30 Clinical Trials for Various Conditions
A randomized, two-period, two-sequence, crossover study to assess the bioequivalence, bioavailability, and pharmacokinetics (PK) of a single dose of atropine administered sublingually (SL) or intramuscularly (IM) in healthy adult volunteers.
Progressive myopia can lead to severe vision loss and is associated with retinal detachment, glaucoma, and other comorbidities. Several studies have shown that off-label, low-dose atropine eye drops slow the progression of myopia. Many eye care providers are now prescribing off-label atropine eye drops for their myopic patients, with the prescribed concentrations varying amongst providers. The purpose of this study is to determine if low-dose atropine eyedrops used daily, cause adverse effects to the eyes. Patients currently using 0.01%, 0.03%, or 0.05% atropine eye drops obtained from compounding pharmacies will be assessed for associated adverse effects.
The purpose of this study is to examine the comfort of giving low concentration atropine eye drops.
This study will perform several objective and subjective measurements of the eye and vision before and after a week of using 0.01% concentration atropine drops. These measurements will help to obtain a comprehensive understanding of the side effects of this concentration of atropine and determine if the drops would be tolerated as a possible preventative treatment for nearsightedness.
Atropine eye drops are considered to be an effective form of myopia control in human eyes. However, the mechanism by which it exerts it effects are not fully understood. Thickening of the choroid subsequent to atropine administration may play an important role in the mechanisms by which atropine induces myopia control. Literature also notes that choroidal thickness undergoes diurnal variations, which is a variable that will be controlled in this study in order to examine atropine's effects on different baseline choroidal thicknesses. The purpose of the proposed study is to characterize better the influence of atropine on choroid thickness. The study aims are to: 1. Determine the effect of low dose concentration of topical atropine (0.1% and 0.01%) on choroid thickness 2. Determine the effect of topical atropine on choroid thickness in relationship to baseline thickness throughout the day and after one week of daily instillation Hypothesis: Atropine's effect on choroidal thickness will be dependent on the subject's baseline thickness measurements, at a designated time of the day when the choroid is at its thinnest.
Study Objectives The objectives for this randomized trial are: 1. To determine the efficacy of daily low-dose atropine (0.01%) for slowing myopia progression over a two-year treatment period in children aged 5 to less than 13 years (Primary Outcome On-Treatment). 2. To determine the efficacy of atropine treatment on myopia progression 6 months following cessation of low-dose atropine treatment (Secondary Outcome Off-Treatment). Synopsis of Study Design The current study is designed as an efficacy study, making effort to maximize adherence to treatment group assignments. After a run-in phase during which all participants are treated with daily artificial tear eyedrops for 2-4 weeks (and glasses are updated if required) to assess their ability to adhere to daily eye drops, participants are randomly assigned to daily atropine or placebo for 24 months, followed by 6 months off treatment.
An infants heart rate is very important because it ensures that blood is pumped to all organs in the body. Heart rate may decrease during anesthesia and surgery, and this is why the anesthesiologist will often give a medication to prevent this from happening. The most common drug for this purpose is called atropine. The dose of most drugs given to babies is based upon the baby's weight, but some believe that the dose of atropine should not be less than 0.1mg. However there is no evidence to support this minimum dose. A larger dose of atropine may cause a very fast heart rate instead. Anesthesiologists routinely dose the atropine based upon the baby's weight without regard for a minimum dose. The purpose of the present study is to measure the heart rate after doses of atropine in neonates and infants who receive less than 0.1 mg.
The purpose of this study is to determine if the antisialagogues (anti-salivary agents), Atropine and Glycopyrrolate, are effective in reducing hypersalivation when sedating patients with Ketamine for procedural sedation in the emergency department or abscess clinic. The investigators will measure salivary flow rate by collecting oral secretions by oral suctioning over a 30 minute time period starting with the administration of Ketamine. The investigators hypothesize that patients who receive either atropine or glycopyrrolate will have fewer oral secretions than patients who receive placebo.
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.
This study is designed to evaluate the effectiveness of adding a plano lens to weekend atropine after visual acuity has stabilized with weekend atropine but amblyopia is still present. Children ages 3 to \<8 years with visual acuity of 20/50 to 20/400 in the amblyopic eye will be enrolled in a run-in phase with weekend atropine until no improvement, followed by randomization of eligible patients to weekend atropine treatment with a plano lens over the sound eye versus without a plano lens over the sound eye. The primary objective is to determine if adding a plano lens to weekend atropine will improve visual acuity in patients with amblyopia still present after visual acuity has stabilized with initial treatment.
Purpose: The investigators plan to test a newly FDA approved pharmacologic stress agent, Regadenoson, in conjunction with atropine in the use of stress echocardiography for the diagnosis of coronary artery disease. The selective nature of Regadenoson allows for its use in patients with contraindications to the currently used drug, Adenosine, which is non-selective. Furthermore, the proposed protocol can be completed faster and without radiation exposure than the current protocol with adenosine. Design: This is a prospective study evaluating people with no prior diagnosis of coronary disease with a prior stress test and are scheduled for cardiac catheterization. Patients who meet inclusion criteria will undergo regadenoson-atropine echocardiography protocol prior to their catheterization. The study will be interpreted by two independent readers blinded to the catheterization results. The sensitivity, specificity, positive and negative predictive values of the regadenoson-atropine study will be then be calculated using the coronary angiogram as a gold standard.
This study is designed to evaluate the effectiveness of treatment of residual amblyopia in children ages 3 to \< 10 years with visual acuity of 20/32 to 20/63 in the amblyopic eye. The study is a randomized clinical trial comparing intensive treatment (42 hours per week of patching plus daily atropine) with a control group that will have rapid weaning of existing treatment followed by spectacle correction only (if needed). The primary objective is to determine if this intensive treatment will improve visual acuity in patients with residual amblyopia. The primary outcome assessment is amblyopic eye visual acuity at 10 weeks. The primary analytic approach for the amblyopic eye acuity will be a treatment group comparison of the proportion of patients with at least two lines of visual acuity improvement.
The purpose of this study is: * To compare the effectiveness of weekend atropine plus near activities and daily patching plus near activities for moderate amblyopia (20/40 to 20/100) and severe amblyopia (20/125 to 20/400) in improving vision in the amblyopic eye of 7 to \<13 year olds. * To determine the maximum improvement in vision of the amblyopic eye with each treatment. * To determine whether amblyopia is associated with structural abnormalities of optic nerve fiber layer.
The purpose of the study is: * To compare the effectiveness and safety of weekend atropine augmented with a plano lens for the sound eye versus weekend atropine alone for moderate amblyopia (20/40 to 20/100) in children 3 to less than 7 years old. * To provide data on the response of severe amblyopia (20/125 to 20/400) to atropine treatment with and without a plano lens.
The objective of this study is to identify a potential pharmacologic option by assessing whether 0.01% atropine may be effective for treating bothersome floaters as measured by scores on a modified NEI VFQ-25.
This research project aims to provide additional knowledge of pharmacological and optical methods of myopia control and to gain a better understanding of the biometry of the pediatric eye, which contributes to the onset and progression of myopia. As a result, this study will improving our best practices for myopia control in pediatric patients.
To evaluate the single-dose pharmacokinetics of atropine gel formulation after topical administration in the oral cavity of healthy adults.
This randomized, three-sequence, three-period, phase 1 study is designed to assess the bioavailability and pharmacokinetics (PK) of sublingually administered atropine sulfate ophthalmic solution 1% USP (at 0.5 mg and 1.0 mg; test) compared to atropine sulfate injection administered IV (1.0 mg; reference).
This study evaluates the progression of myopia in participants using microdosed atropine 0.01%, atropine 0.1%, or placebo ophthalmic solution. Eligible subjects will administer study medication daily in each eye for 48 months. Efficacy and safety assessments will be performed at visits scheduled for 1, 6, 12, 18, 24, 30 and 36 months after initiation of medication use. Subjects will be re-randomized at the 36 month visit, then followed at 6 month intervals for an additional year.
Atropine eye drops are increasingly prescribed for the management of progressive myopia or short-sightedness. A previous study suggested that the back of the eye or choroid may be a part of the mechanism by which it induces its effects. The aim of this study is to characterize the effects of atropine on choroidal thickness and the influence of time of administration (am vs pm). It is hypothesized that the atropine's effect on choroidal thickness will vary with baseline thickness related to diurnal rhythm, where thicker baseline thickness will show a reduced choroidal response.
To test the hypothesis that increasing the sinus node rate with atropine treatment prior to exercise will reduce exercise-triggered ventricular ectopy compared to baseline in patients with CPVT.
The purpose of this study is to determine whether less frequent dosing of atropine drops may be as effective as daily dosing for the treatment of progressive myopia.
The purpose of this study is to learn the effects of genetic make up on response to the drugs atropine and propranolol, to examine how changes in heart rate and blood pressure can be measured, and to test a new statistical analysis method.
The goals of this study are: * To compare the visual acuity outcome in the amblyopic eye after 17 weeks of daily use of atropine versus weekend-only use of atropine. * To compare the proportion of patients achieving a complete treatment response (defined as amblyopic eye acuity \>20/25 or equal to that of the sound eye in the absence of a reduction in the sound eye acuity from baseline) with daily atropine versus weekend-only atropine.
In this single-center retrospective cohort study of adult patients who underwent surgery under general anesthesia at Beth Israel Deaconess Medical Center between September 2016 and January 2024, the association between the choice of neuromuscular blocking agent (NMBA) reversal strategy, comparing sugammadex with neostigmine (combined with a muscarinic antagonist), and postoperative urinary retention (POUR) will be evaluated. In secondary analyses, the effects of NMBA reversal strategy and POUR on costs of care and unplanned hospital visits will be analyzed.
Glucose-dependent insulinotropic polypeptide (GIP) is a hormone produced in the intestine. It is released immediately after meal ingestion and increases insulin release. This, in turn, helps reduce blood glucose levels. This circuit does not work properly in humans with type 2 diabetes mellitus (T2DM). We have previously shown that a peptide called xenin-25 can amplify the effects of GIP on insulin secretion in humans. However, xenin-25 no longer does this when humans develop T2DM. Thus, it is important to understand how xenin-25 works in humans without T2DM so we know why it does not work in humans with T2DM. Acetylcholine is molecule produced by specific types of nerves. The effects of acetylcholine can be blocked by a drug called atropine. We have previously shown in mice that atropine prevents the ability of xenin-25 to increase the effects of GIP on insulin release. The purpose of this clinical trial is to determine if atropine also blocks the effects of xenin-25 in humans without T2DM. If it does, then impaired acetylcholine signaling may be one of the reasons humans develop T2DM and it could be possible to develop drugs that bypass this defect and increase insulin release in humans with T2DM.
Olfactory identification deficits occur in patients with Alzheimer's disease (AD), are associated with disease severity, predict conversion from mild cognitive impairment (MCI) to AD and are associated with healthy elderly subjects developing MCI. Odor (olfactory) identification deficits may reflect degeneration of cholinergic inputs to the olfactory bulb and other olfactory brain regions. Acetylcholinesterase inhibitors (ACheI) like donepezil show modest effects in improving cognition but can be associated with adverse effects and increased burden and costs because of the need for prolonged, often lifelong, treatment. Converging findings on odor identification test performance (UPSIT, scratch and sniff 40-item test) from four pilot studies, including two of our own, suggest that acute change in the UPSIT in response to an anticholinergic challenge (atropine nasal spray), incremental change over 8 weeks, and even the baseline UPSIT score by itself, may predict cognitive improvement with ACheI treatment in MCI and AD. If change in odor identification deficits can help to identify which patients should receive ACheI treatment, this simple inexpensive approach will advance the goal of improving personalized treatment, improve selection and monitoring of patients for ACheI treatment, reduce needless ACheI exposure with risk of side effects, and decrease health care costs.
* To determine whether the success rate with drug treatment (atropine) of amblyopia due to strabismus or anisometropia in patients less than 7 years old is equivalent to the success rate with occlusion (patching) therapy * To develop more precise estimates of the success rates of amblyopia treatment * To identify factors that may be associated with successful treatment of amblyopia * To collect data on the course of treated amblyopia to provide more precise estimates of treatment effects than are now available Extended Follow up of Study Patients * Primary: To determine the long-term visual acuity outcome at age 10 years and at age 15 years in patients diagnosed with amblyopia before age 7 years. * Secondary: To determine whether the long-term visual acuity outcome at age 10 years and at age 15 years differs between patients who received patching followed by best clinical care and patients who received atropine followed by best clinical care
The purpose of this study is to conduct a double blinded randomized control trial to determine the safety and efficacy of using IV fentanyl and atropine prior to Less Invasive Surfactant Administration (LISA) procedure in preterm infants with Respiratory Distress Syndrome compared to the local standard of care to perform this procedure without any premedication. Hypothesis: In infants greater than or equal to 29 weeks gestational age requiring the Less Invasive Surfactant Administration procedure, premedication with a combination of IV atropine and IV fentanyl will be associated with fewer combined bradycardia events, defined as heartrate less than 100 beats per minute for longer than 10 seconds, and hypoxemia events, defined as saturations less than or equal to 80% for longer than 30 seconds, during the procedure compared with placebo. Specific Aims: * To determine if infants receiving IV fentanyl and atropine prior to LISA will have a decrease in hypoxemia and bradycardia events during the procedure compared to infants receiving placebo * To determine if infants receiving premedication prior to Less Invasive Surfactant Administration will have higher procedure first attempt success rate compared with infants receiving placebo * To determine the effect of premedication on cerebral oxygenation compared to placebo during and for 12 hours after Less Invasive Surfactant Administration using cerebral Near Infrared Spectroscopy * To determine the effect of premedication prior to Less Invasive Surfactant Administration on the need for mechanical ventilation for 24 hours after the procedure
The purpose of this study is to compare the results of two standard treatments for amblyopia in order to find out if one is more effective than the other. Amblyopia, which develops in childhood, is also called "lazy eye," because one eye is not being used properly. The brain favors the other eye for some reason, such as crossing or turning out of the eyes, and vision in the weak eye is reduced. Amblyopia is treated by forcing the child to use the weak eye. There are two ways to do this: 1) a patch placed over the "good" eye forces the child to use the weak eye; or 2) an eye drop placed in the "good" eye once a day to blur vision in that eye makes the child rely on the weak eye. The success rates with both of these methods have been reported to be about the same; this study will try to identify if one is more effective than the other. Children will be randomly assigned by computer to one of the following two treatment methods: Patch The child initially will wear a patch over the "good" eye for 8 to 12 hours every day. If vision in the weak eye improves, the patching time will be decreased. If vision remains good after 3 months, the patching will be stopped, unless the child's doctor believes treatment should continue. If vision in the weak eye does not improve, the patching time will be increased. Eye Drops The child will be given one drop per day of atropine in the "good" eye. If vision in the weak eye improves, the drops will be given less often. If the vision remains good after 3 months, the drops will be stopped, unless the child's doctor believes treatment should continue. If the initial daily drop does not improve the vision in the weak eye, the child's eyeglasses may be changed to try to further blur the vision in the "good" eye. After 6 months, treatment may be stopped if it has not been successful. If treatment has been successful after 6 months, it may be continued at a reduced amount or stopped. Follow-up visits will be scheduled every 4 weeks for the first 6 months and every 2 to 4 months after that until the end of the 2-year study. During each visit the eyes will be examined for eye movements and vision, and the pupils will be dilated to examine the inside of the eye.