DOCSLIB.ORG

CLINICAL IMPLICATIONS of NASAL SEPTAL DEFORMITIES Ranko

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
CLINICAL IMPLICATIONS of NASAL SEPTAL DEFORMITIES Ranko CLINICAL IMPLICATIONS OF NASAL SEPTAL DEFORMITIES Ranko Mladina, MD, PhD, Professor Department of ORL Head & Neck Surgery Clinical Hospital Center Zagreb, Croatia Head, Referral Center for Rhinosinusology and Endoscopic Sinus Surgery Ministry of Health, Republic of Croatia 1 1 SEPTAL DEFORMITIES Type1 Type2 2 These two types od so called VERTICAL DEFORMITIES are located in the close vicinity of the anterior nasal valve (limen nasi in Latin) thus diminishing more or less the normal value of the anterior nasal valve angle (the angle between septum and limen nasi, see next slide) from 150 to less. In these very slide both deformities are to the left, just by chance. It does not meter which side is occupied by these types of deformities. They are always either type 1 or type 2. What really meters is that both of these two deformities have great implications on both subjective feeling of nasal breathing quality and rhinomanometric, acoustic rhinometric and body pletizmography findings. They also have a strong influence on the so called nasothoracal reflex, responsible for the real depth of nasopulmonary breathing. How it works? In the region of the anterior nasal valve there are a lot of neural buds belonging to the ophthalmic nerve (nasociliary nerve branches), and maxillary nerve (nasopalatine nerve branches), which are normally agitated by the air stream passing through the nose at the circumstances of anterior nasal valve angle of 150. If the aerodynamic circumstances are changed, and they are changed in cases of both type 1 and type 2 septal deformities, the buds belonging to nasopalatine and nasociliary nerves will not be agitated and no action potential will be forwarded towards the nuclea of the trigeminal nerve in medulla oblongata. In normal conditions, an ordinary action potential comes to nuclea, and owing to the anastomoses with the vagal nerve and its cervical plexus, the electric potential spreads towards the phrenic nerve nucleus, thus producing a strong contraction of the diaphragm. This ensures a long, deep inspirium which can be easily recorded during the body pletizmography measurements. Interesting story, isn’t it? 2 SEPTAL DEFORMITIES IMPAIRED NASAL BREATHING Type 1 150 3 There is an elastic membrane (red arrow) between the caudal edge of the triangular cartilage (dark blue arrow) which allows the movements of triangular cartilage towards the nasal septum during the nasal inspirium and vice versa during the expirium. 3 NASOPULMONARY REFLEX 4 The diaphragm is a large, strong muscle. When relaxed, it is convex with the arch upwards (blue arch in this picture). When contracted, it becomes horizontal, streched, thus enlarging the capacity of the thoracic cavity, producing the negative pressure and promoting the deep inspirium. 4 NASOPULMONARY REFLEX 5 The diaphragm has been contracted by the action of the phrenic nerve (yellow dotted line), supported by the action potential coming also from the anterior valve region from the nerve buds of nasopalatine (ophthalmic nerve branches) and nasocilliary (maxillary nerve branches) nerves 5 NASOPULMONARY REFLEX 6 6 SEPTAL DEFORMITIES Type 2 Branches of the nasociliary n. (V1) Branches of the nasopalatine nerve (V2) Trigeminal nucleus (medula oblongata) “-150” Anastomoses to the vagal nerve and CERVICAL PLEXUS (PHRENIC NERVE) AGITATION OF THE DIAPHRAGM CONTRACTION NASO-THORACIC REFLEX IMPAIRED NASAL BREATHING IMPAIRED PULMONARY BREATHING 7 Septal deformity type 2 sometimes is so emphasized that literally pushes limen nasi laterally. It sometimes can be seen even from outside as a deformity of the nasal apex. We use to say that the desired, physiological value of the anterior nasal , valve angle is not any longer fifteen but minus fifteen degrees! 7 SEPTAL DEFORMITIES Type3 C - shaped 8 This deformity is also unilateral as are previous two, but contrary to both of them, this one is located more posterior, i.e. At the borderline between cartilaginous and osseous part of the nasal septum (quadrangular lamina and perpendicular lamina). It belongs also to so called VERTICAL DEFORMITIES.The most prominent point of its convexity stays usually very close to the head of the middle turbinate or obstructs the view to the ostiomeatal complex (see slide No. 10). 8 SEPTAL DEFORMITIES Type3 Reverse C - shaped 9 9 SEPTAL DEFORMITIES Type 3 10 10 SEPTAL DEFORMITIES Type 3 S MT 11 On CT scans it is normal to see that the middle turbinate at the deformity side is thinned, whereas on the opposite side, because the nasal cavity is enormously wide, middle turbinate in rule is pneumatized (so called compensatory hypertrophy). You can see one example in the middle picture of this slide. Both arrows indicate the mucosal edema that can be usually find in this type of septal deformities as a result of constant irritation by “wrong” air-stream. What does it mean? It means that at the narrower side, owing to the well known Bernoulli’s rule from aerodynamic science, the speed of the airstream must be accelerated as to be able to reach the target (nasopharynx) in the same moment as the air- stream from the other nasal cavity does. Because of that, the air-stream in the narrow side reaches hurricane speeds and, as a side effect, erases the highly differentiated respiratory epithelium resulting in the onset of a simple multilayer, squamous cell epithelium (see slide No. 13). Ostiomeatal complex is seriously impaired! On the other, wider side, the air-stream speeds are not that high, of course, but they are, instead of being laminar, smooth, very confused, in rule turbulent, and the result on the respiratory epithelium is the same as at the opposite side. That means that in this type of septal deformity one can expect to have bilateral impairment of the mucociliary transport in the ostiomeatal region. In other words, the essential prerequisites for the onset of chronic rhinosinusitis are here! 11 THE TYPES OF SEPTAL DEFORMITIES: WORLDWIDE DISTRIBUTION explored by native anterior rhinoscopy solely Type 33 20.36% Type 1 & 2 16.30% Type 5 13.98% Straight septum 10.81% N= 2589 (14 countries involved in the study) 12 Based on the native anterior rhinoscopy, which means without the decongestion, it seems that the type 3 is quite largely spread all over the world. Maybe it can be considered as a “stigma” of the man kind septum. We believe that this type has to do with the inheritance or, most probably, with the action of so called “cranial pincers”, in other words by the squeezing of the splanchocranium by both anterior and posterior skull base, so typical angulations (Huxley’s angle of 1350) in adult humans. This angle does not exist in quadrupeds (that is why they do not have a sphenoid sinus!), nor it can be found in human newborns and small children until the age of approximately seven. This supports the theory that the human ontogenesis is just a short recapitulation of the whole phylogenesis! Anyhow, type 3 is very frequently seen in chronic rhinosinusitis patients! 12 SEPTAL DEFORMITIES Type 3 S MT 13 Please read the notes of the slide No. 11 13 SEPTAL DEFORMITIES: CLINICAL IMPLICATIONS Chronic rhinosinusitis Type 3 Bilaterally impaired nasal breathing Headache 14 Because in most of the type 3 cases there is a close contact between two neighboring surfaces, i.e. The surface of the head of the middle turbinate and the surface of nasal septum (deformed at this side), a lot of action potentials are released from this area to the central nervous system (CNS) alarming it for the pain. Of course, it is not possible to know where exactly the pain comes from, patient does not come to the doctor saying: “Doctor, my middle turbinate is so painful!”, but comes complaining of the stubborn headache. If the headache has it origin in this region, the doctor will be able to immediately stop the pain by inserting in the ostiomeatal region a small cotton ball previously immersed in the xillocaine solution. In very many cases it works perfect! And makes a very clear indication for the septal surgery in particular patient! 14 SEPTAL DEFORMITIES Type4 15 Here we have two vertical deformities in one nose, i.e. Type 1 or 2 on one side, and type 3 on the opposite side. Depending on which one is most anterior, the schematic shape of nasal septum, as looking from above, gives an impression of the letter “S” or letter “Z”. This deformity on this slide has the “S” shape since the anterior deformity (type 2) looks to the left side. 15 SEPTAL DEFORMITIES Type 4 Chronic rhinosinusitis, bilaterally impaired nasal breathing, headache 16 Typical axial CT appearance of the type 4. Please note the mucosal thickening of the ethmoid on the side of the type 3 septal deformity (yellow arrow) 16 SEPTAL DEFORMITIES Type 5 >98% OF FATHERS or/and MOTHERS 17 It usually goes for an ascending, almost horizontal septal spur, but always unilateral! In very many patients the opposite side of the septum could be almost ideally straight! In this very case you can easily see even by anterior rhinoscopy (after the decongestion, of course) the left superior turbinate (red arrow)! You can also see that left middle turbinate has a so called paradoxical shape, i.e. it is convex towards the lateral nasal wall. A discrete signs of the type 3 can be seen on this side of the nasal septum. Contrary to that, the horizontal deformity is nicely seen. You can imagine how large contact between the tip of this spur in the deep nasal areas (Cottle region 4 and 5) could be, particularly when the nasal cycle produces the predominance of the parasympathetic influence. In this very moment, since the changes between two neurovegetative (sympathetic and parasympathetic) components alternate very quickly, starts the typical, unilateral (all the times the same side!) headache.
Load more

Recommended publications
  • Palatal Injection Does Not Block the Superior Alveolar Nerve Trunks: Correcting an Error Regarding the Innervation of the Maxillary Teeth
    Open Access Review Article DOI: 10.7759/cureus.2120 Palatal Injection does not Block the Superior Alveolar Nerve Trunks: Correcting an Error Regarding the Innervation of the Maxillary Teeth Joe Iwanaga 1 , R. Shane Tubbs 2 1. Seattle Science Foundation 2. Neurosurgery, Seattle Science Foundation Corresponding author: Joe Iwanaga, [email protected] Abstract The superior alveolar nerves course lateral to the maxillary sinus and the greater palatine nerve travels through the hard palate. This difficult three-dimensional anatomy has led some dentists and oral surgeons to a critical misunderstanding in developing the anterior and middle superior alveolar (AMSA) nerve block and the palatal approach anterior superior alveolar (P-ASA) nerve block. In this review, the anatomy of the posterior, middle and anterior superior alveolar nerves, greater palatine nerve, and nasopalatine nerve are revisited in order to clarify the anatomy of these blocks so that the perpetuated anatomical misunderstanding is rectified. We conclude that the AMSA and P-ASA nerve blockades, as currently described, are not based on accurate anatomy. Categories: Anesthesiology, Medical Education, Other Keywords: anatomy, innervation, local anesthesia, maxillary nerve, nerve block, tooth Introduction And Background Anesthetic blockade of the posterior superior alveolar (PSA) branch of the maxillary nerve has played an important role in the endodontic treatment of irreversible acute pulpitis of the upper molar teeth except for the mesiobuccal root of the first molar tooth [1, 2]. This procedure requires precise anatomical knowledge of the pterygopalatine fossa and related structures in order to avoid unnecessary complications and to make the blockade most effective. The infraorbital nerve gives rise to middle superior alveolar (MSA) and anterior superior alveolar (ASA) branches.
    [Show full text]
  • Maxillary Nerve-Mediated Postseptoplasty Nasal Allodynia: a Case Report
    E CASE REPORT Maxillary Nerve-Mediated Postseptoplasty Nasal Allodynia: A Case Report Shikha Sharma, MD, PhD,* Wilson Ly, MD, PharmD,* and Xiaobing Yu, MD*† Endoscopic nasal septoplasty is a commonly performed otolaryngology procedure, not known to cause persistent postsurgical pain or hypersensitivity. Here, we discuss a unique case of persis- tent nasal pain that developed after a primary endoscopic septoplasty, which then progressed to marked mechanical and thermal allodynia following a revision septoplasty. Pain symptoms were found to be mediated by the maxillary division of the trigeminal nerve and resolved after percuta- neous radiofrequency ablation (RFA) of bilateral maxillary nerves. To the best of our knowledge, this is the first report of maxillary nerve–mediated nasal allodynia after septoplasty. (A&A Practice. 2020;14:e01356.) GLOSSARY CT = computed tomography; FR = foramen rotundum; HIPAA = Health Insurance Portability and Accountability Act; ION = infraorbital nerve; LPP = lateral pterygoid plate; MRI = magnetic reso- nance imaging; RFA = radiofrequency ablation; SPG = sphenopalatine ganglion; US = ultrasound ndoscopic nasal septoplasty is a common otolaryn- septoplasty for chronic nasal obstruction with resection of gology procedure with rare incidence of postsurgical the cartilage inferiorly and posteriorly in 2010. Before this Ecomplications. Minor complications include epistaxis, surgery, the patient only occasionally experienced mild septal hematoma, septal perforation, cerebrospinal fluid leak, headaches. However, his postoperative course was compli- and persistent obstruction.1 Numbness or hypoesthesia of the cated by significant pain requiring high-dose opioids. After anterior palate, secondary to injury to the nasopalatine nerve, discharge, patient continued to have persistent deep, “ach- has been reported, but is usually rare and temporary, resolv- ing” nasal pain which radiated toward bilateral forehead ing over weeks to months.2 Acute postoperative pain is also and incisors.
    [Show full text]
  • Local Anaesthesia for Descriptive Purposes It Is Convenient to Sub-Divide Local Anaesthesia on an Anatomical Basis Into Topical, Infiltration, and Regional Techniques
    Fundamentals of technique The importance of a quiet, confident, and friendly manner towards all patients so physical comfort is also essential for the co-operation of the patient and the ease of operation of the dental surgeon. The patient should be seated in a semi-reclining position with the back and legs supported and with head rest in the nape of the neck. Most adult patients will respond to the dental surgeon's endeavors to gain the patient his or her confidence and so premedication will not be required for the administration of a local anaesthetic for a relatively simple procedure. Types of local anaesthesia For descriptive purposes it is convenient to sub-divide local anaesthesia on an anatomical basis into topical, infiltration, and regional techniques. Topical or surface anaesthesia: is obtained by the application of a suitable anaesthetic agents to an area of either skin or mucous membrane which it penetrates to anaesthetize superficial nerve-ending. It is most commonly used to obtain anaesthesia of mucosa prior to injection. Spray: containing an appropriate local anaesthetic agent are particularly suitable for this purpose because of their rapidity of action. The active ingredient is 10% lignocaine hydrochloride. When used as a spray it is very easy to spread the solution, and its effect, much more extensively than is desired. The onset time of anaesthesia is about 1 minute and the duration round about 10 minute. Ethyl chloride: when sprayed on skin or mucosa volatilizes to rapidly produces anaesthesia by refrigeration. This phenomenon is of clinical value only when spray directed at a limited area until snow appears.\This technique is of limited value is occasionally used to produce surface anaesthesia prior to incision of a fluctuant abscesses.
    [Show full text]
  • Anatomy Respect in Implant Dentistry. Assortment, Location, Clinical Importance (Review Article)
    ISSN: 2394-8418 DOI: https://doi.org/10.17352/jdps CLINICAL GROUP Received: 19 August, 2020 Review Article Accepted: 31 August, 2020 Published: 01 September, 2020 *Corresponding author: Dr. Rawaa Y Al-Rawee, BDS, Anatomy Respect in Implant M Sc OS, MOMS MFDS RCPS Glasgow, PhD, MaxFacs, Department of Oral and Maxillofacial Surgery, Al-Salam Dentistry. Assortment, Teaching Hospital, Mosul, Iraq, Tel: 009647726438648; E-mail: Location, Clinical Importance ORCID: https://orcid.org/0000-0003-2554-1121 Keywords: Anatomical structures; Dental implants; (Review Article) Basic implant protocol; Success criteria; Clinical anatomy Rawaa Y Al-Rawee1* and Mohammed Mikdad Abdalfattah2 https://www.peertechz.com 1Department of Oral and Maxillofacial Surgery, Al-Salam Teaching Hospital. Mosul, Iraq 2Post Graduate Student in School of Dentistry, University of Leeds. United Kingdom, Ministry of Health, Iraq Abstract Aims: In this article; we will reviews critically important basic structures routinely encountered in implant therapy. It can be a brief anatomical reference for beginners in the fi eld of dental implant surgeries. Highlighting the clinical importance of each anatomical structure can be benefi cial for fast informations refreshing. Also it can be used as clinical anatomical guide for implantologist and professionals in advanced surgical procedures. Background: Basic anatomy understanding prior to implant therapy; it's an important fi rst step in dental implant surgery protocol specifi cally with technology advances and the popularity of dental implantation as a primary choice for replacement loosed teeth. A thorough perception of anatomy provides the implant surgeon with the confi dence to deal with hard or soft tissues in efforts to restore the exact aim of implantation whether function or esthetics and end with improving health and quality of life.
    [Show full text]
  • How to Cite Complete Issue More Information About This Article
    Revista Cubana de Estomatología ISSN: 0034-7507 ISSN: 1561-297X [email protected] Centro Nacional de Información de Ciencias Médicas Cuba Gomes Torres, Marianna Guanaes; Valverde, Ludmila de Faro; Andion Vidal, Manuela Torres; Crusoé-Rebello, Iêda Margarida Trifid nasopalatine canal: case report of a rare anatomical variation and its surgical implications Revista Cubana de Estomatología, vol. 53, no. 2, 2016, pp. 67-70 Centro Nacional de Información de Ciencias Médicas Cuba Available in: https://www.redalyc.org/articulo.oa?id=378663128007 How to cite Complete issue Scientific Information System Redalyc More information about this article Network of Scientific Journals from Latin America and the Caribbean, Spain and Journal's webpage in redalyc.org Portugal Project academic non-profit, developed under the open access initiative Rev Cubana Estomatol. 2016;53(2) Órgano Oficial de la Sociedad Cubana de Estomatología ISSN-1561-297X PRESENTACIÓN DE CASO Trifid nasopalatine canal: case report of a rare anatomical variation and its surgical implications Conducto nasopalatino Trifid: presentación de caso de una variación anatómica rara y sus implicaciones quirúrgicas Marianna Guanaes Gomes Torres,I Ludmila de Faro Valverde,II Manuela Torres Andion Vidal,II Iêda Margarida Crusoé-RebelloI I Department of Oral Radiology, School of Dentistry. Federal University of Bahia, Salvador, BA, Brazil. II Gonçalo Moniz Research Center, Oswaldo Cruz Foundation, Salvador, Bahia, Brazil. ABSTRACT The nasopalatine canal is a long slender structure present in the midline of the anterior maxilla that connects the palate to the floor of the nasal cavity. The nasopalatine canal contains the nasopalatine nerve, the terminal branch of the nasopalatine artery, fibrous connective tissue, adipose tissue, and minor salivary glands.
    [Show full text]
  • A Review of the Mandibular and Maxillary Nerve Supplies and Their Clinical Relevance
    AOB-2674; No. of Pages 12 a r c h i v e s o f o r a l b i o l o g y x x x ( 2 0 1 1 ) x x x – x x x Available online at www.sciencedirect.com journal homepage: http://www.elsevier.com/locate/aob Review A review of the mandibular and maxillary nerve supplies and their clinical relevance L.F. Rodella *, B. Buffoli, M. Labanca, R. Rezzani Division of Human Anatomy, Department of Biomedical Sciences and Biotechnologies, University of Brescia, V.le Europa 11, 25123 Brescia, Italy a r t i c l e i n f o a b s t r a c t Article history: Mandibular and maxillary nerve supplies are described in most anatomy textbooks. Accepted 20 September 2011 Nevertheless, several anatomical variations can be found and some of them are clinically relevant. Keywords: Several studies have described the anatomical variations of the branching pattern of the trigeminal nerve in great detail. The aim of this review is to collect data from the literature Mandibular nerve and gives a detailed description of the innervation of the mandible and maxilla. Maxillary nerve We carried out a search of studies published in PubMed up to 2011, including clinical, Anatomical variations anatomical and radiological studies. This paper gives an overview of the main anatomical variations of the maxillary and mandibular nerve supplies, describing the anatomical variations that should be considered by the clinicians to understand pathological situations better and to avoid complications associated with anaesthesia and surgical procedures. # 2011 Elsevier Ltd.
    [Show full text]
  • NASAL ANATOMY Elena Rizzo Riera R1 ORL HUSE NASAL ANATOMY
    NASAL ANATOMY Elena Rizzo Riera R1 ORL HUSE NASAL ANATOMY The nose is a highly contoured pyramidal structure situated centrally in the face and it is composed by: ü Skin ü Mucosa ü Bone ü Cartilage ü Supporting tissue Topographic analysis 1. EXTERNAL NASAL ANATOMY § Skin § Soft tissue § Muscles § Blood vessels § Nerves ² Understanding variations in skin thickness is an essential aspect of reconstructive nasal surgery. ² Familiarity with blood supplyà local flaps. Individuality SKIN Aesthetic regions Thinner Thicker Ø Dorsum Ø Radix Ø Nostril margins Ø Nasal tip Ø Columella Ø Alae Surgical implications Surgical elevation of the nasal skin should be done in the plane just superficial to the underlying bony and cartilaginous nasal skeleton to prevent injury to the blood supply and to the nasal muscles. Excessive damage to the nasal muscles causes unwanted immobility of the nose during facial expression, so called mummified nose. SUBCUTANEOUS LAYER § Superficial fatty panniculus Adipose tissue and vertical fibres between deep dermis and fibromuscular layer. § Fibromuscular layer Nasal musculature and nasal SMAS § Deep fatty layer Contains the major superficial blood vessels and nerves. No fibrous fibres. § Periosteum/ perichondrium Provide nutrient blood flow to the nasal bones and cartilage MUSCLES § Greatest concentration of musclesàjunction of upper lateral and alar cartilages (muscular dilation and stenting of nasal valve). § Innervation: zygomaticotemporal branch of the facial nerve § Elevator muscles § Depressor muscles § Compressor
    [Show full text]
  • Maxillary Nerve Variations and Its Clinical Significance
    Sai Pavithra .R et al /J. Pharm. Sci. & Res. Vol. 6(4), 2014, 203-205 Maxillary Nerve Variations and Its Clinical Significance Sai Pavithra .R,Thenmozhi M.S Department of Anatomy, Saveetha Dental College Tamil nadu. Abstract: The aim of this review is to collect data from the literature and gives a detailed description of the innervation of the maxilla. We carried out a search of studies published in PubMed up to 2011, including clinical and anatomical studies .several articles has has been published regarding the anatomical variations of the maxillary nerve supplies. The purpose of this paper is to demonstrate the variation in the paths and communications of the maxillary nerve which should be considered by the clinicians as nerve supply,assumed prime importance to oral surgeons to understand better and to avoid complications associated with anaesthesia and surgical procedures. Key words: maxillary nerve, clinical variations THE MAXILLARY NERVE: foramen is usually a single foramen but several studies 1. Anatomical variations of the maxillary nerve supply. have proven to have two or three foramen[2-8]. A low 2. Anatomical variations of the infraorbital nerve. percentage (4.7%) was observed during a study on 3. Anatomical variations of the superior alveolar nerve 1064 skulls, with a higher frequency on the left side, 4.Anatomical variations of the greaterpalatine nerve. both in male and in female skulls[9]. The distance from 5. Anatomical variations of the nasopalatine nerve. the infraorbital foramen to the inferior border of the [10-13] orbital rim is from 4.6 to 10.4 mm . AXILLARY NERVE: Since the infraorbital nerve block is often used to The maxillary nerve is a sensory nerve.
    [Show full text]
  • Lecture 7 Anatomy the PTERYGOPALATINE FOSSA
    د.احمد فاضل القيسي Lecture 7 Anatomy THE PTERYGOPALATINE FOSSA The pterygopalatine fossa lies beneath the posterior surface of the maxilla and the pterygoid process of the sphenoid bone. The pterygopalatine fossa contains the maxillary nerve, the maxillary artery (third part) and the pterygopalatine parasympathetic ganglion. Boundaries Anteriorly: posterior surface of maxilla. Posteriorly: anterior margin of pterygoid process below and greater wing of sphenoid above. Medially: perpendicular plate of palatine bone. Superiorly: greater wing of sphenoid. Laterally: communicates with infratemporal fossa through pterygomaxillary fissure Communications and openings: 1. The pterygomaxillary fissure: transmits the maxillary artery from the infratemporal fossa, the posterior superior alveolar branches of the maxillary division of the trigeminal nerve and the sphenopalatine veins. 2. The inferior orbital fissure: transmits the infraorbital and zygomatic branches of the maxillary nerve, the orbital branches of the pterygopalatine ganglion and the infraorbital vessels. 3. The foramen rotundum from the middle cranial fossa, occupying the greater wing of the sphenoid bone and transmit the maxillary division of the trigeminal nerve 4. The pterygoid canal from the region of the foramen lacerum at the base of the skull. The pterygoid canal transmits the greater petrosal and deep petrosal nerves (which combine to form the nerve of the pterygoid canal) and an accompanying artery derived from the maxillary artery. 5. The sphenopalatine foramen lying high up on the medial wall of the fossa.This foramen communicates with the lateral wall of the nasal cavity. It transmits the nasopalatine and posterior superior nasal nerves (from the pterygopalatine ganglion) and the sphenopalatine vessels. 6. The opening of a palatine canal found at the base of the fossa.
    [Show full text]
  • Year 1969-70. Included in the Document Are Examples of The
    DOCUMCNT RRSUNII ED 031 962 EM 007 42 t By -Desch, S. H.; Stolurow. L. M. Project TAPS. Teaching Anatomy with Programmed Schematics.Progress Report Number I. Harvard Univ., Cambridge, Mass. Computation Lab. Spons Agency -Public Health Service (DHEW). Washington.D.C. Pub Date Jul 69 Note-22p. EDRS Price MF 025 HC 1120 Descriptors -Abstracts, AchievementTests. *Anatomy. Attitude Tests, Computer AssistedInstruction, Computer Oriented Programs, *Computer Programs,Experimental Programs. *Instructional Materials, *Instructional Programs. Programed Instruction.Programed Materials, *Programed Tutoring. Schematic Studies Experimental Programed Instruction of the anatomyof the maxillary division of the trigeminal nerve is being conducted bythe Harvard Computer-Aided Instruction Laboratory in cooperation withTufts University Dental School. Two nearly identical programs are presented. one(PF) using representational diagrams and the other(PD) a schematic diagramand identification key. First year dental students wererandomly selected and divided into four groups, each grouptaking the four sections of the two part course in a different sequence.Attitude testing toward programed instruction and subject achievement testing wasperformed both before and after the course. The entire course requires an average two andone-half hours of student time. Of the six pretest students whotook the first three-quarters of the course. it wasfound that Program PD yielded the most gain onSections One. Two. and the total. but Program PF yielded more on Section Three. There wasless overall gain on Section Three than on the other two sections. More datawill be accumulated in the academic year 1969-70.Included inthe document are examples of theschematic and representational diagrams. pre- and post-attitudequestionnaires, achievement tests. sample lessons, a table of results, a programabstract and a list indicating distribution of the document.
    [Show full text]
  • Trigeminal Nerve Anatomy
    Trigeminal Nerve Anatomy Dr. Mohamed Rahil Ali Trigeminal nerve Largest cranial nerve Mixed nerve Small motor root and large sensory root Motor root • Nucleus of motor root present in the pons and medulla oblongata . • Motor fiber run with sensory fibers but its completely separated from it . • Motor fiber run under the gasserian ganglion and leave the middle cranial fossa through foramen ovale in association with the third division of the sensory root • Just after formen ovale it unit with the sensory root to form single nerve trunk which is mandibular branch of trigeminal nerve Motor fibers supply : 1. Masticatory muscles • Masseter • Temporalis Motor fibers supply : 1. Masticatory muscles • Masseter • Temporalis • medial and lateral pterygoid Motor fibers supply : 1. Masticatory muscles • Masseter • Temporalis • medial and lateral pterygoid 2. Mylohoid Motor fibers supply : 1. Masticatory muscles • Masseter • Temporalis • medial and lateral pterygoid 2. Mylohoid 3. Anterior belly of diagastric 4.Tensor tympani 5. Tensor palatini Motor fibers supply : 1. Masticatory muscles • Masseter • Temporalis • medial and lateral pterygoid 2. Mylohoid 3. Anterior belly of diagastric 4.Tensor tympani Sensory root • Sensory fibers meets in the trigeminal ganglia (gasserian ganglia) • There are two ganglia ( one in each side of cranial fossa) • These ganglia located in the meckels cavity in the petrous part of temporal bone • sensory nerve divided into threee branches Ophthalmic , maxillary , mandibular Ophthalmic branch • Travel through lateral wall of cavernous sinus Ophthalmic branch • Travel through lateral wall of cavernous sinus • Leave the cranial cavity through superior orbital fissure in to the orbit Ophthalmic branch • Supplies : eye ball , conjunctiva, lacrimal gland ,part of mucous membrane of nose and paranasal sinuses , skin of the forehead ,eyelids ,nose Ophthalmic branch Branches : 1.
    [Show full text]
  • Anatomy and Morphology of the Nasopalatine Canal Using Cone-Beam Computed Tomography
    Imaging Science in Dentistry 2013; 43: 273-81 http://dx.doi.org/10.5624/isd.2013.43.4.273 Anatomy and morphology of the nasopalatine canal using cone-beam computed tomography Arpita Rai Thakur1, Krishna Burde2, Kruthika Guttal2, Venkatesh G Naikmasur2 1Department of Oral Medicine and Radiology, Faculty of Dentistry, Jamia Millia Islamia University, New Delhi, India 2Department of Oral Medicine and Radiology, S.D.M. College of Dental Sciences and Hospital, Dharwad, India ABSTRACT Purpose: This study was performed to evaluate the general anatomy and morphology of the nasopalatine canal using cone-beam computed tomography (CBCT) and to determine the human anatomic variability of the nasopalatine canal in relation to age and gender. Materials and Methods: The study included 100 subjects aged between 20 and 86 years who were divided into the following 3 groups: 1) 20-34 years old; 2) 35-49 years old; 3) ›50 years old. The subjects were equally distributed between the genders. CBCT was performed using a standard exposure and patient positioning protocol. The data of the CBCT images were sliced in three dimensions. Image planes on the three axes (X, Y, and Z) were sequentially analyzed for the location, morphology and dimensions of the nasopalatine canal by two independent observers. The correlation of age and gender with all the variables was evaluated. Results: The present study did not reveal statistically significant differences in the number of openings at the nasal fossa; diameter of the nasal fossa openings; diameter of the incisive fossa; shape, curvature, and angulation of the canal as viewed in the sagittal sections; antero-posterior dimensions and length of the canal in the sagittal sections; or the level of division of the canal in the coronal plane by age.
    [Show full text]