Swine diets: Impact of carbohydrate sources on manure characteristics and gas emissions.

Swine growers seeking to lower costs and environmental impact have turned to alternative carbohydrate feed sources. A feeding trial was conducted to determine the effect carbohydrate sources have on manure composition and gas emissions. A total of 48 gilts averaging 138 kg BW were fed diets consisting of (a) low fiber (LF) grain, or (b) high fiber (HF) aro-industrial co-product (AICP). The LF diets included corn and soybean meal (CSBM) and barley soybean meal (BSBM). The HF AICP diets were CSBM based and supplemented with one of the following materials: beet pulp; corn distillers dried grains with solubles; soybean hulls; or wheat bran. Diets were fed for 42 d with an average daily feed intake of 2.71 kg d-1. Feces and urine were collected twice daily and added to manure storage containers in which manure slurries were monitored for gas emissions and chemical properties. Manures of animals fed HF diets had significantly (P < 0.05) more excretion of solids, C, N, and organic N, but less total S compared to pigs fed the LF diets. Animals feed HF diets had significantly (P < 0.05) higher levels of ammonia, sulfide, volatile fatty acids, and phenols in manure compared to pigs fed the LF diets. Manure of animals fed HF diets had 30% (P < 0.05) lower NH3 and 17% lower hydrogen sulfide emissions; however, fiber had no impact on odor emissions. Based on the partitioning of nutrients, animals fed HF fiber diets had increased manure retention for C and N but decreased levels of N gas emissions and manure S. There were little differences in manure and gas emissions for animals fed LF diets, but the source of HF AICP diets had a significant impact on manure composition and gas emissions.

Swine diets impact manure characteristics and gas emissions: Part II protein source.

Soybean meal is the dominate protein source for swine diets in the world driven largely by economics, nutritive value, and availability; but conditions can change requiring growers to consider more economical and available protein alternatives. A feeding trial was conducted to determine the impact dietary protein source material on manure slurry chemical properties and manure gas emissions. A total of 32 gilts averaging 130 kg BW were fed either a control diet formulated with soybean meal (SB) or an alternative protein source that included corn gluten meal (CG); canola meal (CM); or poultry meal (PM), with all diets containing 176 g protein kg-1. Diets were fed for 45 d with an average daily feed intake of 2.68 kg/d. Feces and urine were collected twice daily after each feeding and added to animal-specific manure storage containers. At the end of the study, manure slurries were monitored for gas emissions and chemical properties. Dietary protein source had a significant effect (P < 0.05) on manure pH, total solids, total C, protein N, and total S. Pigs fed the diets containing CM had significantly higher levels of sulfide, butanoic acid, and branch chain fatty acids compared to pigs fed SB diets (P < 0.05). Pigs fed CM diets had significantly lower emissions of NH3 compared to pigs fed SB diets (P < 0.05). There were no significant differences in C or S emissions or in odorant emission as affected by source of dietary protein. Hydrogen sulfide was the most dominate odorants for all dietary treatments.

Swine diets impact manure characteristics and gas emissions: Part I protein level.

Crude protein (CP) is a key nutrient in swine diets supplying essential amino acids, N, and S to animals for growth are fed in excess to maximize growth. Swine diets reduced in CP and supplemented with crystalline amino acids have been shown effective at maintaining animal growth while increasing overall CP use efficiency. A feeding trial study was conducted to determine the effects of reduced dietary CP levels on manure slurry chemical properties and gas emissions. A total of 24 gilts averaging 111 kg BW were fed corn and soybean meal diets formulated with 8.7, 14.8, and 17.6% CP using crystalline amino acid supplementation in the 8.7 and 14.8% CP diets, but only intact protein, soybean meal, in the diet containing 17.6% CP. Diets were fed for 45 d with an average daily feed intake (ADFI) of 2.70 kg across all diets. Animals were fed twice daily with both feces and urine collected during each feeding and added to animal-specific manure storage containers. At the end of the study, manure slurries were monitored for gas emissions and chemical properties. Increasing dietary CP levels increased manure pH, total solids, total N, and total S, including increased levels of ammonia (NH3), volatile fatty acids, and phenolic compounds. Pigs fed lower CP diets had lower emissions of NH3, branched chain fatty acids (BCFA), and phenol compounds which translated into lower emissions in total odor. Emissions of NH3 and odor were reduced by 8.9% and 4.2%, respectively, for each unit percent decline in dietary CP. Hydrogen sulfide was the dominate odorant associated with manure odor emissions. Based on nutrient mass balance, animal retention of dietary N and S increased by 7.0% and 2.4%, respectively, for each unit percent drop in crude protein fed animals, while C retention in the animal declined by 2.1%.

Impact of fiber source and feed particle size on swine manure properties related to spontaneous foam formation during anaerobic decomposition.

Foam accumulation in deep-pit manure storage facilities is of concern for swine producers because of the logistical and safety-related problems it creates. A feeding trial was performed to evaluate the impact of feed grind size, fiber source, and manure inoculation on foaming characteristics. Animals were fed: (1) C-SBM (corn-soybean meal): (2) C-DDGS (corn-dried distiller grains with solubles); and (3) C-Soybean Hull (corn-soybean meal with soybean hulls) with each diet ground to either fine (374 µm) or coarse (631 µm) particle size. Two sets of 24 pigs were fed and their manure collected. Factors that decreased feed digestibility (larger grind size and increased fiber content) resulted in increased solids loading to the manure, greater foaming characteristics, more particles in the critical particle size range (2-25 µm), and a greater biological activity/potential.

Lab-assay for estimating methane emissions from deep-pit swine manure storages.

Methane emission is an important tool in the evaluation of manure management systems due to the potential impact it has on global climate change. Field procedures used for estimating methane emission rates require expensive equipment, are time consuming, and highly variable between farms. The purpose of this paper is to report a simple laboratory procedure for estimating methane emission from stored manure. The test developed was termed a methane production rate (MPR) assay as it provides a short-term biogas production measurement. The MPR assay incubation time is short (3d), requires no sample preparation in terms of inoculation or dilution of manure, is incubated at room temperature, and the manure is kept stationary. These conditions allow for high throughput of samples and were chosen to replicate the conditions within deep-pit manure storages. In brief, an unaltered aliquot of manure was incubated at room temperature for a three-days to assay the current rate of methane being generated by the manure. The results from this assay predict an average methane emission factor of 12.2 ± 8.1 kg CH4 head(-1) yr(-1) per year, or about 5.5 ± 3.7 kg CH4 per finished animal, both of which compare well to literature values of 5.5 ± 1.1 kg CH4 per finished pig for deep-pit systems (Liu et al., 2013). The average methane flux across all sites and months was estimated to be 22 ± 17 mg CH4 m(-2)-min(-1), which is within literature values for deep-pit systems ranging from 0.24 to 63 mg CH4 m(-2)-min(-1) (Park et al., 2006) and similar to the 15 mg CH4 m(-2)-min(-1) estimated by (Zahn et al., 2001).

The effects of colony structure and resource abundance on food dispersal in Tapinoma sessile (Hymenoptera: Formicidae).

The odorous house ant, Tapinoma sessile (Say) (Hymenoptera: Formicidae), exhibits a high degree of variation in colony spatial structure, which may have direct and indirect effects on foraging. Protein marking and mark-release-recapture techniques were utilized to examine the effect of colony spatial structure on food dispersal. Sucrose water spiked with rabbit IgG protein was presented to colonies with varying spatial configurations in laboratory and field experiments. In monodomous laboratory colonies, the rate and extent of food dispersal was rapid due to a decrease in foraging area. In polydomous colonies, food dispersal was slower because conspecifics were forced to forage and share food over longer distances. However, over time, food was present in all extremities of the colony. Experiments conducted in the field produced similar results, with nests in close proximity to food yielding higher percentages of workers scoring positive for the marker. However, the percentage of workers possessing the marker decreased over time. Results from this study provide experimental data on mechanisms of food dispersal in monodomous and polydomous colonies of ants and may be important for increasing the efficacy of management strategies against T. sessile and other pest ant species.

The effect of genetic polymorphism of cytochrome P450 CYP2C9 on phenytoin dose requirement.

The cytochrome P450 enzyme CYP2C9 catalyses the metabolism of numerous therapeutic agents, including the anti-epileptic drug phenytoin. CYP2C9 is genetically polymorphic: two allelic variants are known, CYP2C9*2 and CYP2C9*3, differing from the wild-type CYP2C9*1 by a single point mutation. Both mutant alleles are associated with markedly impaired metabolic capacity for many CYP2C9 substrates compared to the wild-type, resulting in raised serum drug levels upon a given dose. Because this may be relevant in treatment with phenytoin, we studied the effect of CYP2C9 genotype on phenytoin dose requirement in a group of 60 epileptic patients on long-term phenytoin therapy. CYP2C9 genotyping was performed by polymerase chain reaction analysis, phenytoin serum concentrations were measured by high-performance liquid chromatography analysis and related to the maintenance doses. For patients carrying at least one mutant CYP2C9 allele (n = 17), the mean phenytoin dose required to achieve a therapeutic serum concentration was about 37% lower than the mean dose required by wild-type individuals (199 mg/day versus 314 mg/day; P < 0.01). A low maintenance dose (< 200 mg/day) sufficed for 47% of carriers, while 58% of normals required a high dose (> 300 mg/day) for an effective serum level. The results show that there is a strong association between CYP2C9 allelic variants and phenytoin dose requirement. Since phenytoin has a narrow therapeutic index and genotyping may be carried out rapidly and at low cost, dosage adjustment based on CYP2C9 genotype, especially at the induction of therapy, would be of value in order to lower the risk of concentration dependent drug intoxications in carriers.

[Maintenance dose requirement for phenytoin is lowered in genetically impaired drug metabolism independent of concommitant use of other antiepileptics]. / Benodigde dagdosis fenytoïne verlaagd bij genetisch bepaald traag geneesmiddelmetabolisme en onbeïnvloed bij gelijktijdig gebruik van andere anti-epileptica.

OBJECTIVE: To investigate the effect of genetically determined impaired drug metabolism and of the use of comedication on phenytoin maintenance dose requirement. DESIGN: Descriptive. METHOD: In 60 patients on long-term phenytoin therapy the concentration of phenytoin in serum was measured and CYP2C9 genotyping was performed (mutant alleles of CYP2C9 are associated with impaired phenytoin metabolism). In addition, the use of other antiepileptics concurrently with phenytoin was reviewed: phenobarbital, carbamazepine and valproic acid. CYP2C9 genotype and comedication were connected to phenytoin daily dose requirement. The 60 patients were 38 men and 22 women, between 16 and 74 years of age, and all mentally disabled. RESULTS: Genotyping revealed that of the 60 patients 38% (n = 23) carried at least one mutant CYP2C9 allele. Their mean dose of phenytoin was 199 mg dd, while the mean required maintenance dose in non-carriers (n = 37) was 287 mg dd (p < 0.01). When the use of comedication was taken into account, it appeared that the mean phenytoin daily doses in the different comedication groups did not differ significantly. CONCLUSION: Patients with a genetically determined impaired phenytoin metabolism required on average a 30% lower dose than those with a normal metabolism, while the concomitant use of other antiepileptics appeared to have no effect on phenytoin dose requirement.