View clinical trials related to Anosmia.
Filter by:- Causes of olfactory dysfunction can be classified into conductive and sensorineural causes. - Conductive causes are mainly due to structural nasal problem, which can be treated by nasal surgery - Sensorineural causes included post-infection, post-head injury, post Head and Neck irradiation and other central nervous system diseases. - Olfactory Training is well established treatment for sensorineural olfactory dysfunction in foreign countries. - Olfactory Training by neurological chemosensory stimulation using aromatic substances delivered via electronic portable aromatic rehabilitation (EPAR) diffuser was proved to be effective treatment in COVID-19 related olfactory dysfunction in recent Hong Kong study. - However, there is a lack of local study on the effect of Olfactory Training in other non-COVID-19 sensorineural causes of olfactory dysfunction in Hong Kong population.
The COVID-19 pandemic is a novel medical challenge, particularly because of the systemic nature of this disease. Indeed, COVID-19 affects several organs and systems at once. The brain is affected in several ways: direct infection of nerve cells by SARS-CoV-2, inflammation of the central nervous system, severe systemic inflammation damaging nerve cells, global cerebral ischaemia related to respiratory failure, thromboembolic events related to increased intravascular coagulation and severe psychological stress. As a result, COVID-19 sometimes manifests as neurological and neuropsychiatric symptoms such as dizziness, sleep disturbances, cognitive deficits, delirium, or severe depression. Sudden loss of smell is a common symptom associated with COVID-19 and SARS-CoV-2 infection of neurons in the olfactory system has been reported in both hamsters and humans. The vast majority of COVID-19 patients recover their olfactory function within a few weeks. However, a significant minority of infected individuals (1 in 5 cases) still suffers from olfactory disorders (anosmia, hyposmia and/or parosmia) several months after the primary infection. These olfactory disorders are frequently associated with depressive behaviour and cognitive complaints. In PET scans, it is even possible to correlate this cognitive dysfunction with hypometabolism of certain brain regions, including the olfactory gyrus. This project proposes, during one year, to evaluate and follow the evolution of the olfactory capacities of patients suffering from persistent smell disorder since one year (+/- 4 months) following COVID-19. The issue is to study the link between viral persistence in the olfactory sensory organ, chronic inflammation, and central damage to the olfactory system. The follow-up of the evolution of olfactory and neurocognitive capacities, in an integrative way by means of molecular, physiological and behavioural approaches, will inform us on the specificities of "COVID-long" and on the level of peripheral and/or central damage of the olfactory system.
Methods: all studies are case control studies on six different groups: normal individuals, non-COVID-19 patients with olfactory dysfunction, COVID-19 positive patients, previous COVID-19 positive patients with prolonged olfactory dysfunction, patients with chronic rhinosinusitis with and without nasal polyps, and patients with CRS initiating intranasal glucocorticoids.. The patients will be included from the ear-, nose, and throat department and the University Clinic for Flavour, Balance, and Sleep Regional Hospital Gødstrup, as well as Flavour Institute, Department of Clinical Medicine, Aarhus University (AU), and the long COVID-19 clinics in Aarhus and Gødstrup. Microbiome samples will be swabs from the nasal cavity and oral pharynx will be collected and analysed using next-generation sequencing targeting 16S and 18S ribosomal RNA at the Department of Bacteria, Parasite & Fungi at Staten Serum Institute (SSI), Copenhagen, Denmark. Characterization of the microbiome is performed by 16S/18S amplicon-based metagenomics, and data are analyzed by various bio-informatic tools for determination/visualization of alpha/beta diversity as well as principal coordinates analysis (PCoA). Immunological factors will be collected by means of six swabs: in the nasal cavity and used for either flowcytometry or enzyme-linked immunosorbent assay (ELISA). For comparison, truecut biopsies of the nasal mucosa are collected from a subgroup of patients undergoing surgery in general anaesthesia. Due to the novelty of the current study, little relevant information from previous literature can be used for power calculation. However, with an alpha of 5% and a power of 80%, the population size for each group should be 42 participants, assuming the occurrence of bacteria differs with 30% between populations. Taking 20% drop out into account, the investigators aim to include 60 patients in each group. Perspectives: The perspectives of this study is to begin bridging the gap between gut and upper airway microbiome and immunology research. Looking at the explosion of interest in the gut, and in personalized medicine in general, the investigators likewise foresee a huge potential for both general and individual prevention and treatments starting with a deeper understanding of the nasal microbiome and immunology. Examples beyond the scope of this study could be microbiome transplants for chronic sufferers of diseases such as chronic rhinosinusitis, allergies or asthma, or in selecting which patients could reap the benefits of the expensive biological treatments emerging on the market.
The purpose of this study is to learn more about how to better track smell recovery in people who have been infected with the SARS-CoV-2 virus (which causes COVID-19). Many people who have been infected by this virus develop changes in their sense of smell (olfaction). We are interested in measuring smell function objectively via smell cards that test odor intensity, identification, and discrimination. Objective and precise olfactory testing that can be performed in the convenience of one's home will help identify people with smell loss after infection by SARS-CoV-2. We will use results from this test to better understand the relationship between SARS-CoV-2 infection and recovery of olfactory function and to learn whether the AROMHA longitudinal smell test is a reliable olfactory function tracking tool to quantify smell loss in the context of COVID infection. These results may inform the design of therapeutic clinical trials to accelerate the recovery of smell function.
ivermectin is FDA approaved antiparasitic drug which is also claimed to be having potent in vitro antiviral effect,so we are tryying to study itsovid19 anosmia effect upon releiving post covid19 anosmia
Time to recover of Anosmia and / or ageusia and early corticosteroid use
Prevalence and Outcomes of Olfactory and Gustatory Dysfunctions in Patients with COVID-19
This study is designed to investigate the acuity of olfactory dysfunction in COVID-19 positive patients in the United Kingdom. In particular defining severity with objective testing and determining if this has any predictive value on the outcome of the SARS CoV-2 infection. In addition, this study will strive to determine duration / natural history of olfactory dysfunction in these patients in respect to a positive SARS CoV-2 diagnosis. It should also demonstrate the impact of olfactory dysfunction on patient Quality of Life (QOL).
The Malaysian COVID-19 Anosmia Study is a nationwide multicentre observational study to investigate the prevalence and characteristics of olfactory and gustatory/taste disturbances in COVID-19 infection in Malaysia, and to evaluate the predictive value of screening for these symptoms in COVID-19 infection. This study consists of two phases: the first phase is a cross-sectional study and the second phase is a case-control study. The case-control study is described here (the cross-sectional study is described in a separate ClinicalTrials.gov record).