The area of the vocal cords lacks lymphatic drainage, making it a lymphatic boundary. The upper portion above the vocal cords drains to the deep cervical nodes through vessels that penetrate the thyrohyoid membrane. The lower portion below the vocal cords drains to the pre-laryngeal, pre-tracheal, and inferior deep cervical nodes. The aryepiglottic and vestibular folds have a significant lymphatic drainage and are prone to early metastasis.

Anatomy of the Larynx

The larynx is located in the front of the neck, between the third and sixth cervical vertebrae. It is made up of several cartilaginous segments, including the paired arytenoid, corniculate, and cuneiform cartilages, as well as the single thyroid, cricoid, and epiglottic cartilages. The cricoid cartilage forms a complete ring. The laryngeal cavity extends from the laryngeal inlet to the inferior border of the cricoid cartilage and is divided into three parts: the laryngeal vestibule, the laryngeal ventricle, and the infraglottic cavity.

The vocal folds, also known as the true vocal cords, control sound production. They consist of the vocal ligament and the vocalis muscle, which is the most medial part of the thyroarytenoid muscle. The glottis is composed of the vocal folds, processes, and rima glottidis, which is the narrowest potential site within the larynx.

The larynx is also home to several muscles, including the posterior cricoarytenoid, lateral cricoarytenoid, thyroarytenoid, transverse and oblique arytenoids, vocalis, and cricothyroid muscles. These muscles are responsible for various actions, such as abducting or adducting the vocal folds and relaxing or tensing the vocal ligament.

The larynx receives its arterial supply from the laryngeal arteries, which are branches of the superior and inferior thyroid arteries. Venous drainage is via the superior and inferior laryngeal veins. Lymphatic drainage varies depending on the location within the larynx, with the vocal cords having no lymphatic drainage and the supraglottic and subglottic parts draining into different lymph nodes.

Overall, understanding the anatomy of the larynx is important for proper diagnosis and treatment of various conditions affecting this structure.

The oxygen dissociation curve can be shifted to the left by low pCO2, which increases haemoglobin’s affinity for oxygen and makes it less likely to release oxygen to the tissues. In contrast, acidosis, hypercapnia, and hyperthermia cause a right shift of the curve, making it easier for oxygen to be released to the tissues. Raised levels of 2,3-diphosphoglycerate also shift the curve to the right by inhibiting oxygen binding to haemoglobin.

Understanding the Oxygen Dissociation Curve

The oxygen dissociation curve is a graphical representation of the relationship between the percentage of saturated haemoglobin and the partial pressure of oxygen in the blood. It is not influenced by the concentration of haemoglobin. The curve can shift to the left or right, indicating changes in oxygen delivery to tissues. When the curve shifts to the left, there is increased saturation of haemoglobin with oxygen, resulting in decreased oxygen delivery to tissues. Conversely, when the curve shifts to the right, there is reduced saturation of haemoglobin with oxygen, leading to enhanced oxygen delivery to tissues.

The L rule is a helpful mnemonic to remember the factors that cause a shift to the left, resulting in lower oxygen delivery. These factors include low levels of hydrogen ions (alkali), low partial pressure of carbon dioxide, low levels of 2,3-diphosphoglycerate, and low temperature. On the other hand, the mnemonic ‘CADET, face Right!’ can be used to remember the factors that cause a shift to the right, leading to raised oxygen delivery. These factors include carbon dioxide, acid, 2,3-diphosphoglycerate, exercise, and temperature.

Understanding the oxygen dissociation curve is crucial in assessing the oxygen-carrying capacity of the blood and the delivery of oxygen to tissues. By knowing the factors that can shift the curve to the left or right, healthcare professionals can make informed decisions in managing patients with respiratory and cardiovascular diseases.

The patient’s blood gas analysis shows a lower oxygen pressure by about 10kPa than the percentage of oxygen. The PaCo2 level is 3.5, indicating respiratory alkalosis or compensation for metabolic acidosis. The HCO3- level is 18.6, which suggests metabolic acidosis or metabolic compensation for respiratory alkalosis. These results indicate that the patient has metabolic acidosis with complete respiratory compensation. Additionally, the patient’s high blood glucose level suggests that the metabolic acidosis is due to diabetic ketoacidosis.

Arterial Blood Gas Interpretation: A 5-Step Approach

Arterial blood gas interpretation is a crucial aspect of patient care, particularly in critical care settings. The Resuscitation Council (UK) recommends a 5-step approach to interpreting arterial blood gas results. The first step is to assess the patient’s overall condition. The second step is to determine if the patient is hypoxaemic, with a PaO2 on air of less than 10 kPa. The third step is to assess if the patient is acidaemic (pH <7.35) or alkalaemic (pH >7.45).

The fourth step is to evaluate the respiratory component of the arterial blood gas results. A PaCO2 level greater than 6.0 kPa suggests respiratory acidosis, while a PaCO2 level less than 4.7 kPa suggests respiratory alkalosis. The fifth step is to assess the metabolic component of the arterial blood gas results. A bicarbonate level less than 22 mmol/l or a base excess less than -2mmol/l suggests metabolic acidosis, while a bicarbonate level greater than 26 mmol/l or a base excess greater than +2mmol/l suggests metabolic alkalosis.

To remember the relationship between pH, PaCO2, and bicarbonate, the acronym ROME can be used. Respiratory acidosis or alkalosis is opposite to the pH level, while metabolic acidosis or alkalosis is equal to the pH level. This 5-step approach and the ROME acronym can aid healthcare professionals in interpreting arterial blood gas results accurately and efficiently.

When alveolar haemorrhage takes place, the TLCO typically rises as a result of the increased absorption of carbon monoxide by haemoglobin within the alveoli.

Understanding Transfer Factor in Lung Function Testing

The transfer factor is a measure of how quickly a gas diffuses from the alveoli into the bloodstream. This is typically tested using carbon monoxide, and the results can be given as either the total gas transfer (TLCO) or the transfer coefficient corrected for lung volume (KCO). A raised TLCO may be caused by conditions such as asthma, pulmonary haemorrhage, left-to-right cardiac shunts, polycythaemia, hyperkinetic states, male gender, or exercise. On the other hand, a lower TLCO may be indicative of pulmonary fibrosis, pneumonia, pulmonary emboli, pulmonary oedema, emphysema, anaemia, or low cardiac output.

KCO tends to increase with age, and certain conditions may cause an increased KCO with a normal or reduced TLCO. These conditions include pneumonectomy/lobectomy, scoliosis/kyphosis, neuromuscular weakness, and ankylosis of costovertebral joints (such as in ankylosing spondylitis). Understanding transfer factor is important in lung function testing, as it can provide valuable information about a patient’s respiratory health and help guide treatment decisions.

The Epley manoeuvre is a treatment for BPPV, while the Dix-Hallpike manoeuvre is used for diagnosis. The Epley manoeuvre aims to move fluid in the inner ear to dislodge otoliths, while the Dix-Hallpike manoeuvre involves observing the patient for nystagmus when swiftly lowered from a sitting to supine position. Tinel’s sign is positive in those with carpal tunnel syndrome, where tapping the median nerve over the flexor retinaculum causes paraesthesia. The Trendelenburg test is used to assess venous valve competency in patients with varicose veins.

Benign paroxysmal positional vertigo (BPPV) is a common cause of vertigo that occurs suddenly when there is a change in head position. It is more prevalent in individuals over the age of 55 and is less common in younger patients. Symptoms of BPPV include dizziness and vertigo, which can be accompanied by nausea. Each episode typically lasts for 10-20 seconds and can be triggered by rolling over in bed or looking upwards. A positive Dix-Hallpike manoeuvre, which is indicated by vertigo and rotatory nystagmus, can confirm the diagnosis of BPPV.

Fortunately, BPPV has a good prognosis and usually resolves on its own within a few weeks to months. Treatment options include the Epley manoeuvre, which is successful in around 80% of cases, and vestibular rehabilitation exercises such as the Brandt-Daroff exercises. While medication such as Betahistine may be prescribed, it tends to have limited effectiveness. However, it is important to note that around half of individuals with BPPV may experience a recurrence of symptoms 3-5 years after their initial diagnosis.

Kartagener’s syndrome is a condition that can lead to bronchiectasis due to a defect in the cilia, which impairs the lungs’ ability to clear mucus. Bronchiectasis is diagnosed when a person produces large amounts of sputum daily, experiences haemoptysis, and loses weight. While other conditions may cause tiredness, weight loss, or haemoptysis, they are not typically associated with bronchiectasis.

Understanding Kartagener’s Syndrome

Kartagener’s syndrome, also known as primary ciliary dyskinesia, is a rare genetic disorder that was first described in 1933. It is often associated with dextrocardia, which can be detected through quiet heart sounds and small volume complexes in lateral leads during examinations. The pathogenesis of Kartagener’s syndrome is caused by a dynein arm defect, which results in immotile cilia.

The features of Kartagener’s syndrome include dextrocardia or complete situs inversus, bronchiectasis, recurrent sinusitis, and subfertility. The latter is due to diminished sperm motility and defective ciliary action in the fallopian tubes. It is important to note that Kartagener’s syndrome is a rare disorder, and diagnosis can be challenging. However, early detection and management can help improve the quality of life for those affected by this condition.

It is unlikely that direct injury would result in the elevation of the left hemidiaphragm, especially since there is no history of trauma or surgery. However, damage to the long thoracic nerve could cause winging of the scapula due to weakened serratus anterior muscle. On the other hand, injury to the thoracodorsal nerve, which innervates the latissimus dorsi muscle, can lead to weakened shoulder adduction and is a common complication of axillary surgery.

The Phrenic Nerve: Origin, Path, and Supplies

The phrenic nerve is a crucial nerve that originates from the cervical spinal nerves C3, C4, and C5. It supplies the diaphragm and provides sensation to the central diaphragm and pericardium. The nerve passes with the internal jugular vein across scalenus anterior and deep to the prevertebral fascia of the deep cervical fascia.

The right phrenic nerve runs anterior to the first part of the subclavian artery in the superior mediastinum and laterally to the superior vena cava. In the middle mediastinum, it is located to the right of the pericardium and passes over the right atrium to exit the diaphragm at T8. On the other hand, the left phrenic nerve passes lateral to the left subclavian artery, aortic arch, and left ventricle. It passes anterior to the root of the lung and pierces the diaphragm alone.

Understanding the origin, path, and supplies of the phrenic nerve is essential in diagnosing and treating conditions that affect the diaphragm and pericardium.

The patient is displaying symptoms of labyrinthitis, which affects both the vestibular nerve and labyrinth, resulting in vertigo and hearing impairment. In contrast, pure vestibular neuritis only causes vestibular symptoms without affecting hearing. Benign paroxysmal positional vertigo (BPPV) involves otolith displacement and is triggered by head position changes, which is not the case for this patient’s constant vertigo. Facial nerve palsy primarily causes facial drooping and does not affect hearing or vestibular function, making it an unlikely diagnosis for this patient.

Understanding Viral Labyrinthitis

Labyrinthitis is a condition that affects the membranous labyrinth, which includes the vestibular and cochlear end organs. It can be caused by a viral or bacterial infection, or it may be associated with systemic diseases. Viral labyrinthitis is the most common form of the condition.

It’s important to distinguish labyrinthitis from vestibular neuritis, which only affects the vestibular nerve and doesn’t cause hearing impairment. Labyrinthitis, on the other hand, affects both the vestibular nerve and the labyrinth, resulting in both vertigo and hearing loss.

The condition typically affects people between the ages of 40 and 70 and is characterized by an acute onset of symptoms, including vertigo, nausea and vomiting, hearing loss, and tinnitus. Patients may also experience gait disturbance and fall towards the affected side.

Diagnosis is based on a patient’s history and examination, which may reveal spontaneous unidirectional horizontal nystagmus towards the unaffected side, sensorineural hearing loss, and an abnormal head impulse test.

While episodes of labyrinthitis are usually self-limiting, medications like prochlorperazine or antihistamines may help reduce the sensation of dizziness. Understanding the symptoms and management of viral labyrinthitis can help patients seek appropriate treatment and manage their condition effectively.

Acute Treatment of Asthma

When dealing with acute asthma, the initial approach should be SOS, which stands for Salbutamol, Oxygen, and Steroids (IV). It is also important to organize a CXR to rule out pneumothorax. If the patient is experiencing bronchoconstriction, further efforts to treat it should be considered. If the patient is tiring or has a silent chest, ITU review may be necessary. Magnesium is recommended at a dose of 2 g over 30 minutes to promote bronchodilation, as low magnesium levels in bronchial smooth muscle can favor bronchoconstriction. IV theophylline may also be considered, but magnesium is typically preferred. While IV antibiotics may be necessary, promoting bronchodilation should be the initial focus. IV potassium may also be required as beta agonists can push down potassium levels. Oral prednisolone can wait, as IV hydrocortisone is already part of the SOS approach. Non-invasive ventilation is not recommended for the acute management of asthma.

Insertion of a chest drain poses a risk of damaging the long thoracic nerve, which runs from the neck to the serratus anterior muscle. This can result in weakness or paralysis of the muscle, causing a winged scapula that is noticeable along the medial border of the scapula. It is important to use aseptic technique during the procedure to prevent hospital-acquired pleural infection. Chylothorax, pneumothorax, and pyothorax are all conditions that may require chest drain insertion, but they are not known complications of the procedure. Therefore, these options are not applicable.

Anatomy of Chest Drain Insertion

Chest drain insertion is necessary for various medical conditions such as trauma, haemothorax, pneumothorax, and pleural effusion. The size of the chest drain used depends on the specific condition being treated. While ultrasound guidance is an option, the anatomical method is typically tested in exams.

It is recommended that chest drains are placed in the safe triangle, which is located in the mid axillary line of the 5th intercostal space. This triangle is bordered by the anterior edge of the latissimus dorsi, the lateral border of pectoralis major, a line superior to the horizontal level of the nipple, and the apex below the axilla. Another triangle, known as the triangle of auscultation, is situated behind the scapula and is bounded by the trapezius, latissimus dorsi, and vertebral border of the scapula. By folding the arms across the chest and bending forward, parts of the sixth and seventh ribs and the interspace between them become subcutaneous and available for auscultation.

References:
– Prof Harold Ellis. The applied anatomy of chest drains insertions. British Journal of hospital medicine 2007; (68): 44-45.
– Laws D, Neville E, Duffy J. BTS guidelines for insertion of chest drains. Thorax, 2003; (58): 53-59.