The effect of lignite on nitrogen mobility in a low-fertility soil amended with biosolids and urea.

Lignite has been proposed as a soil amendment that reduces nitrate (NO3(-)) leaching from soil. Our objective was to determine the effect of lignite on nitrogen (N) fluxes from soil amended with biosolids or urea. The effect of lignite on plant yield and elemental composition was also determined. Batch sorption and column leaching experiments were followed by a lysimeter trial where a low fertility soil was amended with biosolids (400 kg N/ha equivalent) and urea (200 kg N/ha equivalent). Treatments were replicated three times, with and without lignite addition (20 t/ha equivalent). Lignite did not reduce NO3(-) leaching from soils amended with either biosolids or urea. While lignite decreased NO3(-) leaching from an unamended soil, the magnitude of this effect was not significant in an agricultural context. Furthermore, lignite increased cumulative N2O production from soils receiving urea by 90%. Lignite lessened the beneficial growth effects of adding biosolids or urea to soil. Further work could investigate whether coating urea granules with lignite may produce meaningful environmental benefits.

Empower U: effectiveness of an adolescent outreach and prevention program with sixth-grade boys and girls: a pilot study.

Sixth graders are at a prime age to modify behaviors and beliefs regarding exercise, nutrition, body image, and smoking. Empower U was created to change knowledge, beliefs, and behaviors regarding these topics. This pilot study utilized pre/post assessments of 58 sixth graders from a private middle school in the midsouth. Results showed a significant increase in self-esteem as well as in exercise and nutrition knowledge and beliefs at posttest and a significant increase in body image as well as in self-reported exercise and nutrition behaviors at the 1-month follow-up. Empower U provides nurses with an effective educational program that may be useful in positively impacting health behaviors.

Cardioventilatory effects of acclimatization to aquatic hypoxia in channel catfish.

The mechanisms responsible for altering cardioventilatory control in vertebrates in response to chronic hypoxia are not well understood but appear to be mediated through the oxygen-sensitive chemoreceptor pathway. Little is known about the effects of chronic hypoxia on cardioventilatory control in vertebrates other than mammals. The purpose of this study was to determine how cardioventilatory control and the pattern of response is altered in channel catfish (Ictalurus punctatus) by 1 week of moderate hypoxia. Fish were acclimatized for 7 days in either normoxia (P(O(2)) approximately 150 Torr) or hypoxia (P(O(2)) approximately 75 Torr). After acclimatization, cardioventilatory, blood-gas and acid/base variables were measured during normoxia (P(O(2)) 148+/-1 Torr) then at two levels of acute (5 min) hypoxia, (P(O(2)) 72.6+/-1 and 50.4+/-0.4 Torr). Ventilation was significantly greater in hypoxic acclimatized fish as was the ventilatory sensitivity to hypoxia (Delta ventilation/Delta P(O(2))). The increase in ventilation and hypoxic sensitivity was due to increases in opercular pressure amplitude, gill ventilation frequency did not change. Heart rate was greater in hypoxic acclimatized fish but decreased in both acclimatization groups in response to acute hypoxia. Heart rate sensitivity to hypoxia (Delta heart rate/Delta P(O(2))) was not affected by hypoxic acclimatization. The ventilatory effects of hypoxic acclimatization can be explained by increased sensitivity to oxygen but the effects on heart rate cannot.