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Year 1 Anatomy of the Thorax > Heart and great vessels > Flashcards

Flashcards in Heart and great vessels Deck (47)
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1
Q

What are the great veins?

A

Superior vena cava. Inferior vena cava.

2
Q

What is a tributary? Versus a branch?

A

A tributary is a vessel of a vein flowing INTO a larger one. Branches describe arteries usually – i.e. vessels that supply tissues/organs.

3
Q

What is the anatomy of the superior vena cava in the mediastinum – tributaries and positions?

A

SVC: enters right atrium from above. To the right of the aorta. Formed from asymmetric union of the right and left brachiocephalic (broken down = ‘arm’ then ‘head’) veins. Each brachiocephalic vein forms from an internal jugular vein and a subclavian vein. The internal jugular veins come from the head, and the subclavian veins come from the upper limbs. Left brachiocephalic vein crosses the POSTERIOR region of the manubrium to join the SVC.

4
Q

What is the position of the inferior vena cava in the mediastinum?

A

IVC: enters right atrium from below through the CENTRAL TENDON of the diaphragm at T8.

5
Q

What are the azygos veins?

A

Azygos means asymmetric. Drain the posterior wall of the thorax and abdomen. ARCHES OVER RIGHT LUNG ROOT TO DRAIN INTO THE SVC. Has many branches (posterior intercostal veins) at the posterior of the chest next to vertebrae. These branches are asymmetric, with most on right side of the body. The only branches on the left side are accessory hemiazygos vein and hemiazygos vein – they cross the thoracic vertebral bodies to join the azygos vein on the right. Emerge through the diaphragm at T10. The arrangement of this venous system is VARIABLE.

6
Q

What are the relations of the azygos vein to the great vessels in the superior mediastinum?

A

Azygos is very posterior. Bends anteriorly, above the right pulmonary vein into the SVC – enters posteriorly where the S is, in the third picture.

7
Q

What are the branches of the ascending aorta and aortic arch?

A

Ascending aorta: right and left coronary arteries (end arteries supplying heart muscle). The ascending aorta supplies the coronary arteries because ascending aorta contains most oxygenated blood. Aortic arch: brachiocephalic trunk – divides into right common carotid and right subclavian arteries. Left common carotid artery. Left subclavian artery. There’s no left brachiocephalic trunk, hence – the right brachiocephalic trunk is not assigned with ‘right’, and just called brachiocephalic trunk. Carotid – goes to the head. Subclavian – goes to the upper limbs. NOTE that the brachiocephalic trunk lie behind the sternum and lies in the MIDLINE.

8
Q

What is the relationship of the aorta to the rest of the thorax?

A

Ascending aorta emerges from the left ventricle on the right side of the heart. It rises anterior to trachea (trachea lies anterior to oesophagus), and arches over the left main bronchus at the lung root at T4. Trachea therefore is posterior to, and between the brachiocephalic and left common carotid arteries. Descending aorta is posterior the oesophagus. Th arch goes over the right pulmonary artery also.

9
Q

How do the common carotids branch?

A

Divide into the external and internal carotids high in the neck. These are the main arteries of the head and neck – with the vertebral arteries from the subclavian arteries).

10
Q

What is the anatomy of the pulmonary trunk?

A

Outflow from right ventricle. Lies left of the ascending aorta and bifurcates posteriorly to the left and right pulmonary arteries (bifurcates anterior to the descending aorta, and inferior to the aortic arch.

11
Q

What ligamentous structure is associated with the pulmonary trunk and aortic arch?

A

LIGAMENTUM ARTERIOSUM connects pulmonary trunk to the aortic arch and is remnant of the ductus arteriosus – bypasses lungs in foetal life.

12
Q

What is the pericardium?

A

A fibroserous sac surrounding the heart and its great vessels – leading up to and terminating at the exit of the aorta. The fibrous layer is attached to and blends in with the walls of the great vessels.

13
Q

What are the layers of the pericardium?

A

Two layers. Fibrous pericardium outside. Serous pericardium inside – has a parietal (lines fibrous) layer, and visceral (adheres to the heart) layer.

14
Q

What are the two main pericardial sinuses?

A

Transverse pericardial sinus – Separates the arteries and the veins. Oblique pericardial sinus – Where the serous pericardium visceral layer is reflecting back on itself to become the parietal layer. This reflection occurs on the pulmonary veins. Can be reached by placing a hand under the apex and moving hand superiorly. Remember, the sinuses are found on the outside of the heart – the pericardium is not found inside the heart.

15
Q

What is the embryology of the pericardial sinuses?

A

Heart begins as a tube. The venous end turns upwards during development (hence why most of the vessels in the heart emerge from the top, and the bottom of the heart is just attached to the diaphragm). When these primordial venous and arterial ends are brought together, the transverse pericardial sinus is formed – hence why this is the sinus that separates the arteries and veins. Meanwhile, the veins expand and pericardial reflection (visceral -> parietal) is carried out around them to form oblique pericardial sinus.

16
Q

How is the pericardium supplied with blood?

A

Internal thoracic, pericardiophrenic, musculophrenic and inferior phrenic arteries. And descending aorta.

17
Q

How is the pericardium innervated?

A

Vagus nerve (cranial nerve X).

18
Q

How does blood travel through the heart – BASICS?

A

Into right atrium from pulmonary circulation – via pulmonary veins. etc. etc.

19
Q

What are the anatomical features of the right atrium?

A

Found almost posteriorly. Valve is the atrioventricular valve – called tricuspid valve. The two entry points for the vena cava are INLETS – and are aligned with each other such that if you dropped something through the superior vena cava, it would go through the atrium and straight into the inferior vena cava. Both have valves. The opening of the coronary sinus is found at the IVC inlet, and returns blood from the coronary arteries – also has a valve. There’s also small opening of the small cardiac veins scattered along the walls of the RA which drain the myocardium directly. There is a small window in the medial wall called the fossa ovalis (remnant of the foramen ovale). Foramen ovale is present in a foetus and permits passage of blood from the left right to left atrium to bypass the pulmonary circulation. This the first opportunity to bypass the lungs – the second opportunity is called the ligamentum arteriosum. Crista terminalis: The line of union between the right atrium and the right atrial appendage (pouch-like extension of the pectinate muscles), present on the interior of the atrium. The crista terminalis is generally a smooth-surfaced, thick portion of heart muscle. The photo shows the muscle wall REFLECTED, so the crista terminalis is the entire length of the structure that looks like the border. Musculi pectinate are parallel ridges in the walls of the atria of the heart which fan from the crista. Right auricle – the space anterior to the crista and is just a space in the right atrium. IN RELATION TO THE PHOTO: limbus is a border.

20
Q

What are the anatomical features of the left atrium?

A

Lies to the posterior of the heart, below where the pulmonary trunk bifurcates. There is an atrioventricular valve also – called the mitral valve. Once again, there is the fossa ovalis. Left auricle.

21
Q

What are the anatomical features of the right ventricle?

A

Right ventricle receives blood from the right atria. Pumps blood through the semilunar, pulmonary valves to the lungs. Conus arteriosus – the outflow tract of the right ventricle which leads to the pulmonary trunk. Trabeculae carneae (also called papillary muscles) – net-like structure of the muscular wall found in the inflow portion of the RV and are irregular muscular structures – forms RIDGES and BRIDGES. SOME of these are involved in the valve. Anatomy of the tricuspid valve and pulmonary valve in relation to the ventricle are found in next questions. Septomarginal trabecula – specialised trabeculum forms a bridge between the anterior papillary muscle and interventricular septum and carries a portion of the cardiac conduction to the anterior wall of the RV.

22
Q

What is the anatomical features of the left ventricle?

A

Atrioventricular valve has two cusps called the mitral valve. Anatomy of the valve found in another question. Trabeculae carneae is the net-like structure of the muscular wall – some become part of the AV valve. Forms ridges (connected to ventricular wall across entire surface) and bridges (connected to ventricular wall at two ends). They differ from the RV – in the LV, they are more delicate and finer. Anatomy of the mitral valve and aortic valve in relation to the ventricle are found in next questions.

23
Q

What is the structure of the tricuspid valve and mitral valve?

A

Remember the number and names of the cusps. The cusps of both valves are tethered to the walls of the ventricle by chordae tendineae via projections called papillary muscles (trabeculae careae). Prevents eversion of the AV valve in the atrial direction, so the muscles and chordae tendineae keep the valves closed during ventricular contraction. The papillary muscles in the LV are larger than in the RV valve.

24
Q

What is the structure of the semilunar valves in the pulmonary trunk and aorta?

A

Contain three cusps, which are small sinuses – three pockets.

AORTIC VALVE: In the walls of two of the aortic are two holes – called coronary sinuses – not to be confused with the coronary sinus. These are the openings for the left and right coronary arteries. The sinus with the coronary sinuses inside are called the coronary-aortic sinuses. The sinus without a coronary sinus inside is called the non-coronary-aortic sinus.

25
Q

What is the function of the semilunar sinuses? (x2)

A

The concave nature of the valve and the space created by the sinuses prevent valves from sticking to vessel walls because of the force of ejection. This occurs because blood swirls behind the opening valve. In the case of the aortic valve, it also an area where blood is taken into the coronary arteries.

26
Q

What is the anatomy of the arterial part of the coronary circulation? Variation?

A

Left and right coronary arteries emerge from the aorta. Interventricular coronary arteries – between ventricles. Marginal arteries – go across margins. Circumflex – go back on themselves.

Left coronary artery branches off into the circumflex branch and anterior interventricular branch. These each branch off also – see diagram. Right coronary artery branches off into an early atrial branch (which gives off the sino-atrial nodal branch), a right marginal branch, and the posterior interventricular branch. There is variation about where the posterior interventricular branch arises – can arise from the right coronary artery (called right dominant coronary artery), or the circumflex branch of the left coronary artery. Left dominant coronary artery is LESS common. Try and remember all the names in the photo.

27
Q

What does the posterior interventricular branch of the coronary arteries supply in 80% of people?

A

The AVN.

28
Q

What is the anatomy of the venous part of the coronary circulation?

A

Veins follow the arteries. Drain into the coronary sinus – sit between left atrium and left ventricle.

29
Q

What is the anatomy of the conduction system of the heart?

A

Do not need to focus on this heavily – will talk about this in Cardiovascular System.

30
Q

What is the anatomical course of the spread of electrical excitation through the chambers of the heart?

A

Begins in SAN. Spreads across atria causing contraction. Concurrently, wave stimulates AVN. AVN imposes a small delay, then travels through the bundle of His. Then along the bundle branches, through Purkinje fibres, causing ventricular contraction.

31
Q

What are the lymphatics of the heart?

A

Follow the coronary arteries. Drain mainly into the brachiocephalic nodes anterior to the brachiocephalic veins, and the tracheobronchial nodes, inferior end of the trachea.

32
Q

What are the surface markings of the heart?

A

Marked by the following: 1. Just lateral to right sternal border at the 3rd CC (not ICS). 2. Just lateral to right sternal border at the 6th CC. 3. At the position of the apex beat, just medial to the mid-clavicular line in the 5th left ICS. 4. Lateral (about 2.5cm) to the left sternal border at the 2nd CC.

33
Q

What is the apex beat?

A

A pulsation caused by the apex of the left ventricle of the heart when it is forced against the anterior chest wall during contraction.

34
Q

How is the apex beat palpated?

A

4th ICS (children) and 5th ICS (adults). 6-10cm from the midsternal line. Palpate with the palm and middle three fingers of the right hand, aligning the middle finger with the left 5th ICS and other two fingers above and below. Start palpating from the MAL and move anteriorly towards the MCL. MALES: nipple is in the 4th ICS just lateral to the MCL. FEMALES: hand should be laid BENEATH the breast along its lower border.

35
Q

How does the size of the heart differ in a PA and AP X-ray?

A

When it is viewed in the AP X-ray, heart appears bigger because the X-rays deviate and move outwards earlier because the heart is anterior. There’s also more X-rays that reach the heart because it is one of the first things that the X-rays touch. In a PA X-ray, heart is SMALLER because X-rays reach the heart last, so have less opportunity to spread out when it reaches the heart, and there’s less X-rays involved as many would have been absorbed by the vertebrae.

36
Q

What is angina pectoris?

A

Where chest pain is caused by transient ischaemia of the myocardium resulting from narrowing of the coronary arteries.

37
Q

What is myocardial infarction?

A

Caused by occlusion of the coronary artery and necrosis of part of the myocardium.

38
Q

What are the surface markings of the aorta?

A

Arch begins at the level of the right 2nd CC and ends at the level of the left 2nd CC. Top of the arch is midway between the jugular notch and sternal angle.

39
Q

What are the surface markings of the main branches of the aorta?

A

BRACHIOCEPHALIC TRUNK: superolaterally from the aortic arch to the right sternoclavicular joint. Divides into the right subclavian and right common carotid behind the sternoclavicular joint. RIGHT SUBCLAVIAN ARTERY: draw a line laterally from the right sternoclavicular joint arching over the first rib. RIGHT COMMON CAROTID ARTERY: ascends into the neck on the right side of the trachea. Subject should turn their head to the left so that the right sternocleidomastoid muscle becomes visible. The RCC lies below this muscle – draw up to the ear lobe. LEFT COMMON CAROTID ARTERY: Slightly POSTERIOR and left from the brachiocephalic. Subject should turn head to the right and draw a line from the aortic arch towards the sternoclavicular joint and up the SCM muscle to the left ear lobe. LEFT SUBCLAVIAN ARTERY: draw line laterally from the left sternoclavicular joint, arching over the left first rib.

40
Q

How are the great veins surface marked?

A

RIGHT AND LEFT INTERNAL JUGULAR VEINS: draw lines just lateral to the common carotids to reach the sternoclavicular joints. RIGHT AND LEFT SUBCLAVIAN VEINS: draw lines parallel to the subclavian ARTERIES to meet the internal jugular veins. The subclavian and internal jugular veins unite to form the brachiocephalic veins. RIGHT BRACHIOCEPHALIC: draw a line from the right sternoclavicular joint to the inferior border of the right 1st CC – not palpable. LEFT BRACHIOCEPHALIC: draw a line from the left sternoclavicular joint to the inferior border of the right 1st CC which runs behind the manubrium from left to right. The right and left brachiocephalic veins unite behind the right 1st CC to form the SVC. SUPERIOR VENA CAVA: draw a line from the right 1st CC to the right 3rd CC running behind the right side of manubrium and sternum to join the right atrium.

41
Q

Where are the heart valves located in relation to the surface anatomy?

A

All behind the sternum. Pulmonary = 3rd CC; Mitral – 4th CC; Aortic = 3rd ICS; Tricuspid = 4th ICS. Indicated by the black lines and blue circles in the image.

42
Q

What is the ‘lub’ and ‘dub’ caused by?

A

LUB = closure of the AV valves. DUB = closure of the semi-lunar valves.

43
Q

What is the nature of auscultation when you place the stethoscope on the chest? (x2)

A

BOTH lub and dub will be heard if the stethoscope is applied anywhere on the anterior chest wall. The sound produced by a given valve is carried by the blood stream along the direction of flow. Placing the stethoscope superficial to the blood filled space DOWNSTREAM of the given valve may allow the sound of that valve to be distinguished clearly from sounds of other valves.

44
Q

How are each of the valves auscultated?

A

TRIUSPID: left 5th ICS near the sternum – because this is the direction the blood is pumped from the RA to the RV. MITRAL: lefts 5th ICS at the MCL = apex beat. PULMONARY: left 2nd (or 3rd) ICS near the sternum. AORTIC: right 2nd ICS near the sternum.

45
Q

Why are the aortic and pulmonary valve auscultations in the opposite position to their ventricles?

A

Note: their valves are also in the opposite orientation to their ventricles. Because the direction of the ascending aorta and the pulmonary trunk is the opposite to their ventricles – so the downstream blood flow is in the opposite direction – so valve sounds auscultated in opposite sides also.

46
Q

What is pericarditis?

A

Inflammatory condition of the pericardium. Complain of continuous chest pain that may radiate to the upper limbs – so similar symptoms to heart attack. The pain, unlike STEMI, can be relieved by leaning forward. Can be found inside or outside the pericardium.

47
Q

What is cardiac tamponade?

A

Cardiac tamponade, also known as pericardial tamponade, is when fluid in the pericardium (the sac around the heart) builds up in the pericardial space. The outer layer of the heart is made of fibrous tissue which does not easily stretch, so once fluid begins to enter the pericardial space, pressure starts to increase. As fluid continues to accumulate, each successive diastolic period leads to less blood entering the ventricles.