Boas práticas de manejo para sistemas de aquaponia.

O maior desafio na fase atual de desenvolvimento da aquaponia no Brasil é assegurar que essa atividade venha contribuir diretamente para a produção intensiva de alimentos em áreas rurais e peri-urbanas (ganhos de produção e produtividade), para o desenvolvimento e validação de sistemas fechados e integrados, garantindo o uso múltiplo e racional dos recursos hídricos, a maximização no aproveitamento dos nutrientes e a consequente redução na geração de efluentes (ganhos ambientais), além de proporcionar mais oportunidades de emprego e renda (ganhos sociais e econômicos). Diante disso, o objetivo deste documento é indicar um conjunto de Boas Práticas de Manejo (BPM) para aprimorar o monitoramento da qualidade da água e da avaliação do desempenho produtivo dos sistemas de aquaponia em uso no país, bem como em outros modelos (ou sistemas) aplicáveis a nossa realidade. Vale destacar, que não se trata de comparar diferentes sistemas de aquaponia, já que essa questão é bastante discutida em vários trabalhos que comprovam as vantagens e desvantagens de cada um (FAO, 2016; PATTILLO, 2017). O propósito é justamente indicar um conjunto de BPM para melhoria da qualidade da água e prevenção de doenças de peixes e plantas em sistemas de aquaponia.bitstream/item/178041/1/2018DC01.pd

Influence of ventilation mode on neonatal cerebral blood flow and volume

BACKGROUND: Cerebral hemodynamics is supposed to be influenced by the different ventilation approach. Ventilation support can be classified as non-invasive (N-CPAP) or invasive (SIMV and HFV), the last known to induce endotrauma. Our aim was the non-invasive NIRS assessment of neonatal absolute cerebral blood flow (CBF) and relative cerebral blood volume changes (DeltaCBV) during synchronized intermittent ventilation (SIMV), or high frequency ventilation (HFV) and nasal continuous positive airways pressure (CPAP). METHODS: An observational study in a tertiary referral NICU. CBF and DeltaCBV changes were assessed in 41 preterm newborn infants with respiratory distress syndrome treated using mechanical ventilation or the CPAP device. RESULTS: Basal chromophore traces enabled DeltaCBV (mL/100 g) changes to be calculated. CBF was calculated in mL/100 g/min from the saturation rise integral and rate of rise [O(2)Hb-HHb]. Median DeltaCBV was 0.07 (range 0.01-0.13) in SIMV group, 0.07 (0.01-0.19) in HFV group and 0.13 (0.10-1.28) in CPAP group. Median CBF was 14.44 (2.70-32.10), 9.20 (2.94-19.58) and 31.69 (13.59-34.93) respectively. A multiple regression model showed a significant correlation between DeltaCBV or CBF and ventilation approach. CONCLUSION: In the light of our results, we might speculate that, assuming that hemodynamic autoregulation is safe and arterial blood pressure is preserved, ventilation per se influences brain circulation

Comparison between the perinatal risk inventory and the nursery neurobiological risk score for predicting development in high-risk newborn infants.

BACKGROUND: The availability of a score for predicting neonatal outcome prior to discharge may help us to define the risk of developmental disorders in very low birth weight infants. AIM: To compare Scheiner's Perinatal Risk Inventory (PERI) with Brazy's Neurobiological Risk Score (NBRS) when applied at discharge, in predicting developmental delay at 24 months of age. STUDY DESIGN: To evaluate the predictive power of the two tests, we measured their sensitivity and specificity in predicting outcome (Mental Development Index, MDI, Psychomotor Development Index, PDI, and Amiel-Tison Neurological Examination) in an observational study. SUBJECTS: 102 very low birth weight infants (BW <1,500 g) admitted to our NICU at the Pediatric Department of Padova University. RESULTS: In the cohort studied, 75.5% of the patients had a normal MDI, while 24.5% showed a delayed performance (8.8% mildly and 15.7% severely so); the PDI was normal in 74.5% patients, whilst 25.5% had a delayed performance (9.8% mildly and 15.7% severely so). According to the Amiel-Tison test, neurological performance was normal in 66% patients, impaired without disability in 19% and impaired with disability in 15%. NBRS showed a sensitivity and specificity respectively of 0.96 and 0.23 (MDI), 0.96 and 0.24 (PDI), 0.94 and 0.25 (Amiel-Tison test); for PERI were 0.88 and 0.54 (MDI), 0.77 and 0.51 (PDI), 0.82 and 0.57 (Amiel-Tison test). The PERI and NBRS can predict the MDI with an AUC >0.8 and the PDI or Amiel-Tison findings with an AUC of 0.7-0.8. No significant differences were found between the areas under the ROC curves using the NBRS and the PERI. CONCLUSIONS: : In assessing the prognosis for individual babies, the physician can choose either the PERI or the NBRS to predict PDI, MDI or Amiel-Tison performance

Peripheral perfusion and oxygenation assessment using near-infrared spectroscopy (NIRS) and the oximeter pulsatility indexin healthy neonates

I.F. 2.83

Neurologic outcome in children after extracorporeal membrane oxygenation: Prognostic value of diagnostic tests

This report presents the long-term (36 months) neurologic outcome in 12 neonates and 9 children who survived after extracorporeal membrane oxygenation and attempts to identify its prognostic indicators through a prospective study in the pediatric intensive care unit of a university hospital. Outcome assessment, neurodevelopmental tests, electroencephalogram, auditory evoked potentials, visual evoked potentials, and somatosensory evoked potentials, cerebral sonography, or cerebral tomography were evaluated at the end of bypass and at 6, 12, 24, and 36 months after extracorporeal membrane oxygenation. "Before extracorporeal membrane oxygenation" variables (oxygenation index, pH, oxygen arterial partial pressure) and "during extracorporeal membrane oxygenation" variables (pH, oxygen arterial partial pressure, duration of bypass, clotting activated time, electroencephalogram) were also analyzed. A negative neurologic outcome (Glasgow Outcome Score different from "good recovery" or neurodevelopmental score less than 70) 12 months after extracorporeal membrane oxygenation was documented in 8.3 % of neonates and in 30 % of children who survived. There was no further change in subsequent evaluations (24 and 36 months follow-up). The most abnormal electroencephalogram during extracorporeal membrane oxygenation, the first electroencephalogram, neuroimaging score, and somatosensory evoked potentials after extracorporeal membrane oxygenation treatment were associated with negative neurologic outcome. The study documented that neonates and children treated with extracorporeal membrane oxygenation require long-term follow-up; electroencephalogram, neuroimaging score, and somatosensory evoked potentials have prognostic value for abnormal neurologic outcome. (c) 2005 by Elsevier Inc. All rights reserved

Does helmet CPAP reduce cerebral blood flow and volume by comparison with Infant Flow driver CPAP in preterm neonates?

OBJECTIVE: We compared neonatal helmet continuous positive airway pressure (CPAP) and the conventional nasal Infant Flow driver (IFD) CPAP in the noninvasive assessment of absolute cerebral blood flow (CBF) and relative cerebral blood volume changes (DeltaCBV) by near-infrared spectroscopy. DESIGN AND SETTING: A randomized crossover study in a tertiary referral NICU. PATIENTS AND INTERVENTIONS: Assessment of CBF and DeltaCBV in 17 very low birth weight infants with respiratory distress (median age 5 days) treated with two CPAP devices at a continuous distending pressure of 4 mbar. MEASUREMENTS AND RESULTS: Neonates were studied for two consecutive 60-min periods with helmet CPAP and with IFD CPAP. Basal chromophore traces enabled DeltaCBV changes to be calculated. CBF was calculated in milliliters per 100 grams per minute from the saturation rise integral and rate of rise O(2)Hb-HHb. Median (range) CBF with helmet CPAP was 27.37 (9.47-48.20) vs. IFD CBF 34.74 (13.59-60.10)(p=0.049) and DeltaCBV 0.15 (0.09-0.28) with IFD and 0.13 (0.07-0.27) with helmet CPAP (NS). Using helmet and IFD CPAP, the neonates showed no difference in mean physiological parameters (transcutaneous carbon dioxide and oxygen tension, pulse oximetry saturation, heart rate, breathing rate, mean arterial blood pressure, desaturation rate, axillary temperature). CONCLUSION: Assessing CBF and DeltaCBV measured by near-infrared spectroscopy with two CPAP devices revealed no differences in relative blood volume, but CBF was lower with helmet CPAP. Greater active vasoconstriction and/or passive capillary and/or venous vessel compression seem the most likely reason, due to a positive pressure around the head, neck, and shoulders by comparison with the airway pressure

Does Helmet-CPAP reduce cerebral blood flow by comparison with nasal CPAP in very low birth weight newborns?

OBJECTIVE: We compared neonatal helmet continuous positive airway pressure (CPAP) and the conventional nasal Infant Flow driver (IFD) CPAP in the noninvasive assessment of absolute cerebral blood flow (CBF) and relative cerebral blood volume changes (DeltaCBV) by near-infrared spectroscopy. DESIGN AND SETTING: A randomized crossover study in a tertiary referral NICU. PATIENTS AND INTERVENTIONS: Assessment of CBF and DeltaCBV in 17 very low birth weight infants with respiratory distress (median age 5 days) treated with two CPAP devices at a continuous distending pressure of 4 mbar. MEASUREMENTS AND RESULTS: Neonates were studied for two consecutive 60-min periods with helmet CPAP and with IFD CPAP. Basal chromophore traces enabled DeltaCBV changes to be calculated. CBF was calculated in milliliters per 100 grams per minute from the saturation rise integral and rate of rise O(2)Hb-HHb. Median (range) CBF with helmet CPAP was 27.37 (9.47-48.20) vs. IFD CBF 34.74 (13.59-60.10)(p=0.049) and DeltaCBV 0.15 (0.09-0.28) with IFD and 0.13 (0.07-0.27) with helmet CPAP (NS). Using helmet and IFD CPAP, the neonates showed no difference in mean physiological parameters (transcutaneous carbon dioxide and oxygen tension, pulse oximetry saturation, heart rate, breathing rate, mean arterial blood pressure, desaturation rate, axillary temperature). CONCLUSION: Assessing CBF and DeltaCBV measured by near-infrared spectroscopy with two CPAP devices revealed no differences in relative blood volume, but CBF was lower with helmet CPAP. Greater active vasoconstriction and/or passive capillary and/or venous vessel compression seem the most likely reason, due to a positive pressure around the head, neck, and shoulders by comparison with the airway pressure

Is the CRIB score (Clinical Risk Index for Babies) a valid tool in predicting neuro developmental outcome in extremely low birth weight infants?

infants in the first 12 h of life, as measured by the CRIB (clinical risk index for babies), relates to hospital outcome and subsequent disability at 18 months of age. The CRIB was confirmed as a valid index of initial neonatal risk, even in extremely low birth weight infants, predicting hospital outcome (death or major brain lesions) more accurately than birth weight or gestational age. However, an adjustment of the CRIB score for gestational age might enhance its positive predictive value in relation to short-term developmental outcome in this particular population

Foot pulse oximeter perfusion index correlates with calf muscle perfusion measured by near-infrared spectroscopy in healthy neonates.

Abstract OBJECTIVE: In critically ill neonates, peripheral perfusion and oxygenation assessment may provide indirect information on the circulatory failure of vital organs during circulatory shock. The development of pulse oximetry has recently made it possible to calculate the perfusion index (PI), obtained from the ratio between the pulsatile and nonpulsatile signals of absorbed light. The main goals of this study were: (1) to study foot PI; and (2) to evaluate the relationship between foot PI, obtained continuously by pulse oximetry, and a number of variables, i.e. blood flow (BF), oxygen delivery (DO(2)), oxygen consumption (VO(2)), and fractional oxygen extraction (FOE), measured indirectly by near-infrared spectroscopy (NIRS) on the calf in 43 healthy term neonates (weight 3474.6 +/- 466.9 g; gestational age 39.1 +/- 1.4 weeks). STUDY DESIGN: Calf BF, DO(2) and VO(2) were assessed by NIRS on short-lived venous and arterial occlusion maneuvers. PI was measured on the contralateral foot. RESULTS: Foot PI was 1.26 +/- 0.39. There was a positive correlation between foot PI and both calf BF (r = 0.32, p = 0.03) and DO(2) (r = 0.32, p = 0.03), but no correlation was found between foot PI and calf FOE and between foot PI and VO(2). CONCLUSIONS: In the neonatal intensive care unit, continuously measuring foot PI by pulse oximetry seems clinically more feasible for peripheral perfusion monitoring than spot measurements of the calf BF and/or VO(2) by indirect NIRS