key: cord-0043838-syciq6uw
authors: Szczepanik, Maryla; Raszkowska-Kaczor, Aneta; Olkiewicz, Daria; Bajer, Dagmara; Bajer, Krzysztof
title: Use of Starch Granules Enriched with Carvacrol for the Lesser Mealworm, Alphitobius diaperinus Control in Chicken House: Effects on Insects and Poultry
date: 2020-04-25
journal: J Poult Sci
DOI: 10.2141/jpsa.0190068
sha: a70021cd098674dcd42104fff8d8901adc52104f
doc_id: 43838
cord_uid: syciq6uw

The aim of this study was to investigate the effect of starch granules enriched with carvacrol and mixed with straw pellets (as poultry litter) on the mortality of larvae and adults of the lesser mealworm, Alphitobius diaperinus Panzer, a cosmopolitan pest inhabiting chicken houses in vast numbers worldwide. Additionally, the effect of starch granules on the growth parameters and survival of broiler chickens exposed to treated litter was examined. In this study, granules containing 3, 5, and 10% carvacrol was used. In a simulated chicken house bioassay, this material was mixed with pellets in three different proportions: 30/70%, 40/60%, and 50/50% (granules/pellets, respectively). On this medium, young larvae (approximately 10 days old), older larvae (last stage before pupa), and unsexed 7–10 days old adults of the lesser mealworm, with access to food, were colonized. Experiments were performed at 29°C in the dark. The study shows that poultry litter with the addition of starch granules enriched with 10% of carvacrol in the proportion of 40:60% (granules:pellets) appears to be the optimal medium applicable to broiler houses for A. diaperinus control. In this environment, all larvae and adults died within 3–4 days and the overall development of the experimental chickens was similar to that of the control. However, the feed conversion rate was slightly higher in the treated group (1.72) than in the control group (1.56). The average final body weight in the treated group was 100 g lower than that in the control group (the differences were not statistically significant).

Eliminating insects inhabiting chicken houses is still an unresolved problem in the poultry industry worldwide. A common insect in poultry farms is the lesser mealworm, Alphitobius diaperinus Panzer. This insect, because of its tropical origin, has fully adapted to conditions prevailing in poultry houses. It appears in large numbers in poultry litter and manure, especially under feeders and drinking troughs. This pest feeds primarily on spilled poultry feed or cracked eggs but eats sick and weakened or dead chickens as well (Axtell and Arends, 1990; Salin et al., 2000) . It is well known that this pest is a source and vector of several pathogens such as bacteria, viruses, fungi, protozoa, and platyhelminthes parasites that cause serious poultry and human diseases (Watson et al., 2000; Hazeleger et al., 2008; Roche et al., 2009 ). In addition, A. diaperinus destroys thermal insulation systems in poultry houses when mature larvae emigrate to search for isolated pupation sites (Vaughan et al., 1984) . Such a damage causes temperature drop inside buildings. Thus, its presence in poultry houses creates serious sanitary and economic problems for poultry farmers. The basic method for controlling the pest is by applying chemical insecticides such as pyrethroids, organophosphorus compounds, macrocyclic lactones, and benzylurea compounds, at the end of the poultry cycle. However, these methods are ineffective and do not provide long-term protection against the pest. Continuous usage of these insecticides results in the selection of resistant pest population and increased levels of the chemicals used in the environment. An increasing number of publications have described the resistance of pest to these compounds in several countries (Tomberlin et al., 2008; Chernaki-Leffer et al., 2011; Hickmann et al., 2018) . Thus, owing to environmental pollution caused by the excessive use and misuse of agrochemicals and the requirements of health food from consumers, alternative methods must be sought. This problem may solved by introducing proecological factors into chicken houses to ensure longterm protection against the pest as well as guaranteeing poultry safety. This can be achieved by using essential oils or their main components, especially terpenes. The toxic and behavioral effects of these natural products on the lesser mealworm has been well documented in literature (Szczepanik and Szumny, 2011; Prado et al., 2013; Szołyga et al., 2014; Testa et al., 2018) . The results of these studies show that essential oils or their components obtained from various plant species can be used to control A. diaperinus. The methods of their application in poultry houses can differ; they can be used as a feed additive in poultry nutrition, dietary antibiotic replacer, botanical insecticide, or additive to broiler litter material (Hippenstiel et al., 2011) . An appropriate polymer carrier containing components of essential oils can be easily mixed in a suitable proportion with the litter and remain in the broiler house throughout the entire poultry cycle. The role of such a carrier may be fulfilled using starch.

Starch consists of two fractions: amylose {(C6H10O5)n where n＝5000} and amylopectin {(C6H10O5)n, where n＝ 50 000}, in 20-25% and 75-80%, respectively (Raquez et al., 2008) . Pure starch is a white, semi-crystalline substance free of smell and taste (Kapuśniak et al., 2011; Bajer et al., 2012) . Its melting point range is 220-240℃ and its glass transition temperature is 230℃, higher than its decomposition point at 220℃. Therefore, processing starch in its pure form is difficult; starch must be subjected to plastification to lower its glass transition point, thus breaking the hydrogen bonds and partly decomposing the starch (Poutanen and Forssel, 1996) . Using an increased amount of plasticizer softens all types of starch and lowers the glass transition point (Yu et al., 1998; Mościcki et al., 2009; Bajer et al., 2011) . Starch of 10% humidity and glycerol content 20-35% shows a glass transition point (Tg) of up to 83-71℃ (Yu et al., 1998) . Van Soest and Knooren (1997) stated that starch of 11% humidity and glycerol content 26% shows Tg ＝40℃. The glass transition point of starch materials of considerable humidity and glycerol content is lower than 20℃ .

Glycerin, sorbitol, water, ethylene glycol, urea, formamide, and acetamide are among the most commonly used plasticizers (Poutanen and Forssel, 1996; Park et al., 2005; Spychaj et al., 2006; Galdeano et al., 2009; Bajer et al., 2011) . Water as a starch modifier limits the upper processing temperature by extruction blowing molding because of water vapor emission leading to porosity of the material (Thunwall et al., 2008) . Plasticizer causes an interaction between starch macromolecules that increases the elongation at break as well as impact strength, thus lowering the tensile strength (Rychter et al., 2016) .

Our previous studies have shown that carvacrol significantly impaired the growth and development of A. diaperinus larvae and is toxic to this pest (Szczepanik et al., 2012; Szczepanik et al., 2018) . Therefore, we hypothesize that this monoterpene phenol may be useful for reducing or eliminating insect infestations in poultry houses without toxicity to birds exposed to treated litter. The aim of this study was to investigate the effect of starch granules enriched with carvacrol and mixed with straw pellets as poultry litter on the mortality of larvae and adults of the lesser mealworm. Furthermore, the effect of these granules on the growth parameters and survival of broiler chickens exposed to treated litter was examined.

Native potato starch (Wielkopolska Potato Industry S. A. Luboń, Poland) was used in the study. The plasticizer used was propane-1,2,3-triol (Chempur, Piekary Śląskie, Poland) of density 1,26 g/cm 3 . Calcium carbonate (Chemical Processing Plant and Mineral Resources "Piotrowice," Poland) as the filler and carvacrol (Sigma Aldrich, Poznań, Poland) of density 0,976 g/cm 3 as a compound with insecticidal activity were used.

The biodegradable material with insecticidal properties was obtained as follows: 2% each of potato starch powder, propane-1,2,3-triol (28%), and calcium carbonate and carvacrol in the respective proportions were introduced into a planetary mixer. All ingredients were mixed using a stirrer at 60-120 rpm for 9±2 min (Bajer et al., 2017) .

The pellets were extruded using a single-screw extruder, Plasti-Corder PLV 151 (Brabender GmbH & Co., Germany). The screw had a working length 25D (outer diameter 19.5 mm) and a compression ratio 3:1. The temperature profile along the cylinder was as follows: 70, 80, 90, and 95℃ (die head). The screw rotation speed was 100 rpm. The obtained starch composite, in pellets form with average diameter 3-4 mm, is safe for the environment, as verified by the method described earlier ).

In this study, larvae and adults from a laboratory colony of the lesser mealworm were used. The insects were originally collected from a naturally infested poultry litter in a commercial chicken farm near Toruń (53°01′ N, 18°37′ E, Poland). The insects were stored in glass containers on a diet consisting of 1 part oat flakes, 1 part wheat bran, 0.01 parts brewers' yeast and apple halves to maintain the moisture levels at 60±5% relative humidity. Cotton was placed inside containers to provide a good pupation environment. The colony was kept in a rearing chamber at ＋29℃ in the dark. Szczepanik et al.: Carvacrol for Alphitobius diaperinus Control

The toxicity of the granules was evaluated in a laboratory. In these studies, granules containing 3 and 5% carvacrol were used. The granules (5 g) were placed in 100-mL plastic containers lined with moistened filter paper. Each container was filled with 10 young larvae (approximately 10 days old), 10 older larvae (last stage before pupa), and 10 unsexed, 7-10 days old adults (total insects＝30). In the control samples, pure starch granules were used. During the entire experimental period, water in filter paper and oat flakes as food were available. All containers were placed in incubators at 29℃ and 60±5% r.h. in the dark. The mortality of the insects was assessed daily and corrected by Abbott's formula (Abbott, 1925) . Four replicates were performed for each treatment.

The next stage of our research was the assessment of granule toxicity in conditions similar to the natural. In a chicken house, the granules can be mixed with poultry litter (pellets) in suitable proportions and placed over the entire area of the house. The research on the percentage composition and toxicity of such a mixture was performed in glass containers (20 cm×20 cm×15 cm length/width/depth) lined with moistened filter paper and filled with a mixture of granules and pellets. Granules containing 3, 5 and 10% of carvacrol was used. Granules with the addition 3% of carvacrol were used in a 50/50% ratio with pellets. Granules containing 5% of carvacrol were mixed with pellets in two proportions: 40/60% (granules/pellets, respectively) and 50/ 50%. Granules with a higher dose (10%) of carvacrol were used in three variants: 30/70; 40/60 and 50/50% (granules/ pellets, respectively). On this medium, 10 young larvae (approximately 10 days old), 10 older larvae (last stage before pupa) and 10 unsexed, 7-10 days old adults were colonized. All had access to food. The experiments were performed at ＋29℃ in the dark in 4-replicates for each treatment. Insect mortality was recorded each day and corrected by Abbott's formula (Abbott, 1925) . In the control samples pure starch granules mixed with pellets in appropriate proportions was used.

This study was performed at the Faculty of Animal Breeding and Biology at the University of Technology and Life Science in Bydgoszcz (Poland) as contracted research. It was performed in accordance with the Polish law concerning animal experiments. One-day-old male broiler chickens (Ross 308) were purchased from a local hatchery. They were placed in two 2.5 m 2 boxes and there were 33 broilers in each box. Continuous lighting was provided throughout the experimental period. The ambient temperature was decreased gradually from 32℃ on day 0 to 25℃ on day 21 and subsequently kept constant. All chickens underwent veterinary evaluation. The birds in the control group were kept on a commercial pellet bedding (15 kg in box); the treatment group was cultured on pellet litter mixed with granules containing 10% carvacrol (9 kg pellets and 6 kg granules).

This carvacrol dose was based on the results presented in Table 2 . During the study, the birds were reared in accordance with the instructions in the technical manual for rearing broiler chickens Ross 308 (www.aviagen.com). The chickens were fed ad libitum with commercial, isocaloric, and isotonic, full-compound feed mixtures: starter from 0 to 10 days; grower I from 11 to 21 days; grower II from 22 to 35 days; finisher from 36 to 42 days of growth period. They had unlimited access to water and remained under a veterinarian's care.

During the study, the following performance parameters of the experimental chickens were evaluated: body weight gain (individual body weights were measured weekly), feed intake, feed conversion, and mortality. The feed intake from 0-21 days and 0-42 days for both experimental groups was calculated by dividing the amount of feed consumed by the numbers of days and chickens. The obtained results were used to calculate the feed conversion ratio. The daily feed and water intake on the last day of the experiment was calculated by dividing the amount of feed and water consumed by the number of birds.

Data from the toxicity of starch granules enriched with carvacrol against A. diaperinus were statistically analyzed using a generalized linear mixed model with binomial distribution and logit link function (SPSS, IBM 25.0). Replicates were included as a random factor. The results were considered significant when P＜0.05. The student's t-test (Microsoft Office 2010, Excel) was used to compare the body weights of the experimental broilers.

The high toxicity of the granules against larvae and adults of A. diaperinus was indicated in the study. All insects, after being in contact with granules containing 5% carvacrol, died within 24 h. With the lower content (3%) of carvacrol in the granules, the rate of insect dieback was lower. After 24 h, 22.5% of younger larvae and only 10% of older larvae and adults were killed. The insect mortality increased over the next few days and became extremely high around the fifth or sixth day. For the larvae, mortality was approximately 90% and all adults died within four days after administration ( Table 1) .

The survival rate of the insects colonized on litter with the addition of granules containing carvacrol depended on the concentration of terpene in the granules and the amount of granules used in relation to the pellets. The litter containing granules with the lowest carvacrol content, 3%, had a limited effect. This environment was toxic only for the larvae, especially for younger ones; they died within six days. By contrast, the survival rate of the adults was high; during one week, only 20% of the insects died (Table 2) . Poultry litter mixed with granules containing 5% carvacrol was toxic only to larvae, especially in equal proportions; therefore, those granules were not highly effective. The total mortality of adults in both variants was at a similarly low level. This creates the risk of a relatively rapid restoration of the pest Journal of Poultry Science, 57 (2) population. The introduction of a smaller amount (30%) of granules to the litter, but with a higher content of carvacrol (10%) was effective only against younger larvae. After three days, only 20% of these larvae remained alive and during one week, all larvae died. However, this variant was not effective against older larvae and adults. The mortality of Szczepanik et older larvae after one week was only above 50%; for adults, it was approximately 20% (Table 2) . Increasing the amount of these granules in the litter to 40% resulted in a significant increase in toxicity of the substrate for all tested developmental stages of the pest. Three days after treatment, all younger larvae and adults died; mortality among the older larvae was 57.5%. After the next day, mortality among the older larvae increased to 100%. A comparison of the results shows that adding 40 and 50% of the granules into the litter, i.e., an addition exceeding 10%, does not increase the mortality among insects significantly. From a practical and economic perspective, poultry litter with the addition of starch granules with 10% carvacrol in ratio 40:60% (granules: pellets) appears to be the optimal medium applicable to broiler houses for A. diaperinus control.

Higher doses of essential oils as a pest control agent are required in broiler houses compared with synthetic insecticides. The low doses, at levels of 1-3%, used in natural conditions had no effect, especially against later developmental stages. This has been confirmed by other researchers. For example, Cunila angustifolia essential oil showed an efficacy of 100% for both larvae and adults when it was used at concentrations of 5 and 10% (Prado et al., 2013) . Similarly, 5% Cinnamomum zeylanicum essential oil used with pine shavings reduced infestation by Alphitobius diaperinus in poultry litter (Testa et al., 2018) . However, after applying a 5% dose, a second application of the oil was required in the middle of the chicken rearing cycle. It can be assumed that the use of granules containing 5% carvacrol in two applications can be equally effective. Meanwhile, a higher dose of carvacrol accelerates mortality at all life stages of the pest and prevents re-infestation.

The observed effect of carvacrol on the growth performance of male ROSS 308 chickens is non-significant. The growth, health, and survival recorded during the rearing of the broiler chickens depended primarily on the quality of the inserted hatchlings. The starting average body weight of the hatchlings was similar to the value of the indicator (42 g) contained in the "ROSS 308 Broiler Performance Objectives" (2014) (www.aviagen.com) and ranged from 42.9 g in the control to 42.7 g in the treatment group. During the first 3 weeks of chicken life, a high rate of body weight gain in both groups was observed (Table 3 ). The average body weight of these broilers was even higher than the standard of 959 g. In this period, only one broiler chicken from the control group died. From the third to the fifth week, the body weight of broiler chickens exposed to treated litter was higher compared to that of the control, but without significant statistical differences (Table 3 ). The high body weight gain of all chickens recorded between day 21 and 42 of rearing increased the density of chickens in the experimental boxes from 33 to 40 kg/m 2 . This could be a reason contributing to the increase in broiler chicken mortality. During this period, six broiler chickens in the carvacrol group died, while only three died in the control group (Table 3) . Carcasses of the dead birds were assessed by veterinary examination. Based on anatomopathological changes observed through bacteriological and parasitological tests of the intestinal mucosa, it was found that the cause of broiler chicken death was advanced colibacillosis, with symptoms of inflammation in the upper and lower respiratory tracts. Colibacillosis can be caused by poor environmental conditions (highly dusty chicken house, presence of ammonia in the environment, and overcrowding). However, considering the intense odor of carvacrol with a strong irritating effect emitted from litter, lack of dust, imperceptible odor of ammonia in the experimental room, and exceedance in bird body weight, determining the direct cause of colibacillosis of the respiratory tract of the chickens is difficult. However, it appears that the strong smell of carvacrol as the cause of broiler chicken death can be ruled out. In the first three weeks when the odor emission was the strongest, death was not observed among the carvacrol-treated birds. The observed increase in bird mortality in this period was likely the result of the onset of sudden cardiac death among experimental chickens that had an intense initial rate of weight gain and subsequently achieved a large, final body weight.

The rate of feed utilization by the broiler chickens is shown in Table 4 . From 0 to 21 days, the feed conversion ratio was almost the same for both groups. However, when determined for 42 days of poultry farming, the ratio increased from 1.54 (control) to 1.72 for the treated group. Meanwhile, the daily feed intake on the last day of rearing was almost the same for both groups. Thus, the effect of treated litter on feed utilization by chickens requires further detailed research.

Journal of Poultry Science, 57 (2) 172 The presented results show the high potential of starch granules enriched with carvacrol in controlling the lesser mealworm in poultry litter. The granules' high insecticidal activity and non-toxicity to poultry afford great possibilities for their practical application. The granules used in the study are cheap, easy to produce, environmentally friendly, easily biodegradable, and does not accumulate in the environment. It can be used, in contrast to synthetic insecticides, in a broiler house filled with birds. Furthermore, carvacrol has an anticoccidial action against Eimeria tenella and mixed Eimeria spp. infestation (Giannenas et al., 2003; Oviedo-Rondon et al., 2006) . The addition of terpenes to the litter for A. diaperinus control has been recommended by other researchers (Beier et al., 2014) .

The last stage of our research will be to conduct trials under field conditions in a broiler house. Additionally, it is necessary to evaluate the amount of carvacrol in the tissues of birds, especially in the muscle tissue and the liver. However, based on other studies, it can be assumed that these granules can be used successfully without the risk of accumulation in tissues. Bioactive terpenes are quickly absorbed after oral, pulmonary, or dermal administration, and most are metabolized and either eliminated by the kidneys in the form of glucuronides or exhaled as CO 2 . Hence, their accumulation in the body is unlikely owing to the rapid clearance and short half-lives (Brenes and Roura, 2010) . Essential oils or individual terpenes are widely recommended as a feed additive in poultry nutrition. Birds supplemented with the plant extracts showed higher body weight gain and increased feed consumption when compared with the other groups (Krishan and Narang, 2014) . Carvacrol contained in the granules, through antibacterial and antiviral activities, will enhance the sanitary conditions of the chicken house. The application of starch granules enriched with carvacrol in broiler house would reduce the use of chemical insecticides and enable the production of healthy food. 

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The authors declare no conflict of interest.