Evaluating Commodity Farm Program Selection and Economic Return Variability on Representative Farms in the Mississippi River Delta Region Using a Risk Return Framework

The Agricultural Act of 2014, signed February 7, 2014, introduces a new era of federal support in the production of major agricultural commodities in the United States for the 2014 through 2018 crop years. The ultimate result of the Act was a 954-page piece of legislation that represented market-oriented policies such as the creation of an area-wide shallow loss revenue support program for covered commodities and a greater reliance on crop insurance products offered as a suite of risk management tools available to producers. The impact that this law has on agricultural producers in the Mississippi River delta region of the Mid-south is not yet fully known. Moving forward, the elimination of the direct payment program is likely to have an impact on farm income, as these payments were made annually and were decoupled from actual market prices. Various combinations of federal farm programs, chosen irrevocable, paired with multiple crop insurance products, that are purchased annually, will act to mitigate the risks of production. Simulation analysis provides a basis for evaluating the variability associated with production systems in the Mississippi River delta region. Three representative rice and soybean farms and six corn, cotton, and soybean farms were modeled as to determine the five year net returns resulting from price and yield risk as well as to evaluate alternative farm program and crop insurance selection. Financial performance of these farms is measured for varying levels of risk using a stochastic efficiency criteria. Results are presented for multiple combinations of the agriculture risk coverage and price loss coverage programs of the commodity title and revenue protection, supplemental coverage option endorsement, and the stacked income protection plan for producers of upland cotton contained in crop insurance title of the current farm law. For each farm at each location, an estimate to the net present value of the cumulative net returns above variable costs to the producer for the five year life of the farm bill is provided. Results from different farming operations suggest the preferred pairing of farm programs and crop insurance policies does vary across locale and crops

Robotics and Inquiry: Addressing the Impact on Student Understanding of Physics Concepts (Force and Motion) from Select Rural Louisiana Elementary Students through Robotics Instruction Immersed within the 5E Learning Cycle Model

This embedded mixed methods study investigates the development of rural elementary students’ conceptual understanding of force and motion as a result of the implementation of robotics instruction immersed within a 5E Learning Cycle Model lessons. Three treatment groups and one controlled comparison group (n=96) participated in pretests and posttests (Science Series Assessment 1, Russell and McGuigan, 2001) the day the activities were completed as well as one week after the completion of the treatment, 5E Learning Cycle Model lessons and draw and tell interviews. Prior to the intervention, the Iowa Test of Basic Skills stanine scores were grouped into three levels: high, medium and low, and provided a sample size of 36, three from each ability level from each experimental and control groups. These participants were pulled three at a time and participated individually in the draw and tell activity before the intervention, during and one week following the close of the intervention. Observations, field notes, coded interviews and quantitative data were used for meta-inference. The data suggests that with respect to long term retention of accurate understanding of concepts related to force and motion, participants who utilize robotics instruction immersed within 5E Learning Cycle Model lessons are more likely to successfully retain correct concepts of force and motion (p\u3e.05). According to the findings from this study, participants who did not utilize robotics instruction were less likely to have accurate long term retention of concepts related to force and motion and were more likely to return to their original misunderstandings of said topic. With regards to ability level, low ability participants who utilized the robotics component were more likely to retain knowledge on topics related to force and motion; whereas only one participant in the control group identified as low ability could do the same. This study addresses a gap in the literature by providing the quantitative and qualitative data that supports the importance of immersing robotics into 5E Learning Cycle Model lessons as a means to assist students of various ability levels in addressing their understandings of physics concepts

Review of anthraquinone applications for pest management and agricultural crop protection

We have reviewed published anthraquinone applications for international pest management and agricultural crop protection from 1943 to 2016. Anthraquinone (AQ) is commonly found in dyes, pigments and many plants and organisms. Avian repellent research with AQ began in the 1940s. In the context of pest management, AQ is currently used as a chemical repellent, perch deterrent, insecticide and feeding deterrent in many wild birds, and in some mammals, insects and fishes. Criteria for evaluation of effective chemical repellents include efficacy, potential for wildlife hazards, phytotoxicity and environmental persistence. As a biopesticide, AQ often meets these criteria of efficacy for the non-lethal management of agricultural depredation caused by wildlife. We summarize published applications of AQ for the protection of newly planted and maturing crops from pest birds. Conventional applications of AQ-based repellents include preplant seed treatments [e.g. corn (Zea mays L.), rice (Oryza sativa L.), sunflower (Helianthus annuus L.), wheat (Triticum spp.), millet (Panicum spp.), sorghum (Sorghumbicolor L.), pelletized feed and forest tree species] and foliar applications for rice, sunflower, lettuce (Lactuca sativa L.), turf, sugar beets (Beta vulgaris L.), soybean (Glycine max L.), sweet corn and nursery, fruit and nut crops. In addition to agricultural repellent applications, AQ has also been used to treat toxicants for the protection of non-target birds. Few studies have demonstrated AQ repellency in mammals, including wild boar (Sus scrofa, L.), thirteen-lined ground squirrels (Ictidomys tridecemlineatus,Mitchill), black-tailed prairie dogs (Cyomys ludovicainus, Ord.), common voles (Microtus arvalis, Pallas), housemice (Musmusculus, L.), Tristram’s jirds (Meriones tristrami, Thomas) and black rats (Rattus rattus L.). Natural sources of AQ and its derivatives have also been identified as insecticides and insect repellents. As a natural or synthetic biopesticide, AQ is a promising candidate for many contexts of non-lethal and insecticidal pest management

Optimization of human, animal, and environmental health by using the One Health approach

Emerging diseases are increasing burdens on public health, negatively affecting the world economy, causing extinction of species, and disrupting ecological integrity. One Health recognizes that human, domestic animal, and wildlife health are interconnected within ecosystem health and provides a framework for the development of multidisciplinary solutions to global health challenges. To date, most health-promoting interventions have focused largely on single-sector outcomes. For example, risk for transmission of zoonotic pathogens from bush-meat hunting is primarily focused on human hygiene and personal protection. However, bush-meat hunting is a complex issue promoting the need for holistic strategies to reduce transmission of zoonotic disease while addressing food security and wildlife conservation issues. Temporal and spatial separation of humans and wildlife, risk communication, and other preventative strategies should allow wildlife and humans to co-exist. Upstream surveillance, vaccination, and other tools to prevent pathogen spillover are also needed. Clear multi-sector outcomes should be defined, and a systems-based approach is needed to develop interventions that reduce risks and balance the needs of humans, wildlife, and the environment. The ultimate goal is long-term action to reduce forces driving emerging diseases and provide interdisciplinary scientific approaches to management of risks, thereby achieving optimal outcomes for human, animal, and environmental health

Optimization of human, animal, and environmental health by using the One Health approach

Emerging diseases are increasing burdens on public health, negatively affecting the world economy, causing extinction of species, and disrupting ecological integrity. One Health recognizes that human, domestic animal, and wildlife health are interconnected within ecosystem health and provides a framework for the development of multidisciplinary solutions to global health challenges. To date, most health-promoting interventions have focused largely on single-sector outcomes. For example, risk for transmission of zoonotic pathogens from bush-meat hunting is primarily focused on human hygiene and personal protection. However, bush-meat hunting is a complex issue promoting the need for holistic strategies to reduce transmission of zoonotic disease while addressing food security and wildlife conservation issues. Temporal and spatial separation of humans and wildlife, risk communication, and other preventative strategies should allow wildlife and humans to co-exist. Upstream surveillance, vaccination, and other tools to prevent pathogen spillover are also needed. Clear multi-sector outcomes should be defined, and a systems-based approach is needed to develop interventions that reduce risks and balance the needs of humans, wildlife, and the environment. The ultimate goal is long-term action to reduce forces driving emerging diseases and provide interdisciplinary scientific approaches to management of risks, thereby achieving optimal outcomes for human, animal, and environmental health

Influence of extender, freezing rate, and thawing rate on post-thaw motility, viability and morphology of coyote (Canis latrans) spermatozoa

Abstract The objective of this study was to examine the post-thaw effects of three cryoprotective extenders (Tris-fructose-citric acid extender, Tris-glucose-citric acid extender, and lactose extender), three linear freezing rates (À1, À6, and À20 8C/min), and three thawing rates (37 8C water bath for 120 s, 60 8C water bath for 30 s, and 70 8C water bath for 8 s) on coyote spermatozoa. After thawing, the findings supported that cryopreservation of coyote (Canis latrans) spermatozoa frozen at a moderate freezing rate (À6 8C/min), in either a Tris-fructose or Tris-glucose extender, and thawed at a slow rate (37 8C water bath for 120 s) or moderate rate (60 8C water bath for 30 s), resulted in a more vigorous post-thaw motility (range, 57.5-44.0%) and viability (range, 64-49.6%) with the least amount of morphological and acrosomal abnormalities.

Determination of Cabergoline by Electrospray Ionization Tandem Mass Spectrometry: Picogram Detection via Column Focusing Sample Introduction

An electrospray ionization tandem mass spectrometric method was developed for low-picogram detection of an ergot alkaloid, cabergoline, in coyote plasma extracts. Cabergoline is under investigation as an abortifacient in canid species. Central to the successful development of this method was the ability to introduce relatively large sample volumes into the mass spectrometer. This was achieved by focusing the analyte on a conventional high-performance liquid chromatography guard column prior to elution into the spectrometer. Volumes up to at least 900 μL could be injected onto the guard column using a 100% aqueous mobile phase. Cabergoline retained on the column was eluted as a discreet band into the mass spectrometer by the rapid addition of methanol (30%) to the mobile phase. As compared to flow injection sample introduction, the ability to inject larger sample volumes led to a greatly lowered detection limit. Using this technique and a modification of a previously reported extraction procedure, cabergoline could be determined in coyote plasma at concentrations as low as 9 pg of cabergoline/ mL of plasma

Determination of Cabergoline by Electrospray Ionization Tandem Mass Spectrometry: Picogram Detection via Column Focusing Sample Introduction

An electrospray ionization tandem mass spectrometric method was developed for low-picogram detection of an ergot alkaloid, cabergoline, in coyote plasma extracts. Cabergoline is under investigation as an abortifacient in canid species. Central to the successful development of this method was the ability to introduce relatively large sample volumes into the mass spectrometer. This was achieved by focusing the analyte on a conventional high-performance liquid chromatography guard column prior to elution into the spectrometer. Volumes up to at least 900 μL could be injected onto the guard column using a 100% aqueous mobile phase. Cabergoline retained on the column was eluted as a discreet band into the mass spectrometer by the rapid addition of methanol (30%) to the mobile phase. As compared to flow injection sample introduction, the ability to inject larger sample volumes led to a greatly lowered detection limit. Using this technique and a modification of a previously reported extraction procedure, cabergoline could be determined in coyote plasma at concentrations as low as 9 pg of cabergoline/ mL of plasma

Assessment of cabergoline as a reproductive inhibitor in coyotes (\u3ci\u3eCanis latrans\u3c/i\u3e)

The efficacy of three oral formulations (gelatin capsule, tablet, oil base) and five dosages (50, 100, 250, 500, 1000 μg) of cabergoline to disrupt reproduction in coyotes (Canis latrans) was evaluated. The type of formulation used had no effect on plasma progesterone and prolactin concentrations or on mean litter size. No adverse side effects (for example, vomiting, anorexia, diarrhea) were observed despite the use of doses of up to 20 times the therapeutic dose used for domestic dogs and cats. All coyotes treated with 50, 100, 250 and 500 μg cabergoline whelped, but plasma progesterone concentrations in these coyotes were lower (P ≤ 0.07) than in control animals at day 7 after treatment. Ten of 11 females treated with 1000 yg cabergoline whelped, but progesterone concentrations in these coyotes were lower than in control animals up to day 14 after treatment ( P ≤ 0.04). Dosages of 1 000 μg cabergoline decreased blood serum prolactin (P ≤ 0.1 0) and progesterone (P ≤ 0.06) concentrations, but apparently failed to decrease progesterone below the threshold necessary to maintain pregnancy in all but one animal. However, progressive inhibition of prolactin and progesterone with increasing doses of cabergoline indicated that higher dosages might be effective in coyotes. Survival of pups born to cabergoline-treated females was not different (P \u3c 0.001) from that of pups born to control females, but mean litter size was smaller for females treated with cabergoline (P ≤ 0.073) than for the control females. Although all cabergoline treatments in this study were ineffective at preventing reproduction in coyotes, progressive inhibition of prolactin and progesterone with increasing dosages of cabergoline indicates that higher doses might be effective in preventing reproduction in coyotes. However, the physiological differences from other canine species in dopamine D2 receptors and mechanisms of luteal support may ultimately prevent the use of cabergoline for reproductive control in coyotes

Disease Risks Associated with Increasing Feral Swine Numbers and Distribution in the United States

Feral hogs or “wild boars” come from several sources and include released or escaped domestic swine and the truly wild European boar. When free-roaming in North America, all are included in the term “feral swine,” as are hybrids of the two types. Although morphologically distinct, both the feral swine and European wild swine are recognized as Sus scrofa. The physical damage caused by feral swine has been well documented and includes damage to vehicles, vineyards, tree plantings, archaeological sites, agricultural crops, turf, soils, rare plant communities, and wildlife habitat (Seward et al. 2004). In addition they compete with livestock and native wildlife for food resources; prey on domestic animals and wildlife; and carry diseases that affect pets, livestock, wildlife and people (Seward et al. 2004). Texas, the state with the largest feral hog population, reports the annual damage to agriculture at $51.8 million (Adams et al. 2005). The total damage caused by feral swine in the United States is estimated to be approximately$800 million annually (Pimentel et al. 2000). This estimate is approximate, and probably conservative, because environmental damage costs attributable to feral swine are not easily quantified nor are the costs of potential disease outbreaks