DOCSLIB.ORG

Neuro-Ophthalmologic Manifestations of Paraneoplastic Syndromes

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Neuro-Ophthalmologic Manifestations of Paraneoplastic Syndromes STATE OF THE ART Neuro-Ophthalmologic Manifestations of Paraneoplastic Syndromes Melissa W. Ko, MD, Josep Dalmau, MD, PhD, and Steven L. Galetta, MD Abstract: Paraneoplastic syndromes with neuro- PARANEOPLASTIC CEREBELLAR ophthalmologic manifestations may involve the cen­ DEGENERATION tral nervous system, cranial nerves, neuromuscular Paraneoplastic cerebellar degeneration (PCD) is junction, optic nerve, uvea, or retina. Most of these a syndrome of subacute severe pancerebellar dysfunction disorders are related to immunologic mechanisms (Table 1). Initially, patients present with gait instability. presumably triggered by the neoplastic expression of Over several days to weeks, they develop truncal and limb neuronal proteins. Accurate recognition is essential to ataxia, dysarthria, and dysphagia. The cerebellar disease appropriate management. eventually stabilizes but leaves patients incapacitated. PCD is most commonly associated with cancers of (/Neuro-Ophthalmol 2008;28:58-68) the lung, ovary, and breast and with Hodgkin disease (7). Ocular motor manifestations include nystagmus, ocular dysmetria, saccadic pursuit, saccadic intrusions and he term "paraneoplastic neurologic syndrome" (PNS) oscillations, and skew deviation (8). Over the last 30 refers to dysfunction of the nervous system caused by T years, at least nine anti-neuronal antibodies have been a benign or malignant tumor via mechanisms other than associated with PCD. However, only about 50% of patients metastasis, coagulopathy, infection, or treatment side with suspected PCD test positive for anti-neuronal anti­ effects (1). Whereas reports of possible paraneoplastic bodies in serum or cerebrospinal fluid (CSF) (9). Anti-Yo neuropathies extend back to the 19th century, cerebellar syndromes associated with cancer were first described by and anti-Tr are the autoantibodies most commonly Brouwerin 1919 (2). It was not until 1938 that Brouwer and associated with a pure paraneoplastic cerebellar syndrome Biemond (3) postulated that a "toxicosis" generated by the (Table 2). PCD is pathologically characterized by severe, presence of a tumor was the cause of cerebellar de­ diffuse cerebellar Purkinje cell loss with proliferation of generation. The first description of neuro-ophthalmologic Bergmann glia and sometimes infiltrates of inflammatory manifestations of paraneoplastic disease was by Brain et al cells in the deep cerebellar nuclei. (4) in 1951, who discussed the occurrence of diplopia PCD associated with anti-Yo is usually found in without evidence of ocular paralysis as a frequent symptom postmenopausal women with breast or ovarian cancer of cerebellar degeneration. Descriptions of opsoclonus presenting at approximately 60 years of age. Peterson et al associated with cancer followed in subsequent years (5,6). (10) reported that of 55 patients positive for anti-Yo anti­ We now understand that many PNSs occur in body, all had findings of horizontal nystagmus (Table 3). association with immunologic responses against neuronal Some had downbeat nystagmus with an additional rotatory antigens expressed by the underlying cancer. Because or vertical component. Diplopia was present in approxi­ a PNS can affect any part of the nervous system, neuro- mately one third of these patients. Rare neuro-ophthalmo­ ophthalmologic abnormalities are frequent. This review logic findings included opsoclonus and progressive visual focuses on the neuro-ophthalmologic findings associated loss. Cohen et al (11) reported a patient with anti-Yo PCD with the more classical paraneoplastic disorders. who had recurrent anterior uveitis, upward gaze palsy with eyelid retraction, bilateral sixth cranial nerve palsies, and skew deviation. The initial search for a malignancy was negative. However, an update to the case reported 5 years Departments of Neurology (MWK, JD, SLG) and Ophthalmology later indicated that a poorly differentiated carcinoma, (SLG), University of Pennsylvania School of Medicine, Philadelphia, probably of breast origin, in a right axillary lymph node was Pennsylvania. found on positron emission tomography (PET) and Address correspondence to Melissa W. Ko, MD, 3 W. Gates confirmed by biopsy. This carcinoma had strong expression Building-Neurology 3400 Spruce St., Philadelphia, PA 19104; E-mail: [email protected] of Yo antigen (12). Prognosis in anti-Yo PCD is generally 58 J Neuro-Ophthalmol, Vol. 28, No. 1, 2008 Paraneoplastic Syndromes J Neuro-Ophthalmol, Vol. 28, No. 1, 2008 neuropathy (14,18,19). Autonomic dysfunction with the TABLE 1. Paraneoplastic syndromes ofneuro- development of unilateral or bilateral tonic pupils has been ophthalmologic significance reported in patients with SCLC and anti-Hu antibodies (20- Paraneoplastic encephalitides 22). Neurologic outcome is generally poor; 75% of patients Brain stem become bedridden with a median survival of 7-11 months Encephalomyelitis (14,18). Patients with PCD and SCLC who do not have Anti-Ma2 encephalitis anti-Hu antibodies often harbor VGCC antibodies. These Anti-NMDA receptor encephalitis patients may have overlapping manifestations of Lambert- Paraneoplastic cerebellar degeneration Eaton myasthenic syndrome (see below) (19,23). Opsoclonus-myoclonus For all immunologic types of PCD, CSF studies may Lambert-Eaton myasthenic syndrome show a mild lymphocytic pleocytosis with elevated protein, Paraneoplastic stiff-person syndrome oligoclonal bands, elevated immunoglobulin synthesis, and Paraneoplastic syndromes of retina and optic nerves negative cytology in approximately 60% of patients. Brain Paraneoplastic retinopathies MRI is usually normal at presentation but shows cerebellar Cancer-associated retinopathy atrophy with enlargement of the fourth ventricle and cerebral Melanoma-associated retinopathy and cerebellar sulcal prominence in advanced cases (19). Optic neuropathy Treatment is directed to the underlying malignancy, Bilteral diffuse uveal melanocytic proliferation although PCD in most patients does not improve with cancer treatment. There are only a few reported cases of NMDA, N-methyl-d-aspartate. improvement or stabilization of PCD after treatment of the neoplasm (15,24-26). Plasmapheresis or immunosuppres­ sion (cyclophosphamide or corticosteroids), sometimes used in conjunction with intravenous immunoglobulin poor, with many patients becoming non-ambulatory within (IVIg) and tumor treatment, have shown improvement in 3 months (13,14). Most patients have been reported to die several reports (27,28). A study suggested that the ofneurologic causes (10,15), butRojas etal (13) found this likelihood ofneurologic improvement after IVIg treatment to be the case in only 29%. is higher in those treated within the first month of PCD associated with Hodgkin disease is more developing cerebellar dysfunction (29,30). commonly found in men with a median age of 54 years, reflecting the bimodal age distribution of Hodgkin PARANEOPLASTIC BRAIN STEM disease—one peak occurring in young adulthood and ENCEPHALITIS a second peak occurring after age 50 (16). In addition to the Brain stem encephalitis due to paraneoplastic dis­ cerebellar symptoms of anti-Tr PCD and Hodgkin disease, ease can present with various neurologic and neuro- neuro-ophthalmologic manifestations include downbeat ophthalmologic symptoms and signs, depending on whether nystagmus, diplopia, oscillopsia, and vertigo. Bernal et al the rostral or caudal portions of the brain stem are involved. (17) reported that 2 of 28 patients with anti-Tr PCD When midbrain brain stem structures are involved, patients developed reversible encephalopathy and optic neuritis. may have ptosis, vertical gaze paresis, and nystagmus (31). The overall prognosis of anti-Tr PCD is better than that of Pontine and medullary damage can result in vertigo, hear­ anti-Yo PCD. In one review of 50 cases of PCD (14), ing loss, facial numbness, dysphagia, dysarthria, and hoars­ patients with anti-Tr PCD had a median survival from time eness. Patients may complain of diplopia and oscillopsia of diagnosis of longer than 117 months compared with with signs of vertical nystagmus, upbeat or downbeat patients with anti-Yo PCD, for whom median survival from nystagmus, horizontal gaze paresis, internuclear ophthal­ time of diagnosis was only 13 months. moplegia, skew deviation, sixth cranial nerve paresis, PCD associated with small-cell lung cancer (SCLC) impairment of facial sensation, hyperactive gag reflex or usually relates to several paraneoplastic antibodies, in­ jaw jerk, and weakness of the tongue or palatal muscles (8). cluding anti-Hu, voltage-gated calcium channel (VGCC) The antibodies frequently associated with paraneoplastic antibodies, and infrequently anti-CV2/collapsin response- brain stem encephalitis include Hu, CV2/CRMP-5, Ma-2, mediating protein-5 (CRMP-5). Patients with anti-Hu and NMDA receptor. antibodies may present with subacute cerebellar dysfunc­ tion in the seventh decade that initially resembles pure PCD in up to 20% of patients. Eventually these patients develop PARANEOPLASTIC ENCEPHALOMYELITIS additional neurologic or neuro-ophthalmologic symptoms Paraneoplastic encephalomyelitis (PEM) refers to an of brain stem or limbic encephalitis and peripheral immune-mediated inflammatory disorder that affects the 59 J Neuro-Ophthalmol, Vol. 28, No. 1, 2008 Ko et al TABLE 2. Anti-neuronal antibodies with associated tumors and paraneoplastic syndromes Antibody Associated cancer Syndrome Anti-Hu (ANNA-1) Small cell lung cancer, other Encephalomyelitis, brain stem encephalitis, paraneoplastic
Load more

Recommended publications
  • Supranuclear and Internuclear Ocular Motility Disorders
    CHAPTER 19 Supranuclear and Internuclear Ocular Motility Disorders David S. Zee and David Newman-Toker OCULAR MOTOR SYNDROMES CAUSED BY LESIONS IN OCULAR MOTOR SYNDROMES CAUSED BY LESIONS OF THE MEDULLA THE SUPERIOR COLLICULUS Wallenberg’s Syndrome (Lateral Medullary Infarction) OCULAR MOTOR SYNDROMES CAUSED BY LESIONS OF Syndrome of the Anterior Inferior Cerebellar Artery THE THALAMUS Skew Deviation and the Ocular Tilt Reaction OCULAR MOTOR ABNORMALITIES AND DISEASES OF THE OCULAR MOTOR SYNDROMES CAUSED BY LESIONS IN BASAL GANGLIA THE CEREBELLUM Parkinson’s Disease Location of Lesions and Their Manifestations Huntington’s Disease Etiologies Other Diseases of Basal Ganglia OCULAR MOTOR SYNDROMES CAUSED BY LESIONS IN OCULAR MOTOR SYNDROMES CAUSED BY LESIONS IN THE PONS THE CEREBRAL HEMISPHERES Lesions of the Internuclear System: Internuclear Acute Lesions Ophthalmoplegia Persistent Deficits Caused by Large Unilateral Lesions Lesions of the Abducens Nucleus Focal Lesions Lesions of the Paramedian Pontine Reticular Formation Ocular Motor Apraxia Combined Unilateral Conjugate Gaze Palsy and Internuclear Abnormal Eye Movements and Dementia Ophthalmoplegia (One-and-a-Half Syndrome) Ocular Motor Manifestations of Seizures Slow Saccades from Pontine Lesions Eye Movements in Stupor and Coma Saccadic Oscillations from Pontine Lesions OCULAR MOTOR DYSFUNCTION AND MULTIPLE OCULAR MOTOR SYNDROMES CAUSED BY LESIONS IN SCLEROSIS THE MESENCEPHALON OCULAR MOTOR MANIFESTATIONS OF SOME METABOLIC Sites and Manifestations of Lesions DISORDERS Neurologic Disorders that Primarily Affect the Mesencephalon EFFECTS OF DRUGS ON EYE MOVEMENTS In this chapter, we survey clinicopathologic correlations proach, although we also discuss certain metabolic, infec- for supranuclear ocular motor disorders. The presentation tious, degenerative, and inflammatory diseases in which su- follows the schema of the 1999 text by Leigh and Zee (1), pranuclear and internuclear disorders of eye movements are and the material in this chapter is intended to complement prominent.
    [Show full text]
  • Eye Movement Disorders and Neurological Symptoms in Late-Onset Inborn Errors of Metabolism Koens, Lisette H.; Tijssen, Marina A
    University of Groningen Eye movement disorders and neurological symptoms in late-onset inborn errors of metabolism Koens, Lisette H.; Tijssen, Marina A. J.; Lange, Fiete; Wolffenbuttel, Bruce H. R.; Rufa, Alessandra; Zee, David S.; de Koning, Tom J. Published in: Movement Disorders DOI: 10.1002/mds.27484 IMPORTANT NOTE: You are advised to consult the publisher's version (publisher's PDF) if you wish to cite from it. Please check the document version below. Document Version Publisher's PDF, also known as Version of record Publication date: 2018 Link to publication in University of Groningen/UMCG research database Citation for published version (APA): Koens, L. H., Tijssen, M. A. J., Lange, F., Wolffenbuttel, B. H. R., Rufa, A., Zee, D. S., & de Koning, T. J. (2018). Eye movement disorders and neurological symptoms in late-onset inborn errors of metabolism. Movement Disorders, 33(12), 1844-1856. https://doi.org/10.1002/mds.27484 Copyright Other than for strictly personal use, it is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), unless the work is under an open content license (like Creative Commons). Take-down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Downloaded from the University of Groningen/UMCG research database (Pure): http://www.rug.nl/research/portal. For technical reasons the number of authors shown on this cover page is limited to 10 maximum.
    [Show full text]
  • 2002 Samel 10 Most Common Systemic Health Conditions with A
    Avanti Samel / March 15, 2002 10 Most Common Systemic Health Conditions with a Listing of Frequently Prescribed Medications and their Ocular Side Effects HYPERTENSION ACE Inhibitors: Captopril (Capoten}- blurred vision Enalapril (Vasotec) - Blurred vision, conjunctivitis, dry eyes, tearing Quinipril (Accupril)- amblyopia Benazepril (Lotensin)- N/A Lisinopril (Zestril) - Visual loss, diplopia, blurred vision, photophobia Beta-Blockers: Propranolol (Inderal)- visual disturbances, dry eyes Atenolol (Tenormin)- blurred vision, dry eyes, visual disturbances Metoprolol (Lopressor) - blurred vision, dry eyes calcium Channel Blockers: Diltiazem (Cardizem)- Amblyopia, eye irritation Amlodipine (Norvasc)- abnormal vision, conjunctivitis, diplopia, eye pain Verapamil (Calan)- Blurred vision Nifedipine (Procardia) - blurred vision, Transient blindness at the peak of plasma level · Diuretics: Thiazides: Chlorothiazide (Diuril) - Transient blurred vision, xanthopsia Loop: Furosemide (Lasix) - Blurred vision, Xanthopsia Potassium Sparing: Amiloride (Midamor) - Visual disturbances, Increased lOP Triamterene (Dyrenium)- N/A HYPERLIPIDEMIA Statins: Lovastatin (Mevacor) - Blurred vision, Eye irritation Simvastatin (Zocor)- Cataracts Atorvastatin (Lipitor)- Amblyopia, dry eyes, refraction disorder, eye hemorrhage, glaucoma Resins: Cholestyramine (Questran)- Uveitis Fibrates: Gemfibrozil (Lopid)- Blurred vision Niacin: Niacin (Niacor) - Toxic amblyopia, cystoid macular edema ASTHMA ( ) Beta 2 Agonists: Albuterol (Proventil) - N/A ( Salmeterol (Serevent)-
    [Show full text]
  • GAZE and AUTONOMIC INNERVATION DISORDERS Eye64 (1)
    GAZE AND AUTONOMIC INNERVATION DISORDERS Eye64 (1) Gaze and Autonomic Innervation Disorders Last updated: May 9, 2019 PUPILLARY SYNDROMES ......................................................................................................................... 1 ANISOCORIA .......................................................................................................................................... 1 Benign / Non-neurologic Anisocoria ............................................................................................... 1 Ocular Parasympathetic Syndrome, Preganglionic .......................................................................... 1 Ocular Parasympathetic Syndrome, Postganglionic ........................................................................ 2 Horner Syndrome ............................................................................................................................. 2 Etiology of Horner syndrome ................................................................................................ 2 Localizing Tests .................................................................................................................... 2 Diagnosis ............................................................................................................................... 3 Flow diagram for workup of anisocoria ........................................................................................... 3 LIGHT-NEAR DISSOCIATION .................................................................................................................
    [Show full text]
  • Psychotropic Drugs and Ocular Side Effects Psikotropik İlaçlar Ve Oküler Yan Etkileri
    DOI: 10.4274/tjo.43.67944 Review / Derleme Psychotropic Drugs and Ocular Side Effects Psikotropik İlaçlar ve Oküler Yan Etkileri İpek Sönmez, Ümit Aykan* Near East University, Department of Psychiatry, Nicosia, TRNC, MD *Near East University, Department of Ophthalmology, Nicosia, TRNC Sum mary Nowadays the number of patients using the types of drugs in question here has significantly increased. A study carried out in relation with the long term use of psychotropic drugs shows that the consumption of this group of drugs has substantially increased in terms of variety and quantity. This compilation is arranged in accordance with the ocular complications of psychotropic drugs in long term treatment profile of numerous patients to the results of related literature review. If the doctor and the patients are informed about the eye problems related to the use of psychotropic drugs, potential ocular complications can be easily prevented, supervised and controlled and can even be reversed. (Turk J Ophthalmol 2013; 43: 270-7) Key Words: Psychotropic drugs, ocular, side effects, adverse effects Özet Günümüzde kronik ilaç kullanan hasta sayısı önemli derecede artmıştır. Uzun süreli psikotrop ilaç kullanımı açısından yapılan bir çalışma, hem çeşitlilik hem de miktar açısından bu grup ilaç tüketiminin önemli derecede arttığını göstermektedir. Bu derleme günümüzde çok sayıda hastanın uzun süreli tedavi profilinde yer alan psikotrop ilaçların oküler komplikasyonlarına ilişkin literatür taraması sonucu hazırlanmıştır. Hekim ve hastalar psikotrop ilaç kullanımına bağlı göz problemleri açısından bilgili oldukları takdirde potansiyel oküler komplikasyonlar kolayca önlenebilir, gözlem ve kontrol altına alınabilir ve hatta geriye döndürülebilirler. (Turk J Ophthalmol 2013; 43: 270-7) Anah tar Ke li me ler: Psikotropik ilaç, oküler, yan etki, ters etki Introduction human eye becoming sensitive to psychotropic treatments.
    [Show full text]
  • Chlorpromazine (Thorazine)? Thioridazine (Mellaril) Tamoxifen
    1 Q Systemic drugs and ocular toxicity: Matching Chlorpromazine (Thorazine)? Blue tinting of vision Retinopathy rare at Thioridazine (Mellaril) doses <800 mg/d Tamoxifen Blair Witch cataract Iritis, hypotony can Sildenafil (Viagra) develop Cidofovir Causes a crystalline retinopathy Isotretinoin (Accutane) Causes nyctalopia Rifabutin Yellow tinting of vision Digitalis Causes uveitis with hypopyon (Start with chlorpromazine and work down the list) 2 A Systemic drugs and retinalocular toxicity: Matching Chlorpromazine (Thorazine) Blue tinting of vision Retinopathy rare at Thioridazine (Mellaril) doses <800 mg/d Tamoxifen Blair Witch cataract Iritis, hypotony can Sildenafil (Viagra) develop Cidofovir Causes a crystalline retinopathy Isotretinoin (Accutane) Causes nyctalopia Rifabutin Yellow tinting of vision Digitalis Causes uveitis with hypopyon 3 Systemic drugs and ocular toxicity: Matching Chlorpromazine: Blair Witch cataract 4 Q Systemic drugs and retinalocular toxicity: Matching Chlorpromazine (Thorazine) Blue tinting of vision Retinopathy rare at ThioridazineWhat class of medicine (isMellaril chlorpromazine?) It is a phenothiazine doses <800 mg/d TamoxifenWhat sort of med are phenothiazines? Blair Witch cataract They are neuroleptics (but have other uses as well) Iritis, hypotony can Sildenafil (Viagra) In addition to cataracts, what ophthalmic effects does develop high-dose chlorpromazine therapy have? CidofovirIt causes pigmentation of the lids and conj Causes a crystalline retinopathy IsotretinoinWhat
    [Show full text]
  • Successful Treatment of Tardive Oculogyric Crisis with Bornaprine
    Isr J Psychiatry - Vol. 56 - No 3 (2019) Şengül KOCamer ŞAHIN ET AL. Successful Treatment of Tardive Oculogyric Crisis with Bornaprine Şengül Kocamer Şahin, MD,1 Ayşegül Şahin Ekici, MD,1 Gulcin Elboga, MD,1 Abdurrahman Altindag, MD,1 and Atil Bisgin, MD2 1 Department of Psychiatry, Faculty of Medicine, Gaziantep University, Gaziantep, Turkey 2 Adana Genetics Diseases Diagnosis and Treatment Center and Medical Genetics Department of the Medical Faculty, Cukurova University, Adana, Turkey The presentation is a specific dystonic reaction. Recurrent ABSTRACT oculogyric crisis is different from the acute adverse drug event (4). It has been variously considered to be a form Tardive oculogyric crisis is one of the tardive syndromes of tardive dyskinesia (4). characterized by a spasmodic deviation of eyes typically Antipsychotic discontinuation is still the primary turning upwards after long-term use of high-potency suggestion regarding the management of tardive syn- typical or rarely atypical antipsychotics. Antipsychotic dromes, although no definitive evidence is supported. discontinuation is suggested as a treatment option with If this is not possible, changing to an antipsychotic with changing to an antipsychotic with a lower tardive dystonia a lower tardive dystonia (TDt) risk is the next option risk. Anticholinergic drugs such as trihexyphenidyl may (5). Antidyskinetic agents may be added to treatment also improve the symptoms of tardive dystonia, but these in patients whose symptoms persist despite drug regula- drugs may trigger or aggravate tardive dyskinesia. We tion. Antioxidants that reduce free oxygen radicals such report on a case with tardive syndromes and treatment as Ginkgo biloba, vitamin E, vitamin B6, clonazepam, challenge.
    [Show full text]
  • Scientific Programme
    Scientific programme The times mentioned below are Paris time FRIDAY 23rd APRIL 10.00 - 12.00 Orthoptic Education Forum 14.00 - 16.00 Interactive Strabismus Workshop SATURDAY 24th APRIL 08.30 - 09.00 Opening Ceremony 09.00 - 10.30 Free papers - Strabismus Surgery and Botulinum Toxin o Periosteal fixation of medial and lateral recti for large angle incomitant exotropia Gill Adams o Overcorrection after vertical muscle transposition with augmentation sutures in sixth nerve palsy Dina Hassanein o Strabismus surgery in patients with prior vitreoretinal surgery - strategies and results Jon Peiter Saunte o Double Y-splitting for Duane Syndrome with severe elevation on adduction Alain Spielmann o Robot-assisted simulated strabismus surgery Claude Speeg-Schatz o Axial length in strabismus surgery Hector Jimenez-Ortiz o Strabismus outcomes after surgery in France Quentin Colas o Treatment of strabismus using Bupivacaine & Botulinum Type A Toxin in patients who had prior unsuccessful surgical attempts Talita Cunha Namgalies o Bupivicaine Injection versus mini-Tenotomy for small angle horizontal strabismus in children Hala El Hilali 10.30 - 10.35 Introduction of Bielschovsky Lecturer Stephen Kraft - Hospital for Sick Children, Toronto, Canada 10.35 - 11.05 Bielschovsky Lecture - Nexus of Strabismus, Myopia and Glaucoma Joseph L. Demer - Stein Eye Institute, UCLA, Los Angeles, USA 11.35 - 12.35 Symposium Strabismus in High Myopia Update on Strabismus Surgery in High Myopia Tsuranu Yokoyama - Osaka City General Hospital Children's Medical Center,
    [Show full text]
  • Benign Paroxysmal Positional Vertigo David Solomon, MD, Phd
    Benign Paroxysmal Positional Vertigo David Solomon, MD, PhD Address Department of Neurology, University of Pennsylvania, 3 W. Gates Building, 3400 Spruce Street, Philadelphia, PA 19104-4283, USA. Email: [email protected] Current Treatment Options in Neurology 2000, 2:417–427 Current Science Inc. ISSN 1092-8480 Copyright © 2000 by Current Science Inc. Opinion statement Benign paroxysmal positional vertigo can be diagnosed with great certainty, and treated effectively at the bedside using one of the canalith repositioning procedures described in this paper. This treatment has been shown effective in properly controlled trials, has a rational basis, and has minimal risk [1]. Introduction Benign paroxysmal positional vertigo (BPPV) is the most rior SCC [7]. Convincing evidence [8, Class I] in support common diagnosis made in many specialty clinics serv- of canalithiasis as a pathophysiologic explanation for ing patients with dizziness. This diagnosis is suggested by BPPV validates treatment with any procedure that can a history of brief (less than one minute) episodes of ver- effectively clear these dense particles from the posterior tigo that are provoked by rolling over in bed, lying down, semicircular canal. Canalithiasis can occur in any canal. sitting up from a supine position, bending over, or look- The posterior semicircular canal (PSC) was affected in the ing up. BPPV commonly is worse in the early morning majority of cases of BPPV (93% of cases) [9], with 85% (matutinal vertigo), and may be absent for weeks or being unilateral, and 8% affecting the PSC on both sides. months at a time before returning. Diagnosis rests on the The horizontal semicircular canal (HSC) was affected in observation of characteristic eye movements accompany- 5% of cases.
    [Show full text]
  • Ophthalmic Manifestations of Acute Leukaemias T Sharma Et Al 664
    Eye (2004) 18, 663–672 & 2004 Nature Publishing Group All rights reserved 0950-222X/04 $30.00 www.nature.com/eye 1 1 2 1 Ophthalmic T Sharma , J Grewal , S Gupta and PI Murray REVIEW manifestations of acute leukaemias: the ophthalmologist’s role Abstract neoplastic cells. Ophthalmic involvement can be classified into two major categories: (1) primary With evolving diagnostic and therapeutic or direct leukaemic infiltration, (2) secondary or advances, the survival of patients with acute indirect involvement. The direct leukaemic leukaemia has considerably improved. This infiltration can show three patterns: anterior has led to an increase in the variability of segment uveal infiltration, orbital infiltration, ocular presentations in the form of side effects and neuro-ophthalmic signs of central nervous of the treatment and the ways leukaemic system leukaemia that include optic nerve relapses are being first identified as an ocular infiltration, cranial nerve palsies, and presentation. Leukaemia may involve many papilloedema. The secondary changes are the ocular tissues either by direct infiltration, result of haematological abnormalities of haemorrhage, ischaemia, or toxicity due to leukaemia such as anaemia, thrombocytopenia, various chemotherapeutic agents. Ocular hyperviscosity, and immunosuppression. These involvement may also be seen in graft-versus- can manifest as retinal or vitreous haemorrhage, host reaction in patients undergoing infections, and as vascular occlusions. In some allogeneic bone marrow transplantation, or cases the ocular involvement may be simply as increased susceptibility to infections asymptomatic. In one prospective study, there as a result of immunosuppression that these was a high prevalence of asymptomatic ocular 1 patients undergo. This can range from simple Birmingham and Midland lesions in childhood acute leukaemia.1 In the era bacterial conjunctivitis to an endophthalmitis.
    [Show full text]
  • Evidence Tables
    6/9/2020 Evidence Tables Core A and Core B Lauren Koen, BSN, RN, MPA KATHY AUBERRY, DNP, RN, CDDN TABLE OF CONTENTS GENERAL CORE TRAINING EVIDENCE TABLES _____________________________________________________________________ 2 Evidence Table A: Scope and Significance of Health Issue/ Priority Group ______________________________________________________ 2 Evidence Table B: Training Methods/ Current Material _____________________________________________________________________ 3 CORE A EVIDENCE TABLES ____________________________________________________________________________________ 6 Evidence Table C: Universal Precautions, Inflammation, and Infection ________________________________________________________ 6 Evidence Table D: Vital Signs and Emergencies ___________________________________________________________________________ 9 Evidence Table E: Fatal Four and Sepsis ________________________________________________________________________________ 11 Evidence Table F: Developmental Disabilities and Dementia _______________________________________________________________ 15 Evidence Table G: Direct Support Professional Roles and Responsibilities _____________________________________________________ 19 Core B Evidence Tables ______________________________________________________________________________________ 22 Evidence Table H: Fundamentals for Pharmacology ______________________________________________________________________ 22 Evidence Table I: Rights and Documentation ____________________________________________________________________________
    [Show full text]
  • Eye Movements and Vestibular Function in Critical Care, Emergency, and Ambulatory Neurology (Level 2)
    5th Congress of the European Academy of Neurology Oslo, Norway, June 29 - July 2, 2019 Teaching Course 15 Eye movements and vestibular function in critical care, emergency, and ambulatory neurology (Level 2) Eye movements and vestibular function in critical care and emergency neurology Alexander Tarnutzer Baden, Switzerland Email: [email protected] 1 Eye movements and vestibular function in critical care and emergency neurology 5th EAN Congress Oslo, Norway June 29 - July 2, 2019 TC 15, July 2nd 2019 PD Dr. med. Alexander Tarnutzer Senior leading physician Neurology Cantonal Hospital of Baden Switzerland [email protected] 1 Disclosures ▪ Royalties from books (Oxford University Press, Verlagshaus der Aerzte). ▪ I do not have any financial interest in commercial products presented in this talk. ▪ I do not have any stock holdings in commercial products presented in this talk. 2 2 Topics covered Focused clinical examination of eye movements and vestibular function at the bedside → which key tests to obtain? ▪ Neuro-otological assessment of the comatouse patient in the ICU → how to get the maximum out of a limited examination. Differential diagnosis of eye movement abnormalities in the ED / ICU setting. 3 Bedside clinical neuro-otological examination in the ED / ICU 4 3 Principal types of eye movements ➢ Smooth pursuit eye movements → following a moving target ➢ Saccadic eye movements → shifting gaze ➢ Vestibulo-ocular reflex (VOR) → stabilizing gaze despite moving Nystagmus (spontaneous, gaze-dependent, optokinetic etc...) → stabilize gaze ➢ Vergence eye movements → binocular control Ramboldt et al. 2004 5 Key domains to assess at the bedside ▪ Ocular stability for (I) nystagmus and (II) skew deviation & gaze deviation ▪ (III) the head-impulse test ▪ (IV) postural stability (including malleolar vibration sense) ▪ (V) ocular motor deficits (of saccades, smooth pursuit eye movements and optokinetic nystagmus).
    [Show full text]