View clinical trials related to Organophosphate Poisoning.
Filter by:To Study the Effects of Lipid Emulsion on Hemodynamics in Organophosphate Compound Poisoning Objectives: To study the effect of administration of intravenous lipid emulsion on hemodynamic parameters, incidence of adverse effects in patients with organophosphate poisoning. Background: Lipid emulsion has been used to revert toxicities of lipophilic drugs, toxins (especially lignocaine) and in critically ill patients. Though the safety has been established, the effect on hemodynamics in Organophosphate (OP) poisoned patients has never been studied. Hence this study is underway to fill those lacunae and evaluate the safety profile of lipid emulsion in organophosphate poisoned patients. Methodology: The study is a prospective open label pilot study, which is underway at a tertiary care hospital in North India. Patients with history and clinical features of OP poisoning meeting the inclusion and exclusion parameters are being treated according to institutional protocols. Along with routine treatment a single dose of 20% lipid emulsion is being administered on admission to patients after obtaining consent. Patients are being followed up till discharge or death. Hemodynamic parameters and adverse effects following lipid emulsion administration are being studied over various intervals of time.
The purpose of this study is to evaluate self-reported symptoms as a proxy for acute organophosphate poisoning by examining self-reported acute organophosphate poisoning symptoms and PchE activity in response to occupational acute organophosphate exposure among farmers in Nepal.
We hypothesize that salbutamol will speed removal of alveolar fluid compared to atropine alone in OP poisoned patients. We propose to compare the effect of two stat doses of nebulized salbutamol (2.5 mg; 5.0 mg), with nebulized saline placebo, in symptomatic patients receiving standard resuscitation with atropine, oxygen, and fluids after poisoning with OP pesticides. 25 patients will be randomised to each arm (total 75 patients). Primary outcome will be oxygen saturation's over the following 60 min during resuscitation. Secondary outcomes will include atropine dose administered, speed to stabilization, aspiration or pneumonia, intubation, tachydysrhythmias, and mortality. A positive outcome will result in design of a large definitive phase III study.
Organophosphate pesticide poisoning causes close to 300 000 deaths per year worldwide. Many patients who ingest organophosphates require ventilation; of these patients approximately 50% die. Much of the mortality in these ventilated patients is secondary to intermediate syndrome. This is because OP pesticides inhibit acetylcholinesterase, causing an excess of acetylcholine at nerve synapses and the neuromuscular junction (NMJ). At the NMJ, the excess acetylcholine causes overstimulation and damage, which may lead to sudden respiratory arrest or prolonged ventilation and its associated complications. The investigators believe that blocking these receptors using a neuromuscular blocking agent such as Rocuronium will protect the NMJ from damage and thus prevent intermediate syndrome and reduce number of intubated days and mortality. In this pilot randomised controlled trial Rocuronium, a competitive nicotinic receptor antagonist, will be used to bind to the receptor at the neuromuscular junction and to block the effects of the accumulated acetylcholine. The effects of OP pesticide on cholinesterase in the blood will then be monitored and Rocuronium withdrawn using Sugammadex as the OP is eliminated from the body.
According to the World Health Organization pesticide poisoning is a major health problem due to the millions of cases annually occurring worldwide. Farmers have a particularly high risk of pesticide poisoning because of their work involving pesticide use to protect crops. The majority of pesticide poisonings occur in developing countries. On a short term it is not realistic to reduce farmers' use of pesticides significantly because it would require that secure and cost-effective alternatives are introduced. This is a lengthy process, which should undoubtedly be supported. However, it becomes as important to make sure that farmers can protect themselves from pesticide exposure meanwhile. Use of personal protective equipment can minimize pesticide exposure on farmers' bodies and consequently reduce their risk of pesticide poisoning. However, the sparse research identified through a systematic literature review shows that we are not in a position to give recommendations on what personal protective equipment farmers should protect themselves with against pesticide exposure suitable to their specific conditions. The purpose of the present study is to examine factors that influence farmers' use of personal protective equipment during their work with organophosphates and, based on this examine the ability of locally adapted personal protective equipment to reduce their organophosphate exposure. The hypothesis is that farmers working in locally adapted personal protective equipment have less acute organophosphate poisoning symptoms, a higher plasma cholinesterase level and find it to be a more feasible solution than farmers working in their daily practice wearing. Examining how locally adapted personal protective equipment (onwards referred to as the LAPPE solution) performs in practice implies testing it in an intervention study. A randomized crossover experiment design is chosen partly because fewer farmers have to be recruited since each farmer will act as his own control and partly because the between farmer variation is strongly reduced. The performance of the LAPPE solution will be tested in one experiment and compared to the performance of the same farmers' daily practice wearing (onwards referred to as the DP solution) in another experiment. The LAPPE solution is expected to have a superior performance. The participation sequence (LAPPE/DP or DP/LAPPE) will be randomized. The study will be conducted among farmers in Chitwan, Nepal.
To evaluate the effectiveness of Pralidoxime, a drug used for treatment of pesticide poisoning (Organophosphorous poisonings)
MicroDose Defense Products, LLC is developing an atropine dry powder inhaler (ADPI). This pilot study compares the pharmacokinetics (PK) of inhaled dry powder atropine as delivered by the ADPI to atropine delivery from the AtroPen autoinjector.