Surgical Anatomy of the Liver : Ηepatectomies - Dimitris P. KorkolisDimitris P. Korkolis
- The liver is the largest gland in the body and has a wide variety of functions
- Weight: 1/50 of body weight in adult & 1/20 of body weight in infant
- It is exocrine(bile) & endocrine organ(Albumin , prothrombin & fibrinogen)
Function of the liver :
- Secretion of bile & bile salt
- Metabolism of carbohydrate, fat and protein
- Formation of heparin & anticoagulant substances
- Detoxication
- Storage of glycogen and vitamins
- Activation of vita .D
anatomy of duodenum, location or position of duodenum, parts of duodenum, relations of each parts of duodenum, ligaments of treitz, visceral and peritoneal relation of duodenum, blood supply of duodenum, innervation of duodenum, clinical aspects of duodenum, duodenal ulcer, diverticulum, deodinitis, duodenal obstruction
Surgical Anatomy of the Liver : Ηepatectomies - Dimitris P. KorkolisDimitris P. Korkolis
- The liver is the largest gland in the body and has a wide variety of functions
- Weight: 1/50 of body weight in adult & 1/20 of body weight in infant
- It is exocrine(bile) & endocrine organ(Albumin , prothrombin & fibrinogen)
Function of the liver :
- Secretion of bile & bile salt
- Metabolism of carbohydrate, fat and protein
- Formation of heparin & anticoagulant substances
- Detoxication
- Storage of glycogen and vitamins
- Activation of vita .D
anatomy of duodenum, location or position of duodenum, parts of duodenum, relations of each parts of duodenum, ligaments of treitz, visceral and peritoneal relation of duodenum, blood supply of duodenum, innervation of duodenum, clinical aspects of duodenum, duodenal ulcer, diverticulum, deodinitis, duodenal obstruction
Anterior abdominal wall , Rectus sheath and Inguinal.pptxJudeChinecherem
In this detailed lecture note, we embark on a comprehensive journey through the complex and crucial anatomy of the abdominal wall. The abdominal wall is not just a physical barrier; it is a dynamic structure with multiple layers, muscles, and intricate structures that play a fundamental role in protecting our internal organs, providing support, and enabling various bodily functions.
We will delve deep into the layers of the abdominal wall, understanding the significance of each component - from the outermost skin to the innermost peritoneum. Through detailed illustrations, diagrams, and explanations, you will gain a profound insight into the anatomical intricacies of this region.
Moreover, this lecture note provides valuable insights into the clinical relevance of the abdominal wall. Learn about common medical conditions and surgical procedures related to the abdominal wall, including hernias, trauma, and abdominal wall reconstruction. Whether you are a medical student, healthcare professional, or simply intrigued by the wonders of the human body, this resource will enrich your knowledge and understanding of this vital anatomical structure.
Join us on this educational journey as we unravel the mysteries of the abdominal wall, exploring its anatomy, functions, and clinical significance. Whether you're studying medicine, pursuing a career in healthcare, or just eager to expand your knowledge, this lecture note is a valuable resource for anyone interested in the fascinating world of human anatomy."
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- Video recording of this lecture in English language: https://youtu.be/lK81BzxMqdo
- Video recording of this lecture in Arabic language: https://youtu.be/Ve4P0COk9OI
- Link to download the book free: https://nephrotube.blogspot.com/p/nephrotube-nephrology-books.html
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Flu Vaccine Alert in Bangalore Karnatakaaddon Scans
As flu season approaches, health officials in Bangalore, Karnataka, are urging residents to get their flu vaccinations. The seasonal flu, while common, can lead to severe health complications, particularly for vulnerable populations such as young children, the elderly, and those with underlying health conditions.
Dr. Vidisha Kumari, a leading epidemiologist in Bangalore, emphasizes the importance of getting vaccinated. "The flu vaccine is our best defense against the influenza virus. It not only protects individuals but also helps prevent the spread of the virus in our communities," he says.
This year, the flu season is expected to coincide with a potential increase in other respiratory illnesses. The Karnataka Health Department has launched an awareness campaign highlighting the significance of flu vaccinations. They have set up multiple vaccination centers across Bangalore, making it convenient for residents to receive their shots.
To encourage widespread vaccination, the government is also collaborating with local schools, workplaces, and community centers to facilitate vaccination drives. Special attention is being given to ensuring that the vaccine is accessible to all, including marginalized communities who may have limited access to healthcare.
Residents are reminded that the flu vaccine is safe and effective. Common side effects are mild and may include soreness at the injection site, mild fever, or muscle aches. These side effects are generally short-lived and far less severe than the flu itself.
Healthcare providers are also stressing the importance of continuing COVID-19 precautions. Wearing masks, practicing good hand hygiene, and maintaining social distancing are still crucial, especially in crowded places.
Protect yourself and your loved ones by getting vaccinated. Together, we can help keep Bangalore healthy and safe this flu season. For more information on vaccination centers and schedules, residents can visit the Karnataka Health Department’s official website or follow their social media pages.
Stay informed, stay safe, and get your flu shot today!
MANAGEMENT OF ATRIOVENTRICULAR CONDUCTION BLOCK.pdfJim Jacob Roy
Cardiac conduction defects can occur due to various causes.
Atrioventricular conduction blocks ( AV blocks ) are classified into 3 types.
This document describes the acute management of AV block.
Couples presenting to the infertility clinic- Do they really have infertility...Sujoy Dasgupta
Dr Sujoy Dasgupta presented the study on "Couples presenting to the infertility clinic- Do they really have infertility? – The unexplored stories of non-consummation" in the 13th Congress of the Asia Pacific Initiative on Reproduction (ASPIRE 2024) at Manila on 24 May, 2024.
Explore natural remedies for syphilis treatment in Singapore. Discover alternative therapies, herbal remedies, and lifestyle changes that may complement conventional treatments. Learn about holistic approaches to managing syphilis symptoms and supporting overall health.
Lung Cancer: Artificial Intelligence, Synergetics, Complex System Analysis, S...Oleg Kshivets
RESULTS: Overall life span (LS) was 2252.1±1742.5 days and cumulative 5-year survival (5YS) reached 73.2%, 10 years – 64.8%, 20 years – 42.5%. 513 LCP lived more than 5 years (LS=3124.6±1525.6 days), 148 LCP – more than 10 years (LS=5054.4±1504.1 days).199 LCP died because of LC (LS=562.7±374.5 days). 5YS of LCP after bi/lobectomies was significantly superior in comparison with LCP after pneumonectomies (78.1% vs.63.7%, P=0.00001 by log-rank test). AT significantly improved 5YS (66.3% vs. 34.8%) (P=0.00000 by log-rank test) only for LCP with N1-2. Cox modeling displayed that 5YS of LCP significantly depended on: phase transition (PT) early-invasive LC in terms of synergetics, PT N0—N12, cell ratio factors (ratio between cancer cells- CC and blood cells subpopulations), G1-3, histology, glucose, AT, blood cell circuit, prothrombin index, heparin tolerance, recalcification time (P=0.000-0.038). Neural networks, genetic algorithm selection and bootstrap simulation revealed relationships between 5YS and PT early-invasive LC (rank=1), PT N0—N12 (rank=2), thrombocytes/CC (3), erythrocytes/CC (4), eosinophils/CC (5), healthy cells/CC (6), lymphocytes/CC (7), segmented neutrophils/CC (8), stick neutrophils/CC (9), monocytes/CC (10); leucocytes/CC (11). Correct prediction of 5YS was 100% by neural networks computing (area under ROC curve=1.0; error=0.0).
CONCLUSIONS: 5YS of LCP after radical procedures significantly depended on: 1) PT early-invasive cancer; 2) PT N0--N12; 3) cell ratio factors; 4) blood cell circuit; 5) biochemical factors; 6) hemostasis system; 7) AT; 8) LC characteristics; 9) LC cell dynamics; 10) surgery type: lobectomy/pneumonectomy; 11) anthropometric data. Optimal diagnosis and treatment strategies for LC are: 1) screening and early detection of LC; 2) availability of experienced thoracic surgeons because of complexity of radical procedures; 3) aggressive en block surgery and adequate lymph node dissection for completeness; 4) precise prediction; 5) adjuvant chemoimmunoradiotherapy for LCP with unfavorable prognosis.
Ozempic: Preoperative Management of Patients on GLP-1 Receptor Agonists Saeid Safari
Preoperative Management of Patients on GLP-1 Receptor Agonists like Ozempic and Semiglutide
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2 Case Reports of Gastric Ultrasound
Tom Selleck Health: A Comprehensive Look at the Iconic Actor’s Wellness Journeygreendigital
Tom Selleck, an enduring figure in Hollywood. has captivated audiences for decades with his rugged charm, iconic moustache. and memorable roles in television and film. From his breakout role as Thomas Magnum in Magnum P.I. to his current portrayal of Frank Reagan in Blue Bloods. Selleck's career has spanned over 50 years. But beyond his professional achievements. fans have often been curious about Tom Selleck Health. especially as he has aged in the public eye.
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Introduction
Many have been interested in Tom Selleck health. not only because of his enduring presence on screen but also because of the challenges. and lifestyle choices he has faced and made over the years. This article delves into the various aspects of Tom Selleck health. exploring his fitness regimen, diet, mental health. and the challenges he has encountered as he ages. We'll look at how he maintains his well-being. the health issues he has faced, and his approach to ageing .
Early Life and Career
Childhood and Athletic Beginnings
Tom Selleck was born on January 29, 1945, in Detroit, Michigan, and grew up in Sherman Oaks, California. From an early age, he was involved in sports, particularly basketball. which played a significant role in his physical development. His athletic pursuits continued into college. where he attended the University of Southern California (USC) on a basketball scholarship. This early involvement in sports laid a strong foundation for his physical health and disciplined lifestyle.
Transition to Acting
Selleck's transition from an athlete to an actor came with its physical demands. His first significant role in "Magnum P.I." required him to perform various stunts and maintain a fit appearance. This role, which he played from 1980 to 1988. necessitated a rigorous fitness routine to meet the show's demands. setting the stage for his long-term commitment to health and wellness.
Fitness Regimen
Workout Routine
Tom Selleck health and fitness regimen has evolved. adapting to his changing roles and age. During his "Magnum, P.I." days. Selleck's workouts were intense and focused on building and maintaining muscle mass. His routine included weightlifting, cardiovascular exercises. and specific training for the stunts he performed on the show.
Selleck adjusted his fitness routine as he aged to suit his body's needs. Today, his workouts focus on maintaining flexibility, strength, and cardiovascular health. He incorporates low-impact exercises such as swimming, walking, and light weightlifting. This balanced approach helps him stay fit without putting undue strain on his joints and muscles.
Importance of Flexibility and Mobility
In recent years, Selleck has emphasized the importance of flexibility and mobility in his fitness regimen. Understanding the natural decline in muscle mass and joint flexibility with age. he includes stretching and yoga in his routine. These practices help prevent injuries, improve posture, and maintain mobilit
Pulmonary Thromboembolism - etilogy, types, medical- Surgical and nursing man...VarunMahajani
Disruption of blood supply to lung alveoli due to blockage of one or more pulmonary blood vessels is called as Pulmonary thromboembolism. In this presentation we will discuss its causes, types and its management in depth.
Title: Sense of Taste
Presenter: Dr. Faiza, Assistant Professor of Physiology
Qualifications:
MBBS (Best Graduate, AIMC Lahore)
FCPS Physiology
ICMT, CHPE, DHPE (STMU)
MPH (GC University, Faisalabad)
MBA (Virtual University of Pakistan)
Learning Objectives:
Describe the structure and function of taste buds.
Describe the relationship between the taste threshold and taste index of common substances.
Explain the chemical basis and signal transduction of taste perception for each type of primary taste sensation.
Recognize different abnormalities of taste perception and their causes.
Key Topics:
Significance of Taste Sensation:
Differentiation between pleasant and harmful food
Influence on behavior
Selection of food based on metabolic needs
Receptors of Taste:
Taste buds on the tongue
Influence of sense of smell, texture of food, and pain stimulation (e.g., by pepper)
Primary and Secondary Taste Sensations:
Primary taste sensations: Sweet, Sour, Salty, Bitter, Umami
Chemical basis and signal transduction mechanisms for each taste
Taste Threshold and Index:
Taste threshold values for Sweet (sucrose), Salty (NaCl), Sour (HCl), and Bitter (Quinine)
Taste index relationship: Inversely proportional to taste threshold
Taste Blindness:
Inability to taste certain substances, particularly thiourea compounds
Example: Phenylthiocarbamide
Structure and Function of Taste Buds:
Composition: Epithelial cells, Sustentacular/Supporting cells, Taste cells, Basal cells
Features: Taste pores, Taste hairs/microvilli, and Taste nerve fibers
Location of Taste Buds:
Found in papillae of the tongue (Fungiform, Circumvallate, Foliate)
Also present on the palate, tonsillar pillars, epiglottis, and proximal esophagus
Mechanism of Taste Stimulation:
Interaction of taste substances with receptors on microvilli
Signal transduction pathways for Umami, Sweet, Bitter, Sour, and Salty tastes
Taste Sensitivity and Adaptation:
Decrease in sensitivity with age
Rapid adaptation of taste sensation
Role of Saliva in Taste:
Dissolution of tastants to reach receptors
Washing away the stimulus
Taste Preferences and Aversions:
Mechanisms behind taste preference and aversion
Influence of receptors and neural pathways
Impact of Sensory Nerve Damage:
Degeneration of taste buds if the sensory nerve fiber is cut
Abnormalities of Taste Detection:
Conditions: Ageusia, Hypogeusia, Dysgeusia (parageusia)
Causes: Nerve damage, neurological disorders, infections, poor oral hygiene, adverse drug effects, deficiencies, aging, tobacco use, altered neurotransmitter levels
Neurotransmitters and Taste Threshold:
Effects of serotonin (5-HT) and norepinephrine (NE) on taste sensitivity
Supertasters:
25% of the population with heightened sensitivity to taste, especially bitterness
Increased number of fungiform papillae
ARTIFICIAL INTELLIGENCE IN HEALTHCARE.pdfAnujkumaranit
Artificial intelligence (AI) refers to the simulation of human intelligence processes by machines, especially computer systems. It encompasses tasks such as learning, reasoning, problem-solving, perception, and language understanding. AI technologies are revolutionizing various fields, from healthcare to finance, by enabling machines to perform tasks that typically require human intelligence.
2. KEY POINTS
1. The adult human esophagus is an 18- to 25-cm long muscular tube that
has cervical, thoracic, and abdominal parts.
2. The esophagus wall is composed of striated muscle in the upper
part, smooth muscle in the lower part, and a mixture of the two in the
middle.
3. The myenteric plexus is well developed in the smooth muscle, but is also
present in the striated muscle part of the esophagus.
4. The function of the myenteric plexus in the striated esophagus is not well
understood.
5. Esophagus develops from foregut and by week 10 is lined by ciliated
epithelial cells.
3. 6. Beginning at 4 months, the ciliated epithelium starts to be
replaced by squamous epithelium. At either end of the
esophagus the ciliated epithelium gives rise to esophageal
glands.
7. The upper esophagus is derived from branchial arches
4, 5, and 6, but the derivation of the lower esophagus is not
known.
8. The development of various elements of esophageal wall
requires coordination of a variety of genes and mediators.
9. Esophageal peristalsis appears in the first trimester, and
gastroesophageal reflux can be documented in the second
trimester.
• Unlike the remainder of the GI tract, the esophageal tube has
neither mesentery nor serosal coating .
4. Introduction
• From mouth to stomach, the food conduit consists of
the oral cavity, pharynx, and esophagus.
• The esophagus serves as a dynamic tube, pushing food
toward the stomach.
• Mucus produced by the esophageal mucosa provides
lubrication and eases the passage of food.
• Active peristaltic contractions propel residual material
from the esophagus into the stomach.
5. Anatomical Division
The esophagus is a midline structure lying on the
anterior surface of the spine.
It descends through three compartments: the
neck, the chest, and the abdomen.
This progression has led to its classic anatomic
division into cervical, thoracic, and abdominal
segments.
Two new subdivisions
One is functional aspects and makes a distinction
between the esophageal body and the upper and
lower sphincters.
The other is oncosurgery aspects and
distinguishes between the proximal and the distal
esophagus, with the tracheal bifurcation used as a
6.
7. Anatomic Division
• Cervical
o Cervical begins at the lower end of pharynx (level of 6th
vertebra or lower border of cricoid cartilage) and extends
to the thoracic inlet (suprasternal notch); 18 cm from
incisors.
• Thoracic
o Upper thoracic: from thoracic inlet to level of tracheal
bifurcation; 18-23 cm.
o Mid thoracic: from tracheal bifuraction midway to
gastroesophageal junction; 24-32 cm.
o Lower thoracic: from midway between tracheal bifurcation
and gastroesophageal junction to GE junction, including
abdominal esophagus; 32-40 cm.
• Abdominal
o Considered part of lower thoracic esophagus; 32-40 cm.
8.
9. Gross anatomy of esophagus
• The oesophagus is a muscular tube, typically25 cm long, which
connects the pharynx to the stomach.
• It begins in the neck, level with the lower border of the cricoid
cartilage and the 6th cervical vertebra.
• Descends anterior to the vertebral column through the superior
and posterior mediastina.
• Passes through the diaphragm, level with the 10th thoracic
vertebra.
• Ends at the gastric cardiac orifice level with the 11th thoracic
vertebra.
• Between swallows the esophagus is collapsed but the lumen can
distend to approximately 2 cm in the antero-posterior dimension
and up to 3 cm laterally to accommodate a swallowed bolus.
10. Deviations of esophagus
A healthy esophagus has three minor deviations along its trajectory-
• The 1st inclines to the left as far as the root of the neck, gradually
returns to the median plane near the 5th thoracic vertebra.
• Hence surgical approaches to the esophagus are easier from the left
than from the right when performing intestinocervical esophageal
anastomoses after esophagectomy.
• The 2nd deviation is at the level of the 7th thoracic vertebra, where the
esophagus turns slightly to the right of the Spine, before it pierces
the diaphragm.
11. Deviations of esophagus cont.
• it can also bend slightly to the right as it is pushed by the aorta before
bending to the left to reach the oesophageal hiatus(the 3rd deviation).The
terminal esophagus and the esophagogastric junction are positioned
slightly lateral to the xiphoid process of the sternum and to the left of the
spine
• At this point, the fundus and proximal part of the stomach extend
anterolateral to the body of the vertebra,as a result, the greater curvature
faces the posterior subdiaphragmatic space, and the anterior gastric wall
faces laterally.
• The oesophagus also bends in an anteroposterior plane to follow the
cervicothoracic curvatures of the vertebral column.
12. Constrictions of esophagus
• It is the narrowest part of the alimentary tract (except for the
vermiform appendix).
• Esophagus is constricted -
1. at the beginning (15 cm from the incisor teeth),
2. where it is crossed by the aortic arch (22.5 cm from the incisor teeth),
3. where it is crossed by the left principal bronchus (27.5 cm from the incisors) and
4. as it passes through the diaphragm (40 cm from the incisors).
• These measurements are important clinically with regard to the
passage of instruments along the oesophagus.
13.
14.
15. Cross-section of esophagus at various
level
• Topographic anatomy of the esophagus shown from the cervical level (1)
to the esophagogastric junction (6).
• A transverse section through the mediastinum shows the esophagus and
its surrounding structures in a computed tomographic aspect.
• The close positional relationship among the esophagus, trachea, and
vertebrae and the fascial planes is displayed.
• The dark lines are the prevertebral and previsceral fascia (arrows); the
net-like pattern represents the respective areolar connective tissue.
17. Periesophageal Tissue, Compartments, and Fascial
Planes
• Unlike the general structure of the digestive tract, the esophageal tube has
neither mesentery nor serosal coating.
• Its position within the mediastinum and a complete envelope of loose connective
tissue allow the esophagus extensive transverse and longitudinal mobility.
• Respiration may induce craniocaudal movement over a few millimeters, and
swallows may result in excursion over as much as the height of one vertebral
body.
• This mobility is also the reason why the esophagus may be subjected to easy
blunt stripping from the mediastinum.
• Invasion by malignant tumor and fixation to the surroundings, however, strictly
contraindicate the use of this technique.
18. • The connective tissues in which the esophagus and trachea
are embedded are bounded by fascial planes, the pretracheal
fascia anteriorly and the prevertebral fascia posteriorly.
• In the upper part of the chest, both fascias unite to form the
carotid sheath.
• The anterior and posterior spaces between these fascias form
a communicating compartment between the neck and the
chest.
• This communication provides a plane for rapid spread of
infection through the mediastinum.
19. • The anterior space (previsceral or pretracheal space)- Infections spreading
from anterior lesions of the esophagus may follow this route, but they are
limited distally by the strong fibrous tissue of the pericardium.
• The posterior space(retrovisceral or prevertebral space)- extends from the
base of the skull to the diaphragm. It is formed by the buccopharyngeal
fascia spreading downward via a sheath that separates the esophageal tissue
bed from the prevertebral fascia.
• Posterior space is clinically of greater importance than the anterior space.
The reason is that most instrument perforations with subsequent outflow of
esophageal contents occur above the narrowing of the cricopharyngeal
sphincter in the posterior hypopharynx.
20. • At this level, as in the chest, there is no barrier for stoping
spread of infection into the mediastinum.
• Rupture of the esophagus or leakage of an esophageal
anastomosis may result in descending mediastinitis along
these planes as well.
• Prompt diagnosis is vital for the patient because the prognosis
for esophageal perforation depends on the rapidity with
which treatment is initiated!
22. Anchoring of the esophagus
“The esophagus is stabilized by bony, cartilaginous, and membranous
structures”As shown in figure Fig. 2
• The upper end of the esophagus obtains firm anchorage by the insertion of its
exterior longitudinal muscle into the cartilaginous structures of the hypopharynx
(posterior ridge of the cricoid cartilage) (1) via the cricoesophageal tendon (2).
• The circular muscle is stabilized by its continuity with the inferior laryngeal
constrictor muscles (1), which insert via the raphe to the sphenoid bone.
• Tiny membranes(170 μm in thickness and approximately 3 to 5 mm in length)
connect the esophagus with the trachea, bronchi, pleura, and prevertebral fascia
(3 and 4).
23. • Consisting of collagen and elastic fiber elements and occasional
interpositioned sparse muscle fibers, the membranes are stretchable to
some extent and accumulate around the tracheal bifurcation.
• The attachment at the lower end by the phrenoesophageal membrane &
the two diaphragmatic crura (5) is rather mobile, whereas the posterior
gastric ligaments,such as the gastrosplenic, phrenicolienal, and
phrenicogastric ligaments (6), and the lesser omentum (6) yield a tight
adherence.
( LES, lower esophageal sphincter; UES, upper esophageal sphincter)
26. Fig.3 description
• The posterior walls of the pharynx (4) and the esophagus (7 and 8) have been cut
open in the midline, as shown in a specimen (A) and half-schematically (B).
• The structures of the hypopharynx are exposed by retracting the overlying
incised tissue and removing the mucosa.
• In the center lies the cricoesophageal tendon (6), which attaches the longitudinal
muscle layerof the esophagus (8) to the cricoid cartilage (2).
• The terminal branches of the left laryngeal recurrent nerve (9) are dissected and
are seen lateral to the cricoesophageal tendon.
1= Thyroid cartilage.
27. CERVICAL OESOPHAGUS
• The cervical oesophagus is posterior to the trachea and attached to
it by loose connective tissue.
• The recurrent laryngeal nerves ascend on each side in or near the
tracheo-oesophageal groove.
• Posteriorly are the vertebral column, longus colli and prevertebral
layer of deep cervical fascia.
• Laterally on each side are the common carotid arteries and
posterior part of the thyroid gland.
28. • In the lower neck, where the oesophagus deviates to the left, it is closer to the left
carotid sheath and thyroid gland than it is on the right.
• The thoracic duct ascends for a short distance along its left side.
• The left border of esophagus extends beyond the trachea so that the oesophagus is
more easily exposed via left sided cervical incision.
• Malignant tumors are known to spread from the trachea to the esophagusand vice
versa. Clinically, such spread results in an “acquired fistula.”
• It appears that the lack of interposed connective tissue between the two organs
predisposes to this unlucky event.
• A tracheoesophageal fistula after either an instrumental
perforation, esophagectomy, or chemotherapy and irradiation in this inherently
weak area is a catastrophic problem for both the patient and physician.
29.
30. Transverse section through the neck and
upper part of the chest of a human
autopsy specimen viewed from a
cranial aspect.
1, Esophagus; 2, trachea; 3, pleura; 6, thyroid
gland; and 8, vessels.
The histologic section shows the
esophagus still in the midline posterior
position (A), whereas on the more distal level
of the macroscopic cut surface (B), the
esophagus has shifted toward the left.
Note-the intimate local relationship between
the esophagus and the trachea.
31. Phrenoesophageal membrane (PEM)
• The muscular portion of the diaphragm is inserted on the lumbar vertebrae, the
ribs, and the sternum.
• The central membranous portion is frequently larger and the left crus of the
diaphragm may consist of membranous tissue rather than a significant muscular
mass.
• The subdiaphragmatic and endothoracic aponeuroses blend at the central margin
of the diaphragm to constitute the phrenoesophageal membrane (PEM), also
known as Laimer's ligament or Allison's membrane.
• Intraoperatively, the PEM can be recognized by its well-defined lower edge and its
slightly yellow color, even in the presence of severe periesophagitis.
• The PEM is composed of elastic and collagenous fiber elements, which guarantee
sufficient pliability.
• Because of its origin from a fascia, the PEM in general is relatively strong.
32. • PEM splits into two sheets.
• One sheet extends 2 to 4 cm upward through the hiatus, where its
fibers traverse the esophageal musculature to insert on the
submucosa.
• The other sheet passes down across the cardia up to the level of the
gastric fundus, where it blends into the gastric serosa, the
gastrohepatic ligament, and the dorsal gastric mesentery.
• Although there are sparse attachments via elastic cords in the pattern
shown in 3rd figure, the PEM is clearly some distance away and
separated by loose connective tissue and fat accumulation from the
musculature of the gastroesophageal junction.
33. • This structural arrangement allows the terminal esophagus and the junction to
move in relation to the diaphragm and to “slip through the hiatus like in a tendon
sheath.”
• With advancing age, the elastic fibers are replaced by inelastic collagenous
tissue, and the adhesion of the PEM to the lower portion of the esophagus
loosens,which leads to loss of pliability.
• Disruption of the anchoring structures of the cardia and the proximal part of the
stomach in conjunction with a wide hiatus may result in herniation of the
gastroesophageal junction and the cardia, or even parts of the stomach, into the
mediastinum.
• Abnormal anchoring of the PEM in youth and pathologic accumulation of adipose
tissue in the separating connective tissue space between the PEM and the cardia
musculature are thought to contribute to the development of a hiatal hernia.
35. The phrenoesophageal membrane (PEM).
The lower component of the PEM inserts on the gastric fundus.
On the left, the diaphragm is held up with forceps.
Diaphragmatic decussating fibers (long arrow) and a submembranous inlay of adipose
tissue (short arrow) are seen.
The PEM wraps the esophagogastric junction with a wide membranous collar.
36. Diagram of the tissue organization and supporting
structures at the esophagogastric junction.
The esophagus is opened alongside the greater and lesser curvatures.
The luminal aspect is displayed from the left side.
The fiber elements that attach the phrenoesophageal membrane to the muscle wall of the terminal esophagus are
shown.
37. THORACIC OESOPHAGUS
• In chest,esophagus runs through the superior & posterior mediastinum.
• It is little towards left in the superior mediastinum between the trachea and the
vertebral column. {fig.1(2),(3)}
• It passes behind and to the right of the aortic arch to descend in the posterior
mediastinum along the right side of the descending thoracic aorta. {fig.1(2)}
• Below, as it inclines left, it crosses anterior to the aorta and enters the abdomen
through the diaphragm at the level of the 10th thoracic vertebra. {fig.1(4)}
• Anteriorly,from above downwards, the trachea, right pulmonary artery, left main
bronchus, pericardium (separating it from the left atrium) and the diaphragm are
situated . {fig.1(3),(4),(5) & Anterior(a) & posterior (b) view }
• The vertebral column, longus colli, right posterior intercostal arteries, thoracic
duct, azygos vein and the terminal parts of the hemiazygos and accessory hemiazygos
veins, and, near the diaphragm, the aorta are posterior. {fig.1(3),(4),(5) & Anterior(a) &
posterior (b) view }
•
38. • A long recess of the right pleural sac lies between the oesophagus (in front) and the azygos
vein and vertebral column (behind) in the posterior mediastinum.perforation of the
oesophagus at this point may produce aright-sided pleural effusion.
• In the superior mediastinum, the terminal part of the aortic arch, the left subclavian
artery, thoracic duct, the left pleura and the recurrent laryngeal nerve are left lateral
relations.
• In the posterior mediastinum, the oesophagus is related to the descending thoracic aorta
and left pleura. The right pleura, and the azygos vein as it arches forwards above the right
main bronchus to join the superior vena cava, are right lateral relations.
• When performing transthoracic esophagectomy, surgical access for safe removal of the
esophagus is preferably through the right side of the chest, and the azygos vein must usually
be divided before the esophagus can be dissected free.
.
39. •Below the pulmonary roots, the vagus nerves descend in contact with the
oesophagus, the right mainly behind and the left in front; the vagi subsequently
unite to form a plexus around the oesophagus.
•Low in the posterior mediastinum, the thoracic duct is behind and to the right of
the oesophagus;, crossing to the left of the oesophagus from 7th to 5th thoracic
vertebra and then ascendes up along its left border.
•Lower down the esophagus takes a curve to the left behind the pericardial sac &
passes completely to the left of the midline toward the oesophageal hitus crossing
anterior to the arota.
•Perforation of the lower 1/3rd of the oesophagus are therefore more likely to
result in left-sided pleural effusion.
• On the right of the oesophagus, just above the diaphragm, a small serous
infracardiac bursa may occur; it represents the detached apex of the right
pneumatoenteric recess.
40. The position and relationships of the azygos vein, the thoracic
duct, and the vagus nerve are shown from a right
lateral aspect.
41. ABDOMINAL OESOPHAGUS
• The abdominal oesophagus is 1–2.5 cm in length, and is slightly broader at the
cardiac orifice than the diaphragmatic aperture.
• It lies to the left of the midline and enters the abdomen through the
oesophageal aperture (formed by the two diaphragmatic crura) opposite the
level of the 10th thoracic vertebra.
• It runs obliquely to the left and slightly posteriorly, and ends at the gastro-
oesophageal junction/cardiac orifice of the stomach.
• Left lobe of the liver posteriorly to it, which it grooves slightly.
• Left crus of diaphgram, the left inferior phrenic vessels and the left greater
splanchnic nerve anterior to it,
42. • Its surface is covered in a thin layer of connective tissue and visceral
peritoneum which contains the anterior and posterior vagi as well as the
oesophageal branches of the left gastric vessels.
• The anterior vagus may be single or composed of multiple trunks, and is
closely related to the outer fibres of the longitudinal muscle coat of the
oesophagus.
• The posterior vagus is usually a single trunk and is less closely applied to the
oesophageal muscle within the loose connective tissue, which makes its
identification during surgery somewhat easier.
43. • Abdominal oesophagus is effectively tethered to the diaphragm by
connective tissue,the phreno-oesophageal ligament. This is formed of
two thickened bands of elastin-rich connective tissue-
i. superior phreno-oesophgeal ligament(On the thoracic side of the
diaphragm)- is similarly formed from an extension of the subpleural endothoracic fascia.
It is denser than its inferior counterpart with more elastin present and is tethered much
more firmly through the muscle fibres of the oesophageal wall into the submucosal
tissues. It may well act to restore lower oesophageal position after the movement
engendered by the peristalsis of swallowing.
ii. Inferior phreno-oesophageal ligament (on abdominal side of
diaphgram)-an extension of the transversalis fascia extending beneath the parietal
peritoneum as it is reflected from the diaphragm onto the abdominal oesophagus. The
fibres are only loosely attached to the adventitial tissues and a variable amount of fat
often lies beneath it, between the oesophageal wall and the crural sling. This oesophageal
fat pad tends to act to tether the oesophagus to the fibres of the crura but tends to regress
with age.
44. •Anteriorly, the subperitoneal connective tissue is particularly dense and blends with
both the outer layer of the oesophageal wall and the apex of the crural fibres of the
diaphragm.
•On the posterior aspect the peritoneal reflection is extremely short since the crura
lie steeply angled, and the posterior oesophageal wall has a much shorter ‘effective
length' than the anterior.
•This short reflection of peritoneum is sometimes referred to as the gastrophrenic
ligament and, via the peritoneum over the oesophagus continues directly onto the
posterior surface of the stomach.
45. •It covers the oesophageal branches of the left gastric vessels and the coeliac
branches of the posterior vagus and can thus be said to form an extremely
short, wide mesentery to the abdominal oesophagus.
•In all but the thinnest individuals a pad of adipose tissue is found beneath the
peritoneum covering the anterior surface of the lower abdominal oesophagus
and the adjacent gastric wall.
•It is a useful surgical marker for the external location of the gastro-
oesophageal junction.
46.
47. Oesphagus sphincters
• There is an anatomical sphincter at
the upper end & physiological
sphincter at the lower end of the
oesophagus. 2 types—
1. CRICOPHARYNGEUS OR Inferior
constrictor of the pharynx
2. Oesophagogastric junction sphincter
48. 1.CRICOPHARYNGEUS OR
Inferior constrictor of the
pharynx• This muscle consist of 2 parts—
• A lower transver part(cricopharyngeus)
• an upper oblique portion(thyropharyngeus)
The lower transver fiber arise from cricoid cartilage &
pass horizontally backward round the pharynx to be
inserted into median raphae at the back of this
tube.Its function is to prevent regurgitation of the
esophageal content into the pharynx.
The upper oblique fibers arises from the cricoid &
thyroid cartilage & encircle the hypopharynx,ending
in median raphae.
49. • In act of swallowing,the upper(oblique) part of this muscle
propel the content downward & lower (transver) part
relaxes to allow the content to pass into the oesophagus.
• Incordination of this action,with failure of the
cricopharyngeous to relax will result to increased pressure
in the pharynx & production of a pharyngeal diverticulam.
• A cricopharyngeal myotomy is performed in condition
associated with incordination of muscle relaxation(i.e
pharyngeal diverticulam).
• Intraluminal pressure recording demonstrate a high
pressure zone 2-4 cm.
50. 2.The oesophagogastric junction
• Normally gastric contents regurgitate into the oesophagus because
of the mechanism at the cardia preventing this.
• Median arcuate ligament does not directly contribute to the
competence of the oesophagogastric junction but is of surgical
importance in the region.it is a tough fibrous 1-3 mm wide
condensation of medial fibrous borders of the 2 crura of diaphgram.
• It is usually at level just proximal to the origin of celiac artery.
• The ligament is used as the main anchoring site for Hill-anti reflux
operation.
• The origin of Phrenic vessel lies just proximal to celiac vessels &
should be carefully avoided when the ligament is dissected.
• Median arcuate ligament may be absent or very attenuated.
51. Arterial supply• Unusual ! Arterial supply derived from vessels feeding mainly other organs – thyroid, trachea &
stomach. (“Shared vasculature”)
• Cervical Oesophagus: Right & Left superior & inferior
thyroid arteries.
• Thoracic Oesophagus: Up to tracheal bifurcation Right &
Left inferior thyroid Artery
direct supply from aorta (tracheo-bronchial tree)
• Abdominal Oesophagus: 11 branches off Left gastric
artery and Branches of splenic artery posteriorly.
• All the major arterial vessels divide into minute branches at some
distance from the esophageal wall,and it appears that such small
esophageal tributaries, when torn from the esophagus, have the
benefit of contractile periesophageal hemostasis.
52. • The minute extraesophageal branches enter the esophageal
wall, pass through the tunica muscularis, and give off branches to
the muscle before they form the wide vascular plexus within the
submucosa and mucosa.
• The clear continuity of the vessels and the rich anastomosing
intramural vascularity explain why a mobilized esophagus retains
an excellent blood supply over a long distance.
• On the other hand, the extremely small caliber of the nutritional
vessels also explains leaks after esophagointestinal anastomosis
in the event of mechanical damage to the microvascular
circulation.
53. Extravisceral sources of arterial blood supply to the esophagus, intramural anastomoses (dotted
line), and topographic relationship of the azygos vein to the esophagus and tracheal bifurcation.
The arrows indicate the direction of flow.
54.
55. Arterial cast showing the vascular supply to the middle and lower portions of the
esophagus.
Note that the esophageal branch derives from the bronchial artery. During esophageal
resection, it should be ligated close to the esophageal wall so that the blood supply of the
left main bronchus is not jeopardized.
56. Venous Drainage
• Butler classified the esophageal veins into intrinsic and extrinsic
veins, referring to intraesophageal and extraesophageal wall veins.
1.Intraparietal Veins and Plexuses
• The intraesophageal veins include a subepithelial plexus in the lamina
propria mucosa that receives blood from the adjacent capillaries.
• Aharinejad et al. described two small veins that usually accompany the
arteries in the lamina submucosa, pierce the muscular wall of the
esophagus together with the perforating arteries, and then form the
extramural veins at the surface of the esophagus.
• No valves were found within the esophageal venous circulatory
system.
57. • Two clearly delineated venous plexuses are present beneath the
mucosa of the hypopharynx.
• One plexus lies on the dorsal aspect of the inferior constrictor
muscle, and the other is in the midline posterior to the cricoid
cartilage,this is exactly at the level of the pharyngoesophageal
junction.
• The plexuses were located within an extremely thin submucosa; both
were 2 to 3 cm broad and 4 cm long. The veins were up to 4 mm thick
and of mostly longitudinal orientation, similar to Figure.
• The plexuses receive blood from the mucosa of the laryngopharynx
and esophagus and drain into the thyroid and jugular veins.
• Considered to account for the postcricoid impression on the
esophagus, they may be involved in the “globus sensation” in
patients with venous stasis and tissue swelling.
• It is tempting to postulate that the plexuses also contribute to some
extent to the competence and action of the UES.
59. • A specialized venous arrangement is present at the terminal
esophagus (Figure below). It has been suggested that these venous
anastomoses possibly constitute a communication between the
azygos and the portal systems.
• The intermediate “palisade zone” (Figure below)is thought to act
as a high-resistance watershed between both systems that
provides bidirectional flow. Anastomoses between the systemic
and the portal systems are found in the submucosa and lamina
propria of the lower end of the esophagus and may enlarge in
patients with portal venous obstruction to form varices.
60. Radiograph of the venous circulation at the esophagogastric junction and the esophagus after injection
with barium gelatin. This example shows the various zones of different venous architecture, such as the
gastric zone (GZ), the palisade zone (PZ), the perforating zone (PFZ), and the truncal zone (TZ), as well as
the irregular polygonal network of the proper gastric veins.
61. 2.Extraparietal Veins
• The extrinsic veins drain into the locally corresponding large vessels: the inferior
and superior thyroid veins,the azygos and hemiazygos veins, and the gastric and
splenic veins.
• One point of surgical interest is that because of the proximity to the hilum of the
lung and its lymph nodes, the azygos vein is one of the initial structures to become
involved by extramural spread of tumors of the midesophagus.
• In this situation, the azygos vein may easily be injured during esophageal resection.
In particular, during blunt pull through stripping, injury to this vein is a high-risk
factor for fatal hemorrhage.
• Collateral circulation between the azygos vein and the hemiazygos vein is well
known. However, the hemiazygos, the accessoryhemiazygos, and the superior
intercostal trunks may also form a vessel that does not connect with the azygos
vein.
• The hemiazygos vein, if not ligated out, can be a source of severe bleeding when
the esophagus is resected through a right thoracotomy.
62. Summry of venous drainage
• Intra-oesophageal (Intrinsic) Drainage
– Longitudinally arranged in Submucosa
– Distal end – portal anastamoses
• Extra-oesophageal (Extrinsic) Drainage into locally corresponding veins
– Inf. thyroid (into innominate vein),
– Azygos, hemiazygos
– L gastric & splenic
63.
64. Lymphatic Drainage
• In the proximal third of the esophagus, lymphatics drain
into the deep cervical lymph nodes,
• In the middle third, drainage is into the superior and
posterior mediastinal nodes
(paratracheal, tracheobronchial,carinal, juxtaesophagea
l, and intra-aorticoesophageal lymph nodes).
• The distal-third lymphatics follow the left gastric artery
to the superior gastric, pericardiac,inferior
diaphragmatic lymph nodes and celiac lymph nodes .
65.
66. Special features about lymphatic system of Esoph.
• Lymph capillaries may commence in the tissue spaces of the mucosa
and then unite to form blind endothelial sacculations or channels.
• These initial lymphatics appear to originate exclusively in the region
between the mucosa and the submucosa and form a network of
collecting channels within the submucosa that run parallel to the
organ axis.
• Eventually, the plexuses give off branches that pass the muscle layers
and empty into the collecting subadventitial and surface trunks.
• In contrast to the esophageal veins, all these channels possess
valves.
67. • The concept that lymph flows in the submucosal channels more readily
longitudinally than through the few transverse connections in the muscle and that
only finally does lymph flow through the subadventitial lymphatics and small
ducts into the mediastinal lymph nodes is supported by the clinical observation
that initial tumor spread follows the longitudinal axis of the esophagus within the
submucosa rather than extending in a circular manner.
• A paucity of lymphatics within the lamina mucosa and the abundance of
submucosal lymphatic channels may explain why intramural cancer spreads
predominantly within this layer.
• Unappreciated malignant mucosal lesions may be accompanied by extensive
tumor spread underneath an intact mucosa, and tumor cells may follow the
lymphatic channels for a considerable distance before they pass the muscular
coat to empty into the lymph nodes.
• A tumor-free margin at the resection line,as confirmed from the anatomic point
of view, does not guarantee radical tumor removal. This may be consistent with
the relatively high postoperative recurrence rate at the resection line, including
satellite tumors and metastases in the submucosa far distant from the primary
tumor,even if the margins at the resection line were previously tumor-free.
68. • From clinical observations in cancer patients, one may deduct that
lymph from above the carina flows in a cranial direction into the
thoracic duct or subclavian lymph trunks whereas lymph from
below the carina flows mainly toward the cisterna chyli via the
lower mediastinal, left gastric, and celiac lymph nodes.
• Flow may, however, change under pathologic conditions. When
lymph vessels become blocked and dilated because of tumor
invasion, the valves become incompetent and the flow reverses.
• This explains the retrograde and unexpected spread of some
malignant tumors but limits the value of establishing pathways of
normal flow.
69. Knowledge of the direction of lymph flow and the position of major lymph nodes is essential for
understanding the potential spread of an esophageal malignancy
70. PREVIOUS FIGURE SHOWS—
• Lymph from areas above the tracheal bifurcation drains mostly
toward the neck, and that below the tracheal bifurcation flows
preferentially toward the celiac axis.
• Lymph flow at the bifurcation appears to be bidirectional.
• The dimensions of the lymph nodes are out of scale.
• In the normal, nonmalignant condition,esophageal and
mediastinal lymph nodes are difficult to discern because of their
small diameter of only 3 to 7 mm.
• Lymph nodes that drain the lung are usually bigger and can be
easily visualized by their carbon particle content.
71. Thoracic Duct
• The thoracic duct begins at the proximal end of the cisterna chyli, at the level of the
12th thoracic vertebra,and passes up through the diaphragm via the aortic foramen.
• It then ascends through the posterior mediastinum, between the aorta on its left
and the azygos vein on its right aspect, and continues left dorsal to the esophagus .
• At the level of the 5th thoracic vertebra and just above the arch of the azygos
vein, the thoracic duct inclines to the left to become left side positioned with regard
to the esophagus and spine.
• Then it ascends lateroposteriorly parallel to the trachea and esophagus to convey
the lymph into the bloodstream and terminates at the confluence between the left
subclavian and jugular veins.
• There are, however, numerous anatomic variations.
• The close local relationship of the delicate thoracic duct to the esophagus and
trachea accounts for the occasional injury causing chylothorax during
esophagectomy and cervical anastomosis.
72.
73. Innervation
• Parasympathetic
– Vagus – motor to muscular coats & secretomotor to glands
• Sympathetic
– From cervical & thoracic sympathetic chain
– Contraction of sphincters, wall relaxation, peristalsis
• Intramural
– Combination of all innervation form plexuses & ganglia
– In muscular layers (myenteric or Auerbach’s plexus)
– In submucosa (Meissner plexus)
• The ganglia of Auerbach's plexus arescattered throughout the
entire esophagus and have a variable number of cells.
• However, the concentrationof ganglion cells is greatest in the
terminal esophagus and at the gastroesophageal junction.
74.
75. Esophageal tissues
Wall structure at the esophagogastric junction. The tunica muscularis is composed of both a longitudinal (2a)
and a circular layer (2b). a, muscularis mucosae; b, lamina propria; c, epithelium; G1, esophageal glands;
G2, gastric glands; Ly,lymph vessels; N1, myenteric plexus; N2, submucous nerve plexus.
76. • The mucosa is thick. At the gastro-oesophageal junction, a jagged boundary line
separates the greyish-pink, smooth, oesophageal mucosa from the reddish-pink
gastric mucosa, which is covered by minute bulges and depressions. The tissues
forming the thoracic oesophageal wall, from lumen outwards, are the mucosa
(consisting of epithelium, lamina propria and muscularis mucosae), submucosa,
muscularis externa and adventitia—
A.Mucosa(Tunica Mucosa)--The mucous layer is composed of three components: the
muscularis mucosae, the tunica propria, and the inner lining of nonkeratinizing
stratified squamous epithelium.
1. Muscularis mucosae-- is composed mainly of longitudinal smooth muscle. This
forms the long mucosal folds that run in the longitudinal axis of the tube and
shapes the small transverse ripple folds at the cardia.All these folds disappear on
distention of the esophageal lumen.
At the pharyngeal end of the oesophagus it may be absent or represented only
by sparse, scattered bundles;below this it becomes progressively thicker. The
longitudinal orientation of its cells changes to a more plexiform arrangement
near the gastro-oesophageal junction.
2. Lamina propria(tunica propria)--contains areolar connective tissue, blood
vessels, and lymph channels derived from the lower level of the mucosa.It
contains scattered groups of lymphoid follicles (mucosaassociated lymphoid
tissue), which are especially prominent near the gastro-oesophageal junction.
77. 3. Epithelium--non-keratinized, stratified squamous
epithelium, continuous with that of the oropharynx.quite
thick (300–500 μm). At the base of the epithelium there is a
basal lamina, to which epithelial cells are attached by
hemidesmosomes.
Langerhans cells--Langerhans cells are present in the
oesophageal epithelium. They are immature dendritic cells
and resemble those found in the epidermis. They perform
similar antigen-processing and antigen-presenting
roles, which are important in immunostimulation of naive T
cells and mucosal defence.
78. B. Submucosa--The submucosa loosely connects the
mucosa and the muscularis externa. It contains larger
blood vessels, nerves and mucous glands. Its elastic
fibres are important in the reclosure of the oesophageal
lumen after peristaltic dilatation
Oesophageal glands--Oesophageal glands are small
tubuloacinar glands lying in the submucosa, each group
sending a single long duct through the intervening layers
of the gut wall to the surface. They are composed mostly
of mucous cells, although they also contain serous cells
that secrete lysozyme.
79. C. Muscularis externa
• The muscularis externa is up to 300 μm thick, and consists of the outer
longitudinal and inner circular layers typical of the intestine. The
longitudinal layer is generally thicker than the circular layer.
• The longitudinal fibres form a continuous coat around almost the
entire length of the oesophagus, except that, posterosuperiorly, 3–4
cm below the cricoid cartilage, they diverge as two fascicles that
ascend obliquely to the anterior aspect of the oesophagus.
• Here, they pass deep to the lower border of the inferior
constrictor, and end in a tendon that is attached to the upper part of
the ridge on the back of the cricoid lamina.
• The V–shaped space(Laimer's triangle) between these fascicles is filled
by the circular muscle fibres of the oesophagus, which are thinly
covered below by some decussating longitudinal fibres and above by
the overlapping inferior constrictor.
80.
81. Schematic drawing of the structures at the pharyngoesophageal junction seen from the
posterior aspect. The location of Killian's and Laimer's triangles is indicated; Zenker's diverticula
develop cranial to the cricopharyngeal muscle, and the upper esophageal sphincter is located
caudal to the V-shaped area of Killian.
82. Muscle Types: Striated Versus Smooth
• striated musculature in the pharynx and particularly in the
cricopharyngeal muscle, which is the upper esophageal sphincter
muscle (UES).
• The first sparse smooth muscle fascicles appear 2 to 3 mm caudal to
the UES.
• Farther caudally, progressively more and more smooth muscle
bundles replace the striated muscle in both the external and
internal layers.
• The transition between both types is neither abrupt nor confined to
individual muscle bundles and lacks any distinct anatomic border.
• Caudal to the tracheal bifurcation, no striated muscle elements are
seen any more.
• With regard to sphincter function, it might be of interest to be
aware that the muscle type of the UES differs completely from that
of the LES!
83. The diagram shows the distribution of striated and smooth
muscle in adult esophagus
84. Development of the oesophagus
• At a very early period
the stomach is
separated from pharynx
by a mere constriction
from primitive pharynx.
This constriction is
future esophagus.
85. • Previous to this elongation the
trachea and oesophagus form
a single structure.
• This becomes divided into two
by the in growth of two lateral
septa, which fuse giving rise to
trachea in front and
oesophagus behind.
• At this stage the oesophagus
becomes converted into a
solid rod of cells, losing its
tubular nature.
• This eventually becomes
canalised to form a tube.
86. Common Congenital Tracheo-esophageal anomalies
• Oesophago-tracheal fistula
– Commonest type
– Newborn has violent fits of
vomiting & coughing on
swallowing
– Polyhydraminos
• Partial Obstruction of
Oesophaugs
– Stricture
– Atresia
– newborn salivates excessively,
becomes cyanotic and vomits