Relationship Between Body Mass and the Hoof Area: Understanding the Turner's Formula.

The equine hoof balance has been the subject of several studies, reflecting the importance of hooves for the good health and performance of these animals. An important condition for the hooves health is its loading, where too much weight in a small area can increase the chances of lameness. Therefore, an equation has been proposed to identify the relationship between body mass and hoof size and has been used in several studies. However, a clear description of how it was developed and what its results really indicate is not available in the literature. In light of this, this article aims to describe this Turner's equation and propose modifications to better characterize the body mass to hoof size ratio for fore- and hindlimbs.

Development and validation of a siphoning prototype for surface runoff evaluation.

The degradation of soil and water quality encourages research to assess the effects of rainfall on the losses of soil and chemical elements that result from surface runoff. In seasons of high surface runoff, the collectors must support the total volume drained or allow its correct estimation to avoid misinterpretation of the data. The present investigation aimed to develop and validate a compact and low-cost system to quantify surface runoff, sediments, and chemical elements losses using the bucket-siphon sampler system (BS3) siphoning method. The tests performed within the system used the runoff collected in a Nitisol or solutions constructed at the laboratory through mixing soil (i.e., Nitisol or Cambisol) with tap water. The BS3 method was efficient in estimating the total volume of water runoff and the concentration of sediments and P in the surface runoff. The maximum flow rate supported by the BS3 method, as presented here, is 0.035 L s-1 , which considering a 10-m² plot is equivalent to 12.6 mm h-1 . Due to the craft characteristics of the system, we recommend the calibration of each unit built to obtain a precise ratio between the volume stored and discarded by the siphoning. The prototype developed here is suitable for quantifying runoff volume, sediment, and P losses in field plots and has been manufactured under US$15.00.

Phosphorus speciation in soils with low to high degree of saturation due to swine slurry application.

Soils with continuous application of swine slurry (SS) may present high phosphorus (P) content and high risk for environmental pollution. The aim of this study was to characterize the forms of phosphorus accumulation in 15 fields with increasing degrees of P saturation (DPS) in a watershed with a high density of swine farming. Soil samples collected from 0 to 10 cm were chemically characterized for water soluble phosphorus (WSP), DPS, Hedley chemical fractionation, and chemical speciation by P K-edge XANES. WSP increased linearly to a value of 137% of DPS, with subsequent stabilization at 2.7 mg kg-1. Only the inorganic fractions of the chemical fractionation changed with increasing DPS. Phosphorus forms considered labile increased up to 144% of DPS, with subsequent stabilization. The moderately labile fraction 0.1 M NaOH and non-labile 1 M HCl increased exponentially. Phosphorus K-edge XANES analysis demonstrated that P associated to apatite, amorphous aluminum minerals, and goethite were the main forms of P found and only the latter had a correlation with DPS (-0.57*). With increasing DPS, there are changes in the dynamics of P in the soil, with a reduction in forms associated to Fe and an increase in forms linked to Al. The forms linked to Al buffer the WSP and are recovered in the first inorganic fractions of the Hedley chemical fractionation.