Larval dry weight4.318870.050
Dung-sand weight498.772875.733
Feed utilization rate0.239870.003
Dung-sand conversion rate0.153870.002
Mortality0.109870.001
Corrected totalFeed intake5207.07299
Larval dry weight5.12499
Dung-sand weight4486.27499
Feed utilization rate1.28899
Dung-sand conversion rate0.35999
Mortality0.11899
a. R squared = 0.804 (adjusted R squared = 0.777); b. R squared = 0.157 (adjusted R squared = 0.041). c. R squared = 0.889 (adjusted R squared = 0.873); d. R squared = 0.815 (adjusted R squared = 0.789). e. R squared = 0.575 (adjusted R squared = 0.517); f. R squared = 0.078 (adjusted R squared = −0.049).
Table
Table 7. Transformation capability of the 3rd instar larvae of P. brevitarsis under the optimal combination.
Table 7. Transformation capability of the 3rd instar larvae of P. brevitarsis under the optimal combination.
TreatmentsFeed Intake (g)Larvae Weight Gain (g)Dung-Sand Weight (g)Feed Utilization Rate (%)Dung-Sand Conversion Rate (%)Mortality (%)
CK51.92 ± 0.372.030 ± 0.10240.48 ± 0.3964.90 ± 0.4681.13 ± 0.382.50 ± 2.50 *
A5B4C464.06 ± 0.52 *2.338 ± 0.04952.19 ± 0.60 *80.07 ± 0.65 *84.55 ± 0.53 *0.00 ± 0.00
Using independent sample T-test, * means significantly different (Tukey test, p < 0.05, n = 4).
Table
Table 8. Key nutritional indicators for raw materials, fermented materials, and dry larvae as feed ingredients.
Table 8. Key nutritional indicators for raw materials, fermented materials, and dry larvae as feed ingredients.
Material TypesWC (%)CP (%)Crude Fat (%)Crude Fiber (%)Crude Ash (%)Water-Soluble Chloride (%)FG (mg/kg)GE (KJ/g)
CS8.67.180.643.35.10.409616.57
Cattle manure79.214.160.627.417.61.2011414.74
Fermented CS69.710.190.343.29.60.754717.1
A5B4C4 feed71.213.180.334.715.91.605915.32
Dry larvae72.052.4911.76.115.61.00-19.2
Table
Table 9. Main nutritional indicators for raw materials, fermentation materials, and larvae dung-sand as organic fertilizer.
Table 9. Main nutritional indicators for raw materials, fermentation materials, and larvae dung-sand as organic fertilizer.
Material TypesWC (%)OM (%)HAs (%)TN (%)TP (%)TK (%)TNPK (%)pHWater-
Soluble Chloride (%)		GI (%)
CS8.667.01.061.290.992.354.636.60.4047.09
Manure79.258.91.592.31.292.185.778.91.2066.87
Fermented CS69.765.92.312.230.423.846.499.30.75102.88
A5B4C4 feed71.259.51.822.541.164.137.839.51.6098.73
CS-based larvae dung-sand65.661.31.382.680.874.558.19.40.9577.35
A5B4C4d feed-based larvae dung-sand68.754.80.812.931.674.449.049.21.6075.90
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Zhang, G.; Xu, Y.; Zhang, S.; Xu, A.; Meng, Z.; Ge, H.; Li, J.; Liu, Y.; Ma, D. Transformation Capability Optimization and Product Application Potential of Proteatia brevitarsis (Coleoptera: Cetoniidae) Larvae on Cotton Stalks. Insects 2022, 13, 1083. https://doi.org/10.3390/insects13121083

AMA Style

Zhang G, Xu Y, Zhang S, Xu A, Meng Z, Ge H, Li J, Liu Y, Ma D. Transformation Capability Optimization and Product Application Potential of Proteatia brevitarsis (Coleoptera: Cetoniidae) Larvae on Cotton Stalks. Insects. 2022; 13(12):1083. https://doi.org/10.3390/insects13121083

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Zhang, Guangjie, Yeshan Xu, Shuai Zhang, Andong Xu, Zhuo Meng, Hao Ge, Jing Li, Yusheng Liu, and Deying Ma. 2022. "Transformation Capability Optimization and Product Application Potential of Proteatia brevitarsis (Coleoptera: Cetoniidae) Larvae on Cotton Stalks" Insects 13, no. 12: 1083. https://doi.org/10.3390/insects13121083

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