| Algae for conversion of manure nutrients to animal feed: Evaluation of advanced nutritional value, toxicity, and zoonotic pathogens | 1000956 | Murinda, Shelton | 09/01/2013 | 08/31/2017 | COMPLETE | Pomona | Algae, Animal Feed, Bacteria, Manure, Nutritional Value, Pathogens, Toxic Cyanobacteria | Rationale The need to control manure-derived nutrient pollution is straining the confined animal production industry. California is the top milk producing state and has some of the strictest nutrient regulations. But in the San Joaquin Valley, many dairies do not have affordable access to more land for manure application. A highly productive crop is needed that will convert manure nitrogen (N) and phosphate (P) into feed but in smaller land areas than crops such as corn. Algae are a candidate feed with annual yields typically 7-13 times greater than soy or corn. Beyond 40-50% protein, algae also contain fatty acids, amino acids, pigments, and vitamins that are valuable in animal feeds, especially for adding value to milk. Advances in molecular biology allow us to gather needed information on the risks and benefits of algae-based animal feeds. Overall goal Benefit animal agriculture and the environment by introducing microalgae as a fast-growing livestock feed crop. Aim 1 Cultivate algae in dairy freestall barn flush water, treating this wastewater, while producing algae feedstock at a high annual rate, at least 10-times greater than corn. Algae will be cultivated in 30-cm deep raceway ponds at the 300-head Cal Poly campus dairy farm where extensive manure management research already occurs under USDA and USEPA sponsorship. Aim 2 Produce algae with favorable nutritional characteristics (high digestibility, valuable fatty and amino acid profiles, balanced protein and carbohydrate concentration, etc.) by adjusting the treated-water recycling into the ponds to optimize the N concentration in the growth medium. Aim 3 Test pathogen survival in algae feeds prepared by pasteurization and/or drying and heating. A trend in municipal wastewater treatment is pasteurization of treated effluent using waste heat from natural gas electrical generator. Large dairies with digesters will have waste heat available for pasteurization and drying. High-protein algae will be pelletized with high carbohydrate feeds to create a balanced feed. The heat of pelletization also contributes to pasteurization. Cal Poly has a research feed mill for producing such blended feeds. Aim 4 Monitor contamination by cyanobacteria and any cyanobacterial toxins. Approach Removal of N, P, and other constituents will be optimized in influent and effluent of identical ponds. Algal biomass (harvested by bioflocculation+settling) will be analyzed for N, P, protein, carbohydrates, and profiles of fatty and amino acids. Pathogen and algal communities extant in raw and feed-processed algal biomass will be analyzed using metagenomics and pyrosequencing. Potential toxicity of algal biomass will be studied using toxicity evaluation of cell-free extracts on cultured mammalian cells. A TC 20 Cell counter (BioRad Laboratories) will be used to monitor toxicity events on treated cells using trypan blue staining. Cytotoxic positive samples will be tested for both presence and concentration of known cyanobacterial toxins. The researchers have decades' experience in algae production, wastewater treatment, and food safety. Expected outcomes Starting with dairy, the project will lead the way towards an algae feed industry based on advanced nutritional features to enhance agricultural products (e.g., milk protein, poultry pigment) while assisting farmers to meet manure management challenges. We will address topics rarely covered in the algae field: potential toxicity and zoonotic pathogens. Our approach is unique in that it integrates and addresses a triad of issues, namely, food safety issues along with algae production techniques and waste management. | Project Goals 1. Generate experimental field data and calibrate optimization models. For treatment, expected removals are 85-95% biochemical oxygen demand and soluble Nitrogen (N) and 40-80% solublePhosphate (P) removal, depending on culturing technique and season. 2. Maximize the nutritional value of produced algae for animal feed. The cultures will be optimized to produce biomass at a high rate while also having the highest value composition for feed (in terms of lipids, digestibility, essential fatty and amino acid profiles, including balanced protein and carbohydrate concentrations). 3. Optimize pathogen inactivation methods. Pathogens will die-off in the ponds and during disinfection processing of the harvested biomass. Inactivation rates for representative pathogen indicators will be determined under various algae cultivation conditions and during trials with several biomass disinfection techniques. The optimal combination of pond conditions (e.g., high pH) and biomass processing (e.g., pasteurization) will be determined to achieve needed log inactivation of pathogens, which is typically 1- >4 log10 reduction (Sobsey et al., Available Online). 4. Quantify and control any cyanobacterial toxins. qPCR assays described by Al-Tarineh et al. (2012 a and b) will be used and optimized to reliably determine the copy number of cyanotoxin biosynthesis genes, as well as an internal cyanobacteria 16S rDNA control, in a single reaction. The latter detects for presence of cyanobacteria. If toxins are detected, measures will be taken to control invasion of the ponds by cyanotoxin-producing cyanobacteria strains. Overall Goal Benefit agriculture and the environment by introducing microalgae, a fast-growing livestock feed crop. |
| Integration of Site-Specific Crop Production Practices and Industrial and Animal Agricultural Byproducts to Improve Agricultural Competitiveness and Sustainability | 0425032 | JENKINS J N | 10/01/2013 | 09/30/2018 | ACTIVE | MISSISSIPPI STATE | PRECISION, FARMING, GEOGRAPHIC, INFORMATION, SYSTEM, (GIS), REMOTE, SENSING, (RS), WATER, SWINE, ANIMAL, WASTE, AMMONIA, SOIL, NUTRIENTS, PATHOGEN, NITROGEN, LITTER, LEACHING, CROPS, RUNOFF, BACTERIA, BROILER | Not applicable | Obj 1. Develop ecological and sustainable site-specific agriculture systems, for cotton, corn, wheat, and soybean rotations. 1: Geographical coordinates constitutes necessary and sufficient cornerstone required to define, develop and implement ecological/sustainable agricultural systems. 2: Develop methods of variable-rate manure application based on soil organic matter (SOM), apparent electrical conductivity, elevation, or crop yield maps. 3: Relate SOM, electrical conductivity, and elevation. Obj 2. Develop sustainable and scalable practices for site-specific integration of animal agriculture byproducts to improve food, feed, fiber, and feedstock production systems. 1: Quantify effects of management on sustainability for sweet potato. 2: Balance soil phosphorus (P)/micro¿nutrients using broiler litter/flue gas desulfurization (FGD) gypsum. 3: Effects of site-specific broiler litter applications. 4: Manure application/crop management practices in southern U.S. 5: Compare banded/broadcast litter applications in corn. 6: Develop reflectance algorithms for potassium in wheat. 7: Determine swine mortality compost value in small farm vegetable production. Obj 3. Analyze the economics of production practices for site-specific integration of animal agriculture byproducts to identify practices that are economically sustainable, scalable, and that increase competitiveness and profitability of production systems. 1: Evaluate economics of on-farm resource utilization in the south. Obj 4. Determine the environmental effects in soil, water, and air from site-specific integration of animal agricultural and industrial byproducts into production practices to estimate risks and benefits from byproduct nutrients, microbes, and management practices. 1: Quantitatively determine bioaerosol transport. 2: Role of P and nitrogen (N) immobilizing agents in corn production. 3: Assess impact of management on water sources. 4: Impact of FGD gypsum/rainfall on mobilization of organic carbon/veterinary pharmaceutical compounds in runoff/leached water. 5: Assess soil microbial ecology, antibiotic resistance, and pathogen changes using manure and industrial byproducts in crop production systems. 6: Develop nutrient management practices for sustainable crop production. 7: Develop nutrient management practices for reclaimed coal mine soils. 8: Determine effects of poultry litter/swine lagoon effluent in swine mortality composts. 9: Determine survival of fecal bacterial pathogens on contaminated plant tissue. 10: Identify agricultural/industrial byproducts that modify the breakdown of organic matter. Obj 5. Integrate research data into regional and national databases and statistical models to improve competitiveness and sustainability of farming practices. 1: Develop broiler house emission models. 2: Apply quantitative microbial risk assessment models to animal agriculture/anthropogenic activities. Obj 6. Develop statistical approaches to integrate and analyze large and diverse spatial and temporal geo-referenced data sets derived from crop production systems that include ecological and natural resource based inputs. 1: Develop novel methods of imaging processing. |