key: cord-1018713-ngpv0iwq authors: Ahmed, Abdulrahman K.; Sayad, Reem; Mahmoud, Islam A.; EL-Monem, Aya M. Abd; Badry, Salma H.; Ibrahim, Islam H.; Hafez, Mahmoud HR; El-Mokhtar, Mohamed A.; Sayed, Ibrahim M. title: “Anosmia” the mysterious collateral damage of COVID-19 date: 2022-03-05 journal: J Neurovirol DOI: 10.1007/s13365-022-01060-9 sha: fa4c717c0f3f64af90b37937367719bbf7e75897 doc_id: 1018713 cord_uid: ngpv0iwq COVID-19 pandemic spreads worldwide, with more than 100 million positive cases and more than 2 million deaths. From the beginning of the COVID-19 pandemic, several otolaryngologists described many cases of a sudden loss of smell (anosmia) associated with the disease with or without additional symptoms. Anosmia is often the first and sometimes the only sign in the asymptomatic carriers of COVID-19. Still, this disorder is underestimated, and it is not life-threatening. However, it significantly decreases the quality of life. This olfactory dysfunction continues in several cases even after the nasopharyngeal swab was negative. The occurrence of anosmia can be used as a screening tool for COVID-19 patients and can be used to identify these patients to accomplish the isolation and tracking procedures. In this review, we highlighted the possible mechanisms of anosmia in COVID-19 patients, major pathologies and features of anosmia, implications of anosmia in early diagnosis of COVID-19, evaluation of the smell function during COVID-19, and management and treatment options of COVID-19 anosmia. COVID-19 is caused by SARS-CoV-2, which is a new strain of the coronavirus. The pandemic had emerged in Wuhan, China, and spread rapidly throughout China and successively worldwide Zhu et al. 2020) . Many studies from the USA, Asia (China, South Korea, Iran), Europe (France, Spain, Italy, UK, Germany), and Australia have revealed various levels of smell loss (anosmia/hyposmia/ dysosmia) as an early symptom of COVID-19 (Abalo-Lojo et al. 2020; Aggarwal et al. 2020; Gautier and Ravussin 2020; Gilani et al. 2020; Hopkins et al. 2020; Huang et al. 2020 , Merza et al. 2020 . It was found that sudden anosmia in asymptomatic infected patients could be the early and only symptom of the disease. Self-isolation should be started before alerting the health authorities to patients who acquired anosmia (Roland et al. 2020; Yan et al. 2020) . COVID-19-related anosmia is often not associated with nasal obstruction (Huart et al. 2020; Lechien et al. 2020a, b, c; Altundag et al. 2021) . In some studies, the incidence of anosmia has been observed up to > 80% of .5% of patients may have anosmia without any other clinical symptoms (Beltrán-Corbellini et al. 2020; Lechien et al. 2020a, b, c) . A unique feature of the COVID-19 anosmia is its transient course, which begins suddenly regardless of other features and improves gradually over a short period (about 2 weeks) (Lechien et al. 2020a, b, c) . Other studies have supported the spontaneous improvement of anosmia with a mean duration of 2-3 weeks (Heidari et al. 2020; Hornuss et al. 2020) . However, patients with more than 1 month of anosmia, known as persistent anosmia, have also been observed (Kandemirli et al. 2021; Tsivgoulis et al. 2021) . Taking into consideration that olfactory epithelium undergoes regeneration over 6-8 weeks, COVID-19 could lead to anosmia of more than 2-3 weeks up to 6-8 weeks due to epithelial damage ). The olfactory epithelium, which is responsible for olfaction, is present in the upper part of each side of the nasal cavity. It overlies the superior turbinate, the roof, and the upper part of the nasal septum. The olfactory epithelium is also present in the anterolateral part of the middle turbinate and the posterior part of the nasal septum (Kern 2000) . The olfactory epithelium consists of five main types of cells, namely, sustentacular cells, the olfactory sensory neurons (OSNs), duct cells of Bowman's glands, basal cells, and microvillar cells (van Riel et al. 2015) . The olfactory sensory neurons are bipolar cells projecting their dendritic processes externally into the nasal cavity (Liang 2018) , and these dendritic processes present the olfactory receptors (ORs) are G-protein coupled receptors (Brennan 2018) . The odorants, either inhaled through the nose or entered through the mouth, reach the olfactory epithelium, and bind to the olfactory receptors resulted in the formation of cyclic adenosine monophosphate (cAMP) and chloride ions efflux (Kern 2000; Attems et al. 2015) . The action potential is then transmitted through the olfactory sensory neurons (OSNs) axons to the olfactory bulb on the ventral surface of the frontal lobe. After that, the signals are transmitted from second-order neurons (axons of mitral and tufted cells) to the olfactory areas in the anterior part of the temporal lobe (anterior olfactory nucleus), the olfactory tubercle, and the amygdala (Attems et al. 2015; Diodato et al. 2016) . Some fibers in the hippocampus cause memory and emotional response associated with smell sensation (Aqrabawi and Kim 2020) . Since anosmia is an early and occasionally the only symptom of COVID-19 infection, researchers have proposed five possible mechanisms for the pathogenesis of anosmia associated with COVID-19 ( Fig. 1). (1) Affection of Angiotensin-Converting Enzyme 2 Receptors "ACE2," (2) damage of (2) the virus causes a damage of sustentacular cells; (3) damage of the mitral cell in the olfactory bulb of the brain may also comprise the transmission of odor sensation. (4) Utilization of Zn by the virus prevents its utilization by carbonic anhydrase which is a critical enzyme to maintain the smell function. (5) Following the infection, nasal obstruction caused by increased mucous may prevent the smell stimulus from reaching ORN Although the exact mechanism has not been established, yet some studies-performed on either human specimen from different tissues or on animal models such as micesuggest that the entry of the SARS-CoV-2 virus into the cells depends on the expression of ACE2 and Transmembrane protease serine 2 (TMPRSS2) by the target cells (Hamming et al. 2004; Sungnak et al. 2020) . By analysis 15 different organs collected from 93 patients' biopsies, Hamming and colleagues showed that ACE2 is profusely present in human organs, especially in the epithelial of lung and small intestine suggesting that these places are targets of entry for the SARS-CoV (Hamming et al. 2004) . Moreover, ACE2 is expressed in human vascular endothelium explaining the pathogenesis of the SARS-CoV (Hamming et al. 2004 ). Using C57BL/6J mouse model, Bilinska et al. reported that ACE2 and TMPRSS2 are expressed in murine sustentacular cells of the olfactory epithelium which are the target of SARS-CoV-2 entry and anosmia ). Sungnak and colleagues assessed the transcript expression of genes involved in the viral entry in healthy human donors using single-cell RNA sequencing, and they showed that ACE2 and TMPRSS2 genes are highly expressed in respiratory, intestinal, and corneal epithelial cells, together with innate immunity genes, suggesting the role of the previous genes in SARS-COV transmission and clearance (Sungnak et al. 2020) . SARS-CoV-2 virus utilizes these receptors for entry without inducing a local inflammatory response; therefore, more than 50% of the infected patients have smell dysfunction despite the absence of nasal congestion or rhinorrhea (Kaye et al. 2020; Lechien et al. 2020a, b, c) . Many cells express ACE2 throughout the body such as olfactory epithelium (Brann et al. 2020) , ciliated and goblet cells of respiratory epithelium, oral mucosa, salivary glands, epithelium of the tongue including taste buds (Chen et al. 2020a ) which can explain the occurrence of both anosmia and ageusia concurrently; although each one of them may occur separately. SARS-CoV-2 virus is suggested to cause anosmia by binding to ACE2 receptors on OSNs, sustentacular cells, and Bowman's glands leading to functional damage and disruption (Cooper et al. 2020; Li et al. 2020a, b) . Importantly, the expression of these receptors is low in the olfactory sensory neurons, so another suggested possibility is through infection of sustentacular cells and Bowman's glands which showed higher expression of these entry proteins than the OSNs; damage of these cells may cause disruption of the function of OSNs. Sustentacular cells are supporting cells for the olfactory neurons, and they are supplying the neuronal cells with nutrients, getting rid of residual odorant-binding proteins, and maintaining the structural integrity of the olfactory epithelium (Heydel et al. 2013; Cooper et al. 2020) . SARS-CoV-2 virus is present mostly in the sustentacular cells and pericytes due to the abundance of ACE2 and TMPRSS2 where the damage of these cells was done both metabolically and functionally leading to smell abnormalities up to complete loss of smell sensation (Bryche et al. 2020; Meinhardt et al. 2021) . Bertrand Bryche et al. showed the effect of SARS-CoV-2 infection on the olfactory system in golden Syrian hamsters using confocal double-label immunostaining and revealed that there was great damage to a large number of sustentacular cells and a major loss of cilia necessary for odor detection. Anosmia and hyposmia caused by SARS-CoV-2 are caused by either direct effect of the virus on the sustentacular cells leading to functional disturbance or indirect effect on olfactory sensory neurons leading to metabolic and functional disturbance (Heydel et al. 2013) . Another possible mechanism of anosmia is the inflammatory response released against the virus including the release of proinflammatory cytokines such as tumor necrosis factor-alpha (TNF-α) leading to damage of the olfactory epithelium which results in dysfunction of the sensory odorant neurons (Bryche et al. 2020; Meinhardt et al. 2021) . The regeneration of damaged olfactory sensory neurons usually takes from 8 to 10 days followed by another 5 days for the maturation of their dendritic processes (Schwob et al. 1995; Schwob 2002; Brann and Firestein 2014; Liang 2018) , which is longer than the recovery period of the smell dysfunction associated with SARS-CoV-2 that usually resolve or markedly improve in about one week (Lechien et al. 2020a, b, c; von Bartheld et al. 2020) , while damaged sustentacular cells require a shorter time to regenerate (Schwob et al. 1995; Schwob 2002) which is more consistent with the duration of COVID-19 anosmia. Although it is obvious that the respiratory tract is the most important site of infection, the brain has been shown to be affected by the virus or viral products. Lambrecq et al. (2021) reported frontal EEG changes in 24 cases out of 35 positive COVID-19 patients (Lambrecq et al. 2021) . Large cohort studies concluded that delirium and frontaltype behavioral changes were often described in COVID-19 patient (Helms et al. 2020 ). SARS-CoV-2 virus invades the central nervous by binding to ACE2 receptor; however, the exact pathophysiology of SARS-CoV-2 neuro-invasiveness in different brain tissues during infection is still not completely understood (Li et al. 2020a, b) . The expanded neurological manifestations associated with the infection led some researchers to believe that SARS-CoV-2 is neurotropic Gomez-Pinedo et al. 2020; Paniz-Mondolfi et al. 2020; Politi et al. 2020 ). However, there is currently a lack of precise experimental proof of SARS-CoV-2 neuroinvasiveness in various brain tissues. In fact, it is still unknown if and how SARS-CoV-2 infects distinct parts of the brain after crossing the blood-brain barrier (Zhang et al. 2021) . In postmortem study of positive COVID-19 patients died in the hospitals in Germany, it was reported that SARS-CoV-2 was detected in the brain of 53% (21/40) of examined patients, though there was no clear evidence that SARS-CoV-2 damages the CNS (Matschke et al. 2020 ). Postmortem study of a 74-year-old male infected with SARS-CoV-2 in China reported the presence of SARS-CoV-2 in the frontal lobe tissues in the neural and capillary endothelial cells (Paniz-Mondolfi et al. 2020) . In Italy, autopsy of a male 54-year patient showed severe tissue damage, involving the olfactory nerve, the gyrus rectus, and the brain stem with detectable virus in the tissues (Bulfamante et al. 2020 ). In addition, analysis of human transcriptome databases showed that ACE2 receptor is strongly expressed on many brain locations, including the olfactory bulb, the pericytes, and endothelial cells supporting the permissiveness of the CNS to SARS-CoV-2 infection (Chen et al. 2020b ). Sustentacular cells of the olfactory epithelium are primary supporting cells for the epithelium and important for the metabolism of olfactory neurons and odor perception; therefore, the damage induced by SARS-CoV-2 in these cells may contribute to the olfactory impairments in COVID-19 patients . Interestingly, the previous variant of coronavirus, SARS-CoV-1, that first emerged in China in 2002, could infect the olfactory neurons of mice transgenic for human ACE2. The initial infection was followed by rapid transneuronal transport of the virus to different areas of brain and was associated with death of the animal (Netland et al. 2008 ). On the other hand, other studies on human, hamster, and mice reported that the SARS-COV2 does not/ or less infect the olfactory receptor neurons Brann et al. 2020; Bryche et al. 2020; Bilinska et al. 2021) . The discrepancies in reports of the ability of the virus to infection the neurons may be attributed to the difference in the methods used to describe the expression of the receptor. Majority of the reports did not provide accurate quantitative analyses of the receptor expression. In addition, it is possible to get false positive results from immune fluorescence images of an infected sustentacular cell that phagocytosed a neuron or its debris. These cells which contain the viral protein colocalized with a neuronal marker. Moreover, studies-based detection of the spike protein in the brain may provide false positive results result from the shed spike protein without containing the virus (reviewed by ). Most COVID-19 patients suffer from obstruction of olfactory clefts totally which causes olfactory dysfunction (Eliezer et al. 2020 ), but the exact cause of olfactory clefts obstruction remains unknown (Trotier et al. 2007 ). Laurendon et al. found olfactory clefts accompanied by mild edema and olfactory bulbs in both sides in MRI of COVID-19 patient (Laurendon et al. 2020) . The interaction between SARS-CoV-2 and ACE2 may be the cause of this edema that could be one of the causes of anosmia. Zinc (Zn) is an essential nutrient in the human body. It is needed for cell growth, differentiation, and survival (Andreini et al. 2006) . Also, Zn acts as a cofactor for proteins through catalytic functions of enzymes and transcription factors and acting as a second messenger (Fukada and Kambe 2018) . Zinc deficiency is a predisposing factor of COVID-19 because its deficiency causes thymic atrophy and depression in both adaptive and innate immune responses which increase the susceptibility to infection (Shankar and Prasad 1998) . SARS-CoV-2 virus causes Zn deficiency after infection through the utilization of cellular Zn for viral replication and chelation (Wessels et al. 2020) . The level of Zn is decreased to in 60% of patients with a viral infection, and stayed low for several weeks (Srinivas et al. 1988 ). Zn deficiency is a common cause of anosmia because of the decrease in the function of zinc-dependent metalloenzyme called carbonic anhydrase (CA) which is a critical enzyme to maintain the smell function (Komai et al. 2000) . Hence, Zn level is correlated to COVID-19 anosmia. Anosmia is an early and sometimes the only symptom of COVID-19, which could be a beneficial tool for early detection and prevention of further spread of the pandemic for the following reasons: • The high prevalence of anosmia in COVID-19 patients. A multicenter case series that was conducted on 1420 European COVID-19 cases (laboratory-diagnosed with RT-PCR), using a standardized questionnaire, showed that 997 cases (70.2%) reported smell loss (Lechien et al. 2020a, b, c) . Another multicenter European study, that used certain questionnaires based on the smell and taste component of the National Health and Nutrition Examination Survey and the short version of the Questionnaire of Olfactory Disorders-Negative Statements (sQOD-NS), showed that out of 417 laboratory-confirmed COVID-19 cases with RT-PCR, 357 cases (85.6%) had olfactory dysfunction, among them, there was 284 (79.6%) having anosmia (Lechien et al. 2020a, b, c) . • Anosmia can be the earliest symptom of COVID-19 (Lechien et al. 2020a, b, c; Vaira et al. 2020a, b) . The prospective multicenter cohort study done on 55 French patients mainly complaining of loss dysfunction with 51 of them were COVID-19 positive based on RT-PCR; olfactory dysfunction revealed that the impairment of the smell sensation was the first symptom in 16 (29.1%) of the patients (Salmon Ceron et al. 2020). • Anosmia as a symptom of COVID-19 can be of sudden onset, spontaneous recovery, and a variable duration (it may last below or more than 5 days with a maximum of 2 weeks in some cases, but it can last even more than this period in other patients). Anosmia was also reported without any association of nasal obstruction or rhinorrhea in a considerable proportion of COVID-19 cases (Lechien et al. 2020a, b, c) . In an aforementioned study, made on 55 patients in France, there were 47 (88.7%) out of 53 of them complained of a sudden onset of smell affection (Salmon Ceron et al. 2020). Besides this, in a study performed in Italy on 53 COVID-19 cases who experienced chemo-perceptive affection, 35 (66%) of them reported spontaneous complete recovery of their chemosensory dysfunction; nonetheless, by using the Connecticut Chemosensory Clinical Research Center olfaction test and another standardized test for taste, the results asserted that there were still 80% of these patients with some levels of chemosensory diminution (Vaira et al. 2020a, b) . In addition, it was reported by an abovementioned study (of 1420 cases) that of those with smell loss (997 cases), there were 29.4% without nasal obstruction and 38.5% without rhinorrhea (Lechien et al. 2020a, b, c) . • Smell affection due to COVID-19 is very common in young patients who spend a lot of their time outdoors leading to more spread of the disease (Lechien et al. 2020a, b, c; Salmon Ceron et al. 2020 ). All these reasons encourage using smell tests as a screening tool for COVID-19. In spite of the predicted low specificity of these tests, as anosmia is a common symptom of the abovementioned diseases and it can be caused by some of the drugs used for COVID-19 treatment, their predicted high sensitivity (for the reasons mentioned above) may be useful in early detection of cases or even asymptomatic carriers, and the presence of other coexisting COVID-19-related symptoms (e.g., fever, dry cough) during smell testing time can support the test positive result; then, the diagnosis can be confirmed in positively tested subjects by viral detection methods. Many agents and various pathologies can cause anosmia such as COVID-19, Parkinson's disease, Alzheimer's disease, rhinosinusitis (influenza & allergic rhinitis), drugs, normal aging, stroke, human immunodeficiency virus, head trauma, environmental exposure (smoking, air pollution), depression, and schizophrenia. In various pathological conditions, anosmia is a reliable early symptom. Viral infections, such as SARS-CoV-2 and influenza virus, are common causes of anosmia (Table 1) . Upper respiratory tract infections (URTIs) are a major cause of anosmia (Kalogjera and Dzepina 2012) . The permanent smell loss in adulthood is most commonly caused by URS viruses (influenza, colds) (Deems et al. 1991) . Rhinoviruses (RVs) are the main cause of common colds (Blaas 2016) . The sense of smell can be affected by the viruses through two mechanisms of action. The first mechanism, induced by RVs and other coronavirus infections except SARS-CoV-2, is inducing inflammation in the nasal mucosa coating nasal passages. The mucosa becomes swollen and coated with a covering of nasal discharge leading to nasal obstruction which causes anosmia by preventing the odorant molecules from reaching and binding to their targeting receptors or by reducing the airflow which reduces the number of odorant molecules entering the nasal cavity (Akerlund et al. 1995; Rebholz et al. 2020) . The second mechanism includes the damaging of the olfactory epithelium and its included nerves and cells (Welge-Lüssen and Wolfensberger 2006) . Anosmia after flu infection is possible as with other viruses (Suzuki et al. 2007 ). Loss of olfactory and taste sensations has not been discussed within the clinical features of the flu in medical literature (Paules and Subbarao 2017; Cavallazzi and Ramirez 2018) . In a retrospective and observational study conducted in NFC (Nord Franche-Comté) Hospital, including 70 patients with confirmed COVID-19 and 54 patients with influenza Type A and B, loss of smell and taste sense was confirmed in 17% and 20%, respectively in the influenza group, while in the COVID-19 patients, the loss of smell and taste was recorded in 53% and 49%, respectively (Zayet et al. 2020 ). Allergic rhinitis affects the nasal cavity because of the excessive inflammatory response of the immune system to several allergens present in the air such as bacteria, viruses, mold, dust, and pollen. The symptoms of allergic rhinitis are developed due to damage of the olfactory mucosa including sneezing, rhinorrhea, nasal itching, nasal blockage, and conjunctivitis, and loss of sense of smell and taste (Rebholz et al. 2020) . Anosmia is also associated with allergic rhinitis (Imamura and Hasegawa-Ishii 2016; Rebholz et al. 2020 ). In the case of rhinitis/sinusitis, the interruption of airflow loaded with molecular particles to olfactory sensory neurons due to nasal obstruction is the main cause of loss of olfactory sense, but damage to the olfactory mucosa is also one of the possible causes (Imamura and Hasegawa-Ishii 2016). Among COVID-19 patients, about 13% of the cases of anosmia are reported to be induced by drugs (Tuccori, Lapi et al. 2011) . Many drugs impair the smell function (Ackerman and Kasbekar 1997; Fernández Fernández et al. 2000; Kraus and Vitezic 2000; Manzano Alonso et al. 2001; Chen et al. 2002; Kharoubi 2003; Ferraro et al. 2019) (Table 2) . Smell disorders associated with drugs have two possible; direct and indirect. The direct mechanism includes a disturbance in both neurotransmitter function and neural interaction in sensory coding brain areas. The indirect mechanism includes modifications to the chemical environment of the sensing receptor, as well as physical barriers that prevent chemical molecules from reaching receptors (Doty and Bromley 2004) . The macrolide azithromycin, used as a part of the treatment plan, is known to cause several chemosensory side effects including anosmia and parosmia (Ferraro et al. 2019) . Also, drugs used for the treatment of hypertension (such as ACEIs and ARBs) and DM (such as thiazolidinedione) which are major comorbidities of COVID-19 infection are believed to cause upregulation of ACE2 receptors in both olfactory and oral mucosa which may worsen anosmia caused by COVID-19 infection (Fang et al. 2020 ). Corticosteroids are used to treat edema and inflammation associated with COVID-19 anosmia. However, the French Society of Otolaryngology recommends that corticosteroids should not be used in the treatment of SARS-CoV-2 anosmia (Russell et al. 2020 ). Therefore, precautions should be taken when using steroids in such situations to avoid complications associated with this therapy such as immunosuppression. Anosmia is more frequently associated with fever, persistent cough, diarrhea, fatigue, loss of appetite, and abdominal pain (Marin et al. 2018; Zayet et al. 2020) . Anosmia is less frequently associated with sputum, production, dyspnea, sore throat, vomiting, and rhonchi sounds (Zayet et al. 2020 ). Anosmia associated with other symptoms of allergic rhinitis: sneezing, rhinorrhea, nasal itching, nasal blockage, and conjunctivitis (Varshney and Varshney 2015) . Anosmia associated with a history of taking some drugs like α-interferon, β-blockers, cadmium, ciprofloxacin, cocaine, and cytosine (Ackerman and Kasbekar 1997) . (Henkin 1994; Ackerman and Kasbekar 1997; Doty 2008; Hummel et al. 2009; Ravits and La Spada 2009; Hüttenbrink et al. 2013; Varshney and Varshney 2015; Marin et al. 2018; Watts et al. 2019; Zayet et al. 2020) Using steroids intranasally is helpful in reducing the exacerbation of viral infection in the upper respiratory tract, olfactory dysfunction, and epithelial damage with less complication (Stenner et al. 2008; Jung and Kim 2020) . Another strategy of the therapy is the administration of nasal saline irrigations containing drugs that act by competitive inhibition of ACE2 receptor (Wong et al. 2004) , followed by nasal and oral corticosteroids (Lechien et al. 2020a, b, c) . ENT UK published a guide for the management of the loss of smell associated with COVID-19. They recommend considering referral when the symptoms of smell loss last more than 4-6 weeks in negative patients and do not have any other cause identified, or more than 3 months in COVID-19 patients. In addition, the UK guidance recommended all patients with anosmia for more than 6 weeks with additional neurological symptoms regardless of COVID status to undergo MRI imaging of the brain (Walker et al. 2020) (Fig. 2) . Patients are advised to follow the first-line treatment measures, which is the use of topical corticosteroid sprays and smell training until the specialist visits. There is a simple available method for the recovery of anosmia, which is smell training Damm et al. 2014; Pekala et al. 2016; Hummel et al. 2018; Kattar et al. 2021) . The exposure to odours frequently for a prolonged time reduces the threshold to these odours and produces a sensitizing effect (Miwa et al. 2019) . Using theophylline to inhibit phosphodiesterase activity is a general approach for the improvement of the olfactory sensitivity by prolonging the intracellular signalling cascade which increases odor perception; however, this pharmacological choice is not effective in most cases (Gudziol and Hummel 2009 ). Therefore, several doctors suggested that the surgical intervention could be a solution to anosmia. However, it remains difficult to predict the extent of improvement in the olfactory function after the operation (Scangas and Bleier 2017) . Coffee can affect the sense of smell in COVID-19 patients, because of its caffeine content. It improves the cases but the recovery rates depend on if the cases have Captopril, Enalapril. Diltiazem, Nifedipine, Amlodipine, Felodipine, Candesartan. Azithromycin, Amikacin, Doxycycline, Ciprofloxacin, Cocaine, Cytosine, arabinoside. Levodopa, Phenytoin, Tricyclic antidepressants, Amitriptyline, Imipramine, Lithium, Nortriptyline, Clozapine. Cisplatin, Methotrexate, Vincristine. Glipizide, Insulin, Metformin, Levothyroxine. Auranofin, Colchicine, Gold, Methimazole, Corticosteroids (nasal), Propylthiouracil, β-Blockers, Fluvastatin, Interferon-α, Lovastatin, Midodrine, Pegylated, Diuretics, interferon, Terbinafine, Xylocaine (nasal), Flunisolide, Tobacco products, and smoking. any chronic disease such as hypertension, diabetes, or heart diseases-or not (Asiyeh et al. 2021 ). The recovery rate in cases without any chronic disease was higher than in cases with chronic diseases (Asiyeh et al. 2021 ). There is a large number of smell tests that have been developed, such as the Connecticut Chemosensory Clinical Research Center olfactory test (CCCRC), the University of Pennsylvania Smell Identification Test (UPSIT), and the Self-administered Computerized Olfactory Testing System (SCOTS) (Cain et al. 1983; Doty et al. 1984; Doty 2007; Jiang and Liang 2015) . We are focusing here on the first two mentioned tests because they were applied to evaluate olfactory dysfunction in COVID-19 patients. It measures the smell threshold and odor identification ability. n-Butanol is used as the test substance. The highest concentration of this substance applied in this test is 4% and the concentrations are then decreased by 3 folds for each subsequent solution of n-butanol through the rest of the containers. Every container in the test has an opening that fits for one nostril. The subject is asked to sniff from an nbutanol container and a blank container (as a control) at each time to determine which container emits a stronger odor. The threshold is determined after 4 times of the correct answer at the same concentration. The average score of both nostrils represents the total score. Then, the composite score is determined; it ranges from 0 to 50, corresponding to the scores of the threshold test (Cain et al. 1983; Vaira et al. 2020a, b) . It is composed of ten familiar odorants and ten distractors. The odorants are presented to each nostril, one at a time. The subject is asked to choose the correct odorant after smelling it. If the subject claims inability to smell an item, he/she does not have to identify it. The score scale of the odor identification (ID) test is from 1 to 10, and the composite score scale is from 0 to 50. The overall composite score (olfactory threshold composite score + odor identification composite score) is then calculated and compared to normative values (Cain et al. 1983; Vaira et al. 2020a, b) . Despite the elegant approach, the test has some disadvantages (e.g., no standardization of odorants of the identification test, inability to detect malingerers, and the test duration is relatively long (about 35 min)) (Doty 2007 ). This test is present in the form of 4 ten-page booklets, every page contains a "scratch and sniff" strip embedded with a specific microencapsulated odorant and a multiple-choice question about it. The odor can be sniffed by one or both nostrils at a time. After sniffing the odorant, the patient selects a choice related to the odor out of four alternatives per question even if the odor is not perceived. After determining the total score of the test (according to the total number of the correct answers), the score is compared with standard database scores to estimate the degree of the patient's smell function (Doty et al. 1984; Doty 2007 ). This test is not a time-consumer (it takes about 10 to15 min). Table 3 shows the standard cut-off points of the total scores of UPSIT and CCCRC test (Moein et al. 2020; Vaira et al. 2020a, b) . The prevalence of anosmia is high among COVID-19 patients and may affect the quality of their life. Anosmia associated with COVID-19 can be the only diseasepresenting symptom that puts ENT doctors in the first line of COVID-19 contact. Therefore, anosmia must be considered by health workers an indication of suspicion for empirical diagnosis of COVID-19 infection. ENT specialists recommend several approaches for treatment of COVID-19 associated anosmia including pharmacological, surgical and smell training approaches. Acknowledgement Figure 1 is created with Biorender.com. 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