thoracic clinical cases copy Flashcards
role of costal cartilages
-prolong the ribs anteriorly and contribute to elasticity of the thoracic wall
-prevents many blows from fracturing the sternum and/or ribs
-in elderly people, costal cartilage undergo calcification making them radiopaque and less resilient
rib fractures
-weakest part of rib is just anterior to its angle
-rib fracture commonly result from direct blows or indirectly from crushing injuries
-middle ribs are most commonly fractured
-direct violence may fracture rib anywhere
-broken ends may injury internal organs such as lung or spleen
-segmental
flail chest
-occurs when a sizable segment of the anterior and/or lateral thoracic wall moves freely bc of multiple rib fractures
-condition allows loose segment of the wall to move paradoxically (inward on inspiration and outward on expiration)
-extremely painful
-impairs ventilation-> affecting oxygenation of blood
-during treatment the loose segment may be internally fixed with plates or wires to prevent movement
-greater pulmonary contusion with flail compared to segmental
supernumerary ribs
-12 ribs on each side but the number may be increased by the presence of cervical and/or lumbar ribs or decreased by failure of 12th pair to form
-cervical ribs- articulate with C7 and are clinically significant bc they may compress spinal nerves C8-T1 or the inferior trunk of the brachial plexus suppling the upper limb
-tingling and numbness may occur along medial border of forearm
-may also compress subclavian artery resulting in ischemic muscle pain in the upper limb
-resection may be required to relieve pressure -> performed through transaxillary approach (incisions in axillary fossa/armpit
-lumbar ribs- less common than cervical ribs but have clinical significance bc you may confuse identification of vertebral levels in images
thoracotomy, intercostal space incisions, and rib excision
-surgical creation of an opening through the thoracic wall to enter a pleural cavity -> thoracotomy
-anterior thoracotomy- may involve making H shaped cuts through perichondrium of one or more costal cartilages (4th and 5th) and then shelling out segments of costal cartilage to gain entrance to the thoracic cavity
-posterior thoracotomy- posterolateral aspects of 5th-7th intercostal spaces are important sites for incisions
-*lateral approach is most satisfactory for entry through thoracic cage with pt lying on contralateral side -> upper limb fully abducted, placing the forearm beside the pts head -> elevated and laterally rotates the inferior angle of scapular, allowing access as high as the 4th intercostal space
single intercostal space thoracotomy
-inferior upper rib- VAN (vein, artery, nerve)
-superior lower rib- NAV
-rib retraction allows for single intercostal space
-care to avoid the superior neurovascular bundle
-if wider exposure is required -> surgeons use H shaped incisions to incise the superficial aspect of the periosteum that surrounds the rib, strip the periosteum from the rib, and then remove a wide segment to gain better example
-in ribs absence -> entry made through deep aspect of the periosteal sheath sparing the adjacent intercostal muscle
-after surgery missing pieces of ribs regenerate from the intact periosteum imperfectly
-intrathoracic surgery can be performed using minimally invasive endoscopic approach
sternal biopsies
-used for bone marrow needle biopsy
-bc of its breadth and subcutaneous position
-needle first pierces the thin cortical bone and then enters the vascular trabecular (spongy) bone
-commonly used to obtain specimens of bone marrow for transplantation and detection of metastatic cancer
surgical entry into thorax
-gain wide access to thoracic cavity for sugical procedures in mediastinum -> sternum divided in the median plane (median sternotomy) and retracted
-after surgery -> halves of sternum are reunited and held together with wire suture
-lateral thoracotomy through intercostal spaces provides wide access to the pulmonary cavities
-minimally invasive thoracic surgery (thoracoscopy) allows access to the thorax through small intercostal incision for many intrathoracic procedures
thoracic outlet syndrome
-clinicians refer to the superior thoracic aperture as the thoracic outlet -> they are emphasizing the important nerves and arteries that pass through this aperture into the lower neck and upper limb
-various types of thoracic outlet syndromes exist ->
-costocalvicular syndrome- pallor and coldness of skin of the upper limb and diminished radial pulse resulting from compression of subclavian artery between the clavicle and 1st rib (particularly when angle between the neck and shoulder is increased)
dislocation of ribs
-slipping rib syndrome
-dislocation of sternocostal joint
-displacement of a costal cartilage from sternum
-causes severe pain particularly during deep respiration
-injury produces lump like deformity at the dislocation site
-common in body contact sports
-possible complications are pressure on or damage to nearby nerves, vessels, and muscles
-rib separation refers to dislocation of costochondral junction- between rib and its costal cartilage
-separations of 3rd-10th ribs -> tearing of perichondrium and periosteum usually occurs -> rib may move superiorly, overriding the rib above and causing pain
paralysis of diaphragm
-detected radiographically by noting its paradoxical movement
-you can auscultate the diaphragm excursion
-paralysis of half the diaphragm bc injury to its motor supply from the phrenic nerve does not affect the other half bc the domes are separately supply by right and left phrenic nerves
-instead of descending on spiration -> paralyzed dome is pushed superiorly by abdominal viscera that are being compressed by active side
-paralyzed dome descends during expiration as it is pushed down by positive pressure in the lungs
sternal fractures
-not common
-crush injuries can occur during traumatic compression of thoracic wall
-concern in sternal injuries is not primarily for the fractures -> heart and/or lung injury
-myocardial contusion, cardiac rupture, tamponade
breast quadrants
-divided into 4 quadrants
-axillary process- extension of mammary gland of superolateral quadrant
change in breasts
-changes like branching of lactiferous ducts occurs throughout menstrual cycle during pregnancy
-mammary glans are prepared for secretion by midpregnancy -> they dont produce milk until shortly after baby is born
-colostrum- creamy white to yellowish premilk fluid- may be secreted during last trimester and during initial episode of nursing
-colostrum believed to be especially rich in protein, immune agents, and growth factor affecting infants intestines
-multiparous women (who have given birth two or more times)- breast often increase in size and pendulous
-breast in elderly usually small bc of decrease in fat and atrophy of glandular tissue
supernumerary breasts and nipples
-supernumerary (exceeding 2) breasts (polymastia) or nipples (polythelia) - may occur superior or inferior to normal breasts
-consist of only a rudimentary nipple and areola
-may appear along a line extending from the axilla to the groin, the location of embryonic mammary crest (ridge)
carcinoma of breast
-understanding lymphatic drainage -> predicting metastasis of cancer
-breast cancer takes a long time to develop -> screening
-usually adenocarcinomas arising from epithelial cells of lactiferous ducts in mammary gland lobules
-metastatic cancer cells enter lymphatic vessel and pass through 2 or 3 groups of lymph nodes before entering venous system
-breast cancer can spread via lymphatics and veins AND direct invasion
-interference with dermal lymphatics by cancer may cause lymphedema -> deviation of nipple and thickened leather like appearance of skin
-prominent/puffy skin between dimpled pores gives it an orange peel appearance -
-larger dimples result from cancerous invasion of the glandular tissue and fibrosis -> causes shortening or places traction on the suspensory ligaments
-subareolar breast cancer- may cause inversion of nipple involving lactiferous ducts
spread of breast cancer
-spread by means of lymphatic vessels (lymphogenic metastasis)
-carry cancer cells from breast to lymph nodes -> usually axilla
-cells lodge in nodes -> nest of tumor cells (metastases)
-communication between axillary, cervical, parasternal nodes -> may cause to spread to supraclavicular lymph nodes, opposite breast, or abdomen
-axillary most common site
-absence of enlargement of axillary nodes does not mean metastasis from breast cancer has not occurred-> may have passed to other nodes such as infra and supra clavicular or directly into circulation
-removal of axillary nodes or damage via radiation/chemo -> lymphedema in ipsilateral upper limb
-posterior intercostal veins drain into azygos/hemiazygos system of veins along bodies of vertebrae and communicate with internal vertebral venous plexus surrounding spinal cord
-cancer cells spread via venous routes to vertebrae -> spinal cord -> brain
-when cancer invades retromammary space -> attach to or invade pectoral fascia overlying -> interpectoral nodes -> advanced cancer of breast
-can spread medially to substernal and paraspinal nodes
