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Precordium
Precordium
Precordium
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In anatomy, the precordium or praecordium is the portion of the body over the heart and lower chest.[1]

Defined anatomically, it is the area of the anterior chest wall over the heart. It is therefore usually on the left side, except in conditions like dextrocardia, where the individual's heart is on the right side. In such a case, the precordium is on the right side as well.

The precordium is naturally a cardiac area of dullness. During examination of the chest, the percussion note will therefore be dull. In fact, this area only gives a resonant percussion note in hyperinflation, emphysema or tension pneumothorax.

Precordial chest pain can be an indication of a variety of illnesses, including costochondritis and viral pericarditis.

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References

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Precordium

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The precordium is the region of the anterior chest wall overlying the heart and the lower portion of the great vessels. Anatomically, it forms a roughly rectangular area over the heart and the lower part of the thorax. This area serves as the external surface through which cardiac activity can be observed and assessed non-invasively. In clinical examination, the precordium is evaluated via inspection, palpation, and auscultation to detect normal and abnormal cardiac movements, sounds, and impulses. A key feature is the point of maximal impulse (PMI), typically located at the fifth intercostal space along the midclavicular line, which corresponds to the apical beat of the left ventricle and measures about 2-3 cm in diameter with a tapping quality in healthy individuals. Precordial impulses represent pulsations from the heart or great vessels that may be visible or palpable, providing insights into ventricular contraction and overall cardiac dynamics. Abnormal precordial findings often signal underlying cardiac conditions; for instance, a displaced or hyperdynamic PMI may indicate left ventricular enlargement or , while sustained or bifid impulses can suggest elevated end-diastolic pressure or . Examination techniques emphasize assessing the , duration, and location of these movements, with additional over parasternal and epigastric regions to identify contributions from right ventricular or aortic activity. Such evaluations are fundamental in diagnosing structural heart diseases, arrhythmias, and hemodynamic abnormalities.

Anatomy

Location and Boundaries

The precordium is the external region overlying the heart on the anterior chest wall, primarily on the left side, and serves as the surface area for clinical assessment of cardiac activity. It typically spans from the second to the fifth intercostal spaces, with the heart's base positioned at the level of the second intercostal space and its apex at the fifth intercostal space along the left midclavicular line. The precise boundaries of the precordium are superiorly limited by the second intercostal space, inferiorly by the sixth intercostal space (particularly along the right border where the heart's projection extends), medially by the sternum, and laterally by the midclavicular line. These landmarks approximate the projection of the heart onto the thoracic surface. In , a rare congenital malformation where the heart is mirrored to the right side of the , the precordium shifts accordingly to the right anterior chest wall, altering the standard left-sided location. The term "precordium" originates from Latin, meaning "before the heart," with the alternative historical spelling "praecordium" occasionally used in medical literature.

Underlying Structures

The precordial region overlies a series of layered anatomical structures that form the anterior , providing protection and facilitating the transmission of cardiac activity to the surface. Superficially, the skin and cover the area, followed by the . Beneath these lie the skeletal muscles, including the anteriorly and the (external, internal, and innermost layers) between the , which contribute to respiratory movements and structural support. The bony framework consists of the (particularly ribs 2 through 5 on the left side, corresponding to the heart's position) and the , with costal cartilages connecting the to the . Deeper layers include the parietal pleura lining the and the , leading to the where the encases the heart. The primary structure beneath the precordium is the heart, a muscular organ positioned in the middle mediastinum with its base oriented posteriorly and apex directed anteriorly and inferiorly toward the left fifth intercostal space. The heart comprises four chambers: the right atrium, which receives deoxygenated blood from the superior and inferior vena cavae and coronary sinus; the right ventricle, which pumps this blood into the pulmonary trunk; the left atrium, which collects oxygenated blood from the pulmonary veins; and the left ventricle, the thickest chamber, which ejects oxygenated blood into the aorta. Major vessels arising from the heart include the ascending aorta, emerging from the left ventricle to supply systemic circulation, and the pulmonary trunk (or pulmonary artery), branching from the right ventricle to deliver deoxygenated blood to the lungs. Adjacent to the heart are several structures that influence its position and function within the thorax. Laterally, portions of the lungs and their covering visceral and parietal pleurae contact the heart's pulmonary surfaces. Inferiorly, the diaphragm forms the boundary, with the heart's diaphragmatic surface resting primarily on the right ventricle. Posteriorly, the lies adjacent to the heart's base, separated by minimal tissue, while the descending and are also in close proximity. In broader definitions of the precordial area extending to the , a portion of the (such as the fundus) may lie indirectly beneath via the diaphragm, though the heart remains the dominant structure. These underlying structures integrate with the thoracic cage to anchor the heart while allowing transmission of mechanical cardiac impulses to the precordial surface. The heart's contractions generate pulsations that propagate through the pericardium, which encases the myocardium and reduces friction, then through the mediastinal pleura, endothoracic fascia, intercostal muscles, and subcutaneous tissues to produce visible or palpable precordial movements, such as the apical impulse from left ventricular motion. This layered transmission enables the thoracic wall to convey subtle cardiac dynamics without significant attenuation in healthy individuals.

Physical Examination

Inspection

Inspection of the precordium involves a systematic visual examination of the anterior chest wall overlying the heart to identify any abnormalities in contour, symmetry, or movement. The patient is positioned or semi-recumbent at 30 to 45 degrees, with the upper body exposed and adequate lighting to enhance visibility, preferably natural side lighting to cast shadows that highlight subtle pulsations or deformities. The examiner observes from the foot of the bed and from the patient's side, scanning for overall chest symmetry, scars, deformities such as or , and any visible pulsations arising from underlying cardiac structures. In healthy individuals, the precordium typically appears symmetric with no prominent deformities or scars, and visible cardiac activity is minimal. A slight leftward bulge may be noted in thin or lean patients due to the heart's natural position, but the apical impulse is generally not visible unless the chest wall is particularly thin, where a gentle flicker or brief outward movement at the fifth in the midclavicular line may occur during . No sustained lifts, heaves, or diffuse pulsations are observed, reflecting normal cardiac function without enlargement or hyperactivity. Abnormal findings during inspection can signal underlying cardiac pathology, such as visible heaves or sustained lifts over the precordium indicating , or prominent retractions of the chest wall suggesting increased intrathoracic pressure from conditions like . or may appear in acutely ill patients, while surgical scars—such as a midline sternotomy from coronary bypass—provide historical clues to prior interventions. Displaced or hyperdynamic pulsations, like a laterally shifted , may hint at , though such observations warrant confirmation via . Patient positioning and respiration influence the visibility of precordial features; in the supine position, left ventricular impulses are more apparent, but deep inspiration can reveal right ventricular movements that are otherwise obscured. Elevating the head of the bed or having the patient sit up may accentuate certain pulsations or deformities, while left lateral decubitus should be avoided to prevent distortion of chest contours. These variations help differentiate normal physiologic shifts from pathologic signs.

Palpation

Palpation of the precordium involves the tactile assessment of the chest wall overlying the heart to evaluate cardiac impulses, using the fingertips or heel of the hand to detect the point of maximal impulse (PMI) and other movements. The patient is positioned supine with the upper body elevated 30–45 degrees and instructed to exhale and hold at end-expiration to optimize detection of impulses. The examiner stands at the patient's right side, beginning palpation over the apex area in the fifth intercostal space at or near the midclavicular line, where the PMI is typically located in adults. Additional areas, such as the left lower sternal border, upper left sternal border, and epigastrium, are palpated systematically using the fingertips for fine vibrations or the palm for broader lifts. In healthy individuals, the PMI presents as a brief, low-amplitude tapping impulse with a of less than 3 cm, lasting less than two-thirds of and peaking early in the systolic phase. This impulse is easily palpable in thin-chested patients but may be subtle or impalpable in those with or , and no or sustained heaves are detected elsewhere on the precordium. Abnormal findings during palpation include heaves, which are sustained lifts or thrusts indicating increased ventricular workload, such as a left ventricular heave from due to pressure overload or a from . are palpable vibratory sensations corresponding to turbulent blood flow, often associated with loud murmurs graded 4/6 or higher, and are assessed by placing the fingertips or ball of the hand over the relevant precordial areas. Displacement of the PMI laterally beyond the midclavicular line or downward suggests , while a double or bifid impulse may indicate . Specific maneuvers enhance palpation sensitivity; for instance, the heel of the right hand is placed along the left sternal border to detect right ventricular impulses, which are normally absent but may become prominent in conditions like . Positioning the patient in the left lateral decubitus enhances appreciation of the apical impulse and its contour, particularly for subtle findings. These techniques allow differentiation of dynamic cardiac motions, complementing visual observations of pulsations.

Percussion

Percussion of the precordium involves indirect percussion, where the middle finger of the nondominant hand (the pleximeter) is firmly placed on the chest surface, and the middle finger of the dominant hand (the plexor) delivers a quick, sharp tap to the distal interphalangeal joint of the pleximeter finger. This technique maps the area of cardiac dullness by percussing systematically across the precordial region, typically starting from areas of resonance (lungs) and moving toward the expected heart borders to identify the transition to a dull note. In normal findings, percussion elicits a dull note over the cardiac silhouette, extending from the right sternal border to the left midclavicular line in the fifth intercostal space, with a transverse span of approximately 6-8 cm. The area of dullness reflects the underlying heart size, though this is influenced by the position and orientation of the cardiac chambers. Determination of the cardiac borders relies on identifying the medial and lateral limits of this dullness: the left border is typically at the midclavicular line (about 7-9 cm from the midsternal line), while the right border lies near or at the sternal edge in the fourth to sixth intercostal spaces. In cases of cardiac enlargement, such as cardiomegaly, the left border shifts laterally beyond the midclavicular line (e.g., >10.5 cm from the midsternal line in the fifth interspace), expanding the area of dullness and indicating increased heart size. Limitations of precordial percussion include reduced accuracy in patients with , where excess dampens the percussive sound, or in those with lung hyperinflation (e.g., ), where overexpanded lungs obscure the cardiac dullness by interposing resonant tissue between the heart and chest wall. These factors can lead to underestimation of heart size, making percussion less reliable when used in isolation.

Auscultation

of the precordium involves listening to and using a to evaluate cardiac function. The diaphragm is used for high-pitched sounds, such as most and systolic , while the bell, applied with minimal pressure, detects low-pitched sounds like diastolic or third . Examination proceeds systematically across key precordial zones: the aortic area at the right upper sternal border (2nd ), pulmonic area at the left upper sternal border (2nd ), tricuspid area at the lower left sternal border (4th-5th ), and mitral area at the cardiac apex (5th , midclavicular line). Patients are typically examined in , left lateral decubitus (to enhance apical sounds), and upright positions to optimize detection. Normal heart sounds include the first heart sound (S1), produced by closure of the mitral and tricuspid valves at the onset of , and the second heart sound (S2), generated by closure of the aortic and pulmonic valves at the beginning of . S1 is best heard at the apex and lower left sternal border, while S2 is prominent at the base (upper sternal borders). Physiologic splitting of S2, where the pulmonic component (P2) follows the aortic component (A2), widens during inspiration due to increased right ventricular delaying P2; this is normally heard at the pulmonic area and varies with respiration. Murmurs, arising from turbulent blood flow, are characterized by timing, location, radiation, and intensity. Timing is determined relative to S1 and S2: systolic murmurs occur between S1 and S2 (e.g., ejection or regurgitant types), while diastolic murmurs follow S2 (e.g., early or mid-diastolic). Location corresponds to underlying pathology, such as mitral murmurs at the apex radiating to the axilla, or aortic murmurs at the right upper sternal border radiating to the neck. Intensity is graded on the Levine scale from 1 to 6 for systolic murmurs (grade 1: faint and barely audible; grade 6: audible without the stethoscope) and 1 to 4 for diastolic murmurs, with grades 4 and above often accompanied by a palpable thrill. Dynamic maneuvers aid in differentiating murmurs. Inspiration augments right-sided sounds and murmurs (e.g., tricuspid or pulmonic) by increasing venous return to the right heart, while expiration enhances left-sided sounds. The , involving forced expiration against a closed , decreases preload and intensifies murmurs from hypertrophic obstructive or while diminishing most other murmurs, such as those from .

Clinical Significance

Normal Findings

In healthy individuals, the precordial examination typically reveals no visible pulsations upon inspection, though a subtle apical impulse may be observable in thin-chested persons when viewed from the side with the patient supine. Palpation identifies the point of maximal impulse (PMI) as a brief, tapping outward movement less than 3 cm in diameter, located at the fifth intercostal space in the midclavicular line, without thrills or heaves. Percussion delineates an area of absolute cardiac dullness approximately fist-sized, positioned just left of the sternum, with a transverse diameter of about 6-8 cm in adults. Auscultation yields clear first (S1) and second (S2) heart sounds in regular rhythm, corresponding to atrioventricular and semilunar valve closures respectively, without murmurs, extra sounds, or rubs; S1 is best heard at the apex and S2 at the base. Normal findings exhibit variations influenced by age, body habitus, and athletic conditioning. In young children, the PMI is typically located at the 4th intercostal space just medial to the midclavicular line and may be more diffuse; it shifts to the 5th space by . Thin body habitus often accentuates visibility and palpability of the PMI or parasternal impulses, and in lean athletes, S2 may sound louder due to enhanced and minimal overlying tissue. These physiologic adaptations, such as increased amplitude from exercise training, remain within normal limits and do not indicate . Physiological influences further modulate precordial findings, providing dynamic baselines. Respiratory variation causes physiologic splitting of S2 during inspiration, widening the interval between aortic and pulmonic components due to delayed right ventricular ejection. Positional changes affect the PMI location, shifting it laterally in the left lateral decubitus position to enhance detection, or medially when . Such influences, including transient increases in impulse amplitude from fever or anxiety, underscore the importance of standardized examination conditions. These normal precordial parameters serve as essential benchmarks for identifying deviations in clinical practice, facilitating early detection of cardiac abnormalities through comparison.

Abnormal Findings

Abnormal findings in the precordial examination deviate from normal baselines, such as the apical impulse located in the fifth intercostal space at the midclavicular line, and signal potential cardiac dysfunction through altered inspection, palpation, percussion, and auscultation results. These deviations often correlate across modalities; for instance, a laterally displaced apical impulse on inspection and palpation may accompany an S3 gallop on auscultation, suggesting ventricular volume overload. During , visible abnormalities include lateral displacement of the apical impulse, which can occur in left ventricular dilation, and paradoxical pulsations where the precordium moves inward during rather than outward, indicative of conditions like or severe dysfunction. Other observations may involve prominent parasternal lifts or diffuse heaving motions over the precordium, pointing to . Palpation reveals issues such as sustained heaves, often felt as forceful lifts along the left sternal border in , or diffuse over the left precordium in . Thrills, palpable vibrations resembling a cat's , are typically detected over areas in cases of , such as a systolic thrill at the right upper sternal border. The apical impulse may feel hyperdynamic and displaced laterally or inferiorly, correlating with chamber enlargement. Percussion demonstrates changes like an expanded area of dullness over the precordium, extending beyond the normal 6-8 cm from the midsternal line, which accurately indicates when confirmed by imaging. In pericardial effusions, the borders of dullness may shift outward, enlarging the due to fluid accumulation. Auscultation uncovers anomalies including extra , such as the S3 gallop—a low-frequency sound in early signaling ventricular dysfunction—and the S4 gallop, a presystolic sound from atrial contraction against a stiff ventricle. Murmurs, turbulent flow noises, may present as holosystolic types radiating to the in or ejection systolic murmurs peaking mid-systole over the base in . These auscultatory findings often align with palpatory thrills or visible pulsations for a comprehensive assessment of underlying . Cardiac conditions often manifest with characteristic precordial findings during physical examination. In cardiomegaly, the apex beat is typically displaced laterally and downward due to heart enlargement, reflecting increased cardiac volume from causes such as hypertension or valvular disease. Pericarditis commonly presents with sharp precordial pain that worsens on inspiration or supine position, accompanied by a pericardial friction rub audible over the left sternal border, indicating inflammation of the pericardial layers. Valvular heart diseases, including aortic stenosis or mitral regurgitation, produce precordial murmurs and thrills from turbulent blood flow across abnormal valves, with systolic ejection murmurs often radiating to the neck or axilla. Non-cardiac disorders can mimic cardiac precordial abnormalities but lack associated cardiac signs. causes localized, reproducible precordial pain in the costosternal junctions, exacerbated by movement or deep breathing, without murmurs or displaced impulses. leads to hyperresonant percussion notes over the precordium due to air accumulation in the pleural space, often with diminished breath sounds and no cardiac thrills. Precordial pain syndromes include benign and ischemic etiologies. , prevalent in youth, involves sudden, sharp, fleeting precordial pain lasting seconds to minutes, without radiation or exertional trigger, resolving spontaneously. pectoris features exertional precordial pressure or tightness radiating to the arm or jaw, stemming from myocardial ischemia due to . Abnormal precordial signs, such as displaced apex or new , necessitate prompt diagnostic evaluation. These findings often warrant (ECG) to assess rhythm or ischemia, for structural assessment, or further imaging like chest radiography to differentiate cardiac from non-cardiac causes.

References

  1. https://anatomy.ttuhscep.edu/cardiovascular_system/heart_tables.html
  2. https://www.ncbi.nlm.nih.gov/books/NBK593199/
  3. https://med.stanford.edu/stanfordmedicine25/the25/precordial.html
  4. https://www.ncbi.nlm.nih.gov/books/NBK322/
  5. https://www.kenhub.com/en/library/anatomy/precordium
  6. https://www.imaios.com/en/e-anatomy/anatomical-structures/precordium-1536888564
  7. https://www.kenhub.com/en/library/anatomy/surface-projections-of-the-heart
  8. https://www.ncbi.nlm.nih.gov/books/NBK556074/
  9. https://www.osmosis.org/answers/dextrocardia
  10. https://www.merriam-webster.com/medical/precordium
  11. https://www.ncbi.nlm.nih.gov/books/NBK535414/
  12. https://www.ncbi.nlm.nih.gov/books/NBK470256/
  13. https://www.physio-pedia.com/Anatomy_of_the_Human_Heart
  14. https://www.uptodate.com/contents/examination-of-the-precordial-pulsation
  15. https://pressbooks.library.torontomu.ca/assessmentnursing/chapter/inspection-of-the-precordium/
  16. https://www.ncbi.nlm.nih.gov/books/NBK2213/
  17. https://www.ncbi.nlm.nih.gov/books/NBK553078/
  18. https://pubmed.ncbi.nlm.nih.gov/1835287/
  19. https://pmc.ncbi.nlm.nih.gov/articles/PMC3221199/
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  21. https://www.ncbi.nlm.nih.gov/books/NBK525958/
  22. https://www.kenhub.com/en/library/anatomy/percussion-and-auscultation-of-the-heart
  23. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1544984/
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  27. https://www.ncbi.nlm.nih.gov/books/NBK542284/
  28. https://www.ajconline.org/article/S0002-9149%2800%2901008-0/abstract
  29. https://www.ncbi.nlm.nih.gov/books/NBK532931/
  30. https://publications.ersnet.org/content/erj/8/10/1756.full.pdf
  31. https://my.clevelandclinic.org/health/diseases/precordial-catch-syndrome
  32. https://www.hopkinsmedicine.org/health/conditions-and-diseases/angina-pectoris
  33. https://www.escardio.org/static-file/Escardio/Subspecialty/EACVI/position-papers/echocardiography-acute-cardiovascular-care.pdf
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