1. Free OnDemand Webinar
“At Natural Medicine Seminars, we would like to continually encourage and challenge our students in becoming the best diagnosticians through advanced training.
Please enjoy this complimentary webinar.”
Dr. Patrick Garrett
This is part one of a two part series. Part one – Heart
Part two – Lungs

2. Advanced Diagnostics Introduction The Cardiac Exam The Pulmonary Exam
Normal Heart Sounds
Abnormal Heart Sounds
The Pulmonary Exam
Normal Lung Sounds
Abnormal Lung Sounds

3. Introduction Why bother listening to the heart?
Auscultation of the heart is an essential part of even a cursory cardiac exam.  By listening to the heart you can gather information about the: 
1) Rate of the heart
2) Rhythm of the heart
3) Valvular function (e.g. stenosis, regurgitation, insufficiency)
4) Anatomical defects (e.g. atrial septal defects -ASD, ventricular septal defect -VSD, ventricular hypertrophy)

4. The Cardiac Exam Why bother listening to the heart?
Auscultation of the heart is an essential part of even a cursory cardiac exam.  By listening to the heart you can gather information about the: 
1) Rate of the heart
2) Rhythm of the heart
3) Valvular function (e.g. stenosis, regurgitation, insufficiency)
4) Anatomical defects (e.g. atrial septal defects -ASD, ventricular septal defect -VSD, ventricular hypertrophy)

5. The Cardiac Exam Where to Listen and Why
#1 Start with the Tricuspid region located between the 3rd, 4th, 5th, and 6th intercostal spaces at the left sternal border (LLSB)

6. The Cardiac Exam Where to Listen and Why
#2 Move to the Pulmonary region located between the 2nd and 3rd intercostal spaces at the left sternal border (LUSB)

7. The Cardiac Exam Where to Listen and Why
#3 Then to the Mitral region is located near the apex of the heard between the 5th and 6th intercostal spaces in the midclavicular line

8. The Cardiac Exam Where to Listen and Why
#4 End with the Aortic region located between the 2nd and 3rd intercostal spaces at the right sternal border (RUSB)

9. Flow Tricuspid, Pulmonary, Mitral (Bicuspid), Aortic
The Cardiac Exam
Flow
Tricuspid, Pulmonary, Mitral (Bicuspid), Aortic

10. The Cardiac Exam
Hint:
Here is a mnemonic to help remember the different valve locations.
“A PeT Monkey”
Starting from the
RUSB = A (Aortic Valve)
LUSB = Pet (Pulmonic Valve)
LLSB = PeT (Tricuspid Valve)
Apex = Monkey (Mitral Valve)
Don’t forget both of the carotids!

11. The Cardiac Exam
Hint:
Here is a mnemonic to help remember each of the atrial-ventricular valve locations.
“LAB RAT”
Left AV valve = (Bicuspid)
Right AV valve = (Tricuspid)

12. Additional Parts to the a complete cardiac examination
The Cardiac Exam
Additional Parts to the a complete cardiac examination
After the initial examination in the supine positions, several additional maneuvers should be accomplished in the thorough cardiac exam.

13. Additional Parts to the a complete cardiac examination
The Cardiac Exam
Additional Parts to the a complete cardiac examination
First: Instruct the patient to turn onto their left side (left decubitus position) and listen with the bell of the stethoscope at the apex for mitral stenosis (This will be a low pitched diastolic murmur).

14. Additional Parts to the a complete cardiac examination
The Cardiac Exam
Additional Parts to the a complete cardiac examination
Second: Instruct the patient to sit upright and re-examine the 4 valvular regions, again with the diaphragm of the stethoscope.

15. The Cardiac Exam If a murmur is heard, further exam may be useful
Maneuver
Rt Sided
Lt Sided
TR / PS AS MR
Hypertrophic Cardiomyopathy
Change with Respiration
Inspiration
Increased
Decrease or no change
To decrease flow
Valsalva Maneuver
Decrease
Increase
Squat to Stand
Variable
To increase flow
Leg Elevation
No Decrease
Hand Grip
Stand to Squat

16. Additional Parts to the a complete cardiac examination
The Cardiac Exam
Additional Parts to the a complete cardiac examination
Last: Instruct the patient to lean forward, exhale, and hold their breath.  This Valsalva Manuever will increase the blood pressure and will help identify any underlying murmur.
Listen with the diaphragm between the second and third intercostal spaces at the right sternal (aortic) and left sternal (pulmonic) areas for aortic regurgitation.

17. Normal Heart Sounds
The normal heart sounds are often described as sounding like “lub dub”.
Lub - The first heart sound is caused by vibrations arising from closure of both of the atrial-ventricular valves (mitral [bicuspid] and tricuspid). It coincides with the beginning of ventricular systole and so each first sound comes at the beginning of the pulse wave.
Dub - The second heart sound is softer, shorter and of higher frequency and is caused by closure of the semi-lunar valves (aortic and pulmonary). It coincides with the end of ventricular systole and so occurs at the end of each pulse wave.
Clinical Pearl: Because of their relationship to the pulse wave it is useful to listen to the heart sounds while feeling the pulse.

18. Abnormal Sounds
The presence of a murmur indicates either increased or turbulent blood flow.
Turbulent flow may arise because of abnormal flow across a valve or as a result of an abnormal communication between the chambers of the heart / great vessels.

19. When are murmurs considered “normal”?
Abnormal Sounds
When are murmurs considered “normal”?
Increased flow across a normal valve may occur in high output states, such as pregnancy, severe anemia, or associated with a significant pyrexia.

20. Abnormal Sounds
In the event that you hear a murmur, your description and documentation should include these 4 properties of an “abnormal” heart sound:
LOCATION
TIMING
GRADE
QUALITY

21. Abnormal Sounds
LOCATION - Knowing the location of the murmur will help determine the most likely etiology, diagnostic testing, and follow up. Note any radiation of the sound. (i.e. Aortic will radiate into the carotids)
*Location of maximal intensity (i.e. …between the 2nd and 3rd intercostal spaces at the right sternal border [2-3 ICS / URSB] with radiation into right carotid)

22. Location of Maximal Intensity
Abnormal Sounds
Radiation
Location of Maximal Intensity
Radiation
Typical for
2nd right intercostal space
Right carotid artery
Aortic stenosis
5th or 6th left intercostal space
Left anterior axillary line, left axilla
Mitral regurgitation (including mitral regurgitation due to mitral valve prolapse)
Left axilla Lower left sternal border
LRSB, Epigastrium, 5th ICS mid left thorax
Tricuspid regurgitation
5th left intercostal space mid- left thorax
Lower left sternal border
Hypertrophic cardiomyopathy

23. Abnormal Sounds
TIMING – Knowing the timing of the heart sound will narrow down the most likely cause.
*Note which part of the diastolic systolic phase the sound occurs. (i.e. early diastolic, pan systolic, etc)

24. Determining the timing
Abnormal Sounds
Determining the timing
Early Systolic – The murmur will over shadow the lub. This will sound like : Murmur-Dub
 Mid Systolic – The murmur will occur after the lub and prior to the dub. This will sound like : Lub -MurmurDub
Late Systolic – The murmur will over shadow the dub. This will sound like : Dub-Murmur
HoloSystolic – The murmur will over shadow both of the lub and the dub. This will sound like : Murmur-Murmur

25. Abnormal Sounds Murmur Timing and other Descriptions Description
Possible Diagnosis
Systolic ejection murmur
Normal, pulmonic, or aortic stenosis
Early diastolic murmur
Aortic regurgitation
Ejection Sound
Aortic valve disease
Pansystolic murmur
Tricuspid or mitral regurgitation
Late diastolic murmur
Tricuspid or mitral stenosis
Systolic click with late systolic murmur
Mitral valve prolapse
Opening snap with diastolic rumble murmur
Mitral stenosis S3
Normal in children and occurs in heart failure S4
Physiological and in various diseases

26. Abnormal Sounds
GRADING – Every murmur should be graded according to its intensity. This will differentiate a light murmur from a harsh murmur.

27. Abnormal Sounds Murmur Grades Grade Volume Thrill 1
Sound is very faint, only heard in ideal circumstances No 2
Sound is loud enough to be generally heard 3
Sound is louder then grade 2 but no thrill 4
Sound is louder then grade 3 with a thrill
Yes 5
Sound is heard with stethoscope partially off chest 6
Sound is heard with stethoscope entirely off chest

28. Abnormal Sounds
Thrills – Typically a murmur that is loud enough to be graded a 4, 5, or 6 will be associated with a palpable thrill.
To check for a thrill, place the palm of your right left hand across the base of the heart. You should be able to feel the vibration transfer through the chest wall.

29. Abnormal Sounds QUALITY – The quality and pitch of the heart sound.
*This may include terms such as harsh, musical, rumble, blowing. Use the modifier – High, Medium, Low and note any changes in body position or with respiration.

30. Abnormal Sounds Quality
If there is a musical “honk” or “coo”, it is usually due to an Aortic Stenosis.
If the murmur creates a “harsh” sound it is also usually due to an Aortic Stenosis.

31. Clinical Examples
If the sound is normal, document the rate and rhythm and the absence of an audible murmur.
If the sound is abnormal, document rate, rhythm, location of murmur, timing, grade, and quality. If the sound radiates, make sure to note where.

32. Etiology of Pediatric Murmurs
30% Innocent Murmur 20% Ventricular Septal Defect, VSD 11% Aortic Stenosis AS /AI 9% Mitral Valve Prolapse MVP/Mitral Regurgitation MR 7% Sub Aortic Stenosis (HOCM) 7% Pulmonary Stenosis, PS 5% Tetralogy of Fallot, ToF 9% other
Finley et al. Assessing children's heart sounds at a distance with digital recordings Pediatrics Dec;118(6):

33. Normal Heart Sound
Click on the speaker to hear the heart sound
Note the Lub Dub sound
Now go to the next page and listen to the most common abnormal sounds you will hear in adults.

34. Mitral Regurgitation Mitral Stenosis Aortic Regurgitation
Click on the speaker to hear the heart sound
Mitral Stenosis
Aortic Regurgitation
Aortic Stenosis
Pulmonary Stenosis

35. Tricuspid Regurgitation
VSD
Pericarditis
Mid-Systole Click
Opening Snap

36. Tumor Plop
Third Heart Sound
Fourth Heart Sound
Physiological Split
Wide Split

37. Normal Heart Sounds S1
S1 - The first heart tone, or S1, forms the "lub" of "lub-dub" and is composed of components Mitral and Tricuspid valves. It is caused by the sudden block of reverse blood flow due to closure of the atrioventricular valves at the beginning of ventricular contraction, or systole.
When the pressure in the ventricles rises above the pressure in the atria, venous blood flow entering the ventricles is pushed back toward the atria, catching the valve leaflets, closing the inlet valves and preventing regurgitation of blood from the ventricles back into the atria. The S1 sound results from reverberation within the blood associated with the sudden block of flow reversal by the valves.

38. Normal Heart Sounds S2
S2 - The second heart tone, or S2, forms the "dub" of "lub-dub" and is composed of components Aortic and Pulmonic valves. It is caused by the sudden block of reversing blood flow due to closure of the aortic valve and pulmonary valve at the end of ventricular systole, i.e beginning of ventricular diastole. As the left ventricle empties, its pressure falls below the pressure in the aorta, aortic blood flow quickly reverses back toward the left ventricle, catching the aortic valve leaflets and is stopped by aortic (outlet) valve closure. Similarly, as the pressure in the right ventricle falls below the pressure in the pulmonary artery, the pulmonary (outlet) valve closes. The S2 sound results from reverberation within the blood associated with the sudden block of flow reversal.

39. Mitral Regurgitation
Mitral regurgitation (MR), also known as mitral insufficiency or mitral incompetence, is a valvular heart disease which consists of abnormal leaking of blood through the mitral valve, from the left ventricle into the left atrium of the heart

40. Mitral Stenosis
Mitral Stenosis is a valvular heart disease characterized by the narrowing of the orifice of the mitral valve of the heart.
With mitral stenosis, the valve does not open completely, and to transport the same amount of blood the left atrium needs a higher pressure than normal to overcome the increased gradient.

41. Aortic Regurgitation
Aortic regurgitation (AR), also known as aortic insufficiency or aortic incompetence, is a valvular heart disease which consists of abnormal leaking of blood through the aortic valve, from the aorta into the right ventricle of the heart

42. Aortic Stenosis
Aortic Stenosis is a valvular heart disease characterized by the narrowing of the orifice of the aortic semilunar valve of the heart.
With Aortic stenosis, the valve does not open completely, and to transport the same amount of blood the right ventricle needs a higher pressure than normal to overcome the increased gradient.
This will eventually lead to right ventricular hypertrophy.

43. Pulmonary Stenosis
Pulmonary Stenosis is a valvular heart disease characterized by the narrowing of the orifice of the pulmonic semilunar valve of the heart.
With pulmonary stenosis, the valve does not open completely, and to transport the same amount of blood the left ventricle needs a higher pressure than normal to overcome the increased gradient.
This will eventually lead to left ventricular hypertrophy.

44. Tricuspid Regurgitation
Tricuspid regurgitation (TR), also known as tricuspid insufficiency or tricuspid incompetence, is a valvular heart disease which consists of abnormal leaking of blood through the tricuspid valve, from the right ventricle into the right atrium of the heart

45. VSD
A ventricular septal defect (VSD) is a defect in the ventricular septum, the wall dividing the left and right ventricles of the heart.
This allows oxygenated from the left ventricle to mix with de-oxygenated blood from the right ventricle.

46. Pericarditis
Pericarditis is an inflammation of the pericardium (the fibrous sac surrounding the heart).
Chest pain, radiating to the back and relieved by sitting up forward and worsened by lying down, is the classical presentation.
Other symptoms of pericarditis may include dry cough, fever, fatigue, and anxiety. Pericarditis can be misdiagnosed as myocardial infarction (heart attack), and vice versa.

47. Mid-Systolic Click
Mid-systolic clicks are due to blood flow through the semilunar valves.
They occur at the start of blood ejection — which starts after S1 — and ends with the cessation of the blood flow — which is before S2. Therefore, the onset of a midsystolic ejection murmur is separated from S1 by the isovolumic contraction phase; the cessation of the murmur and the S2 interval is the aortic or pulmonary hangout time. The resultant configuration of this murmur is a crescendo-decrescendo murmur.
Causes of midsystolic ejection murmurs include outflow obstruction, increased flow through normal semilunar valves, dilation of aortic root or pulmonary trunk, or structural changes in the semilunar valves without obstruction.

48. Opening Snap
The Opening Snap in addition to a typical murmur indicates the murmur is due to mitral stenosis and not a flow rumble across a non-stenotic valve.
The timing of the Opening Snap has been suggested as a gauge of the severity of the stenosis.

49. Third Heart Sound (S3)
Rarely, there may be a third heart sound also called a protodiastolic gallop, ventricular gallop, or informally the "Kentucky" gallop as an onomatopoeic reference to the rhythm and stress of S1, S2, and S3 together (S1=ken; S2=tuc; S3=ky).
It occurs at the beginning of diastole after S2 and is lower in pitch than S1 or S2 as it is not of valvular origin.
The third heart sound is benign in youth and some trained athletes, but if it re-emerges later in life it may signal cardiac problems like a failing left ventricle as in dilated congestive heart failure (CHF).
S3 is thought to be caused by the oscillation of blood back and forth between the walls of the ventricles initiated by inrushing blood from the atria.
The reason the third heart sound does not occur until the middle third of diastole is probably because during the early part of diastole, the ventricles are not filled sufficiently to create enough tension for reverberation. It may also be a result of tensing of the chordae tendineae during rapid filling and expansion of the ventricle.

50. Tumor Plop
A third heart sound can also be simulated by a myxoma of the left atrium. This type of third heart sound is often referred to as a "tumor plop".
The "tumor plop" is caused by the gelatinous tumor, which is attached by a stalk to the atrial septum, plunging into the ventricle and pushing the blood ahead of it like a syringe plunger.

51. Fourth Heart Sound (S4)
The rare fourth heart sound is sometimes audible in healthy children and again in trained athletes, but when audible in an adult is called a presystolic gallop or atrial gallop.
This gallop is produced by the sound of blood being forced into a stiff / hypertrophic ventricle.
It is a sign of a pathologic state, usually a failing left ventricle.
The sound occurs just after atrial contraction ("atrial kick") at the end of diastole and immediately before S1, producing a rhythm sometimes referred to as the “Tennessee” gallop where S4 represents the "tenn-" syllable. The combined presence of S3 and S4 is a quadruple gallop. At rapid heart rates, S3 and S4 may merge to produce a summation gallop.

52. Physiological Split
During inspiration, the increased negative intrathorasic pressure which allows lung expansion also induces both increased blood return from the body into the right ventricle and simultaneous reduced blood volume return from the lungs into the left ventricle. Because of the increased blood volume in the right atrium, the pulmonary valve stays open longer during ventricular systole whereas the aortic valve closes slightly earlier due to slightly reduced left ventricular volume.
Thus the Pulmonary Valve component of S2 is delayed relative to the Aortic valve component. This delay in P2 versus A2 is heard as a slight broadening or even "splitting" of the second heart sound, though usually only in the pulmonic area of the chest because the P2 is soft and not heard in other areas.
During expiration, the less negative (than during inspiration) intrathoracic pressure no longer increases blood return to the right ventricle versus the left ventricle, the right ventricle volume in no longer increased, the pulmonary valve closes earlier, Pulmonic valve occurs earlier and overlaps Aortic valve.
It is physiological to hear a "splitting" of the second heart tone in younger people, during inspiration and in the "pulmonary area", i.e. the 2nd ICS (intercostal space) at the left edge of the sternum. During expiration the interval between the two components normally shortens and the S2 sounds become merged.

53. Wide Split
A bundle branch block will produce continuous splitting but the degree of splitting will still vary with respiration.
If splitting does not vary with inspiration, it is termed a "fixed split S2" and is usually due to an atrial septal defect (ASD) or ventricular septal defect (VSD). The ASD or VSD creates a left to right shunt that increases the blood flow to the right side of the heart, thereby causing the pulmonic valve to close later than the aortic valve independent of inspiration/expiration.
Reverse splitting indicates pathology. Aortic stenosis, hypertrophic cardiomyopathy, left bundle branch block, and a ventricular pacemaker could all cause a reverse splitting of the second heart sound.

54. Diagnosing Murmurs Accuracy in Diagnosis of Systolic Murmurs Maneuvers
This study looks at the sensitivity, specificity and predictive value of physical exam maneuvers that historically have been used in diagnosing systolic murmurs.
Two cardiologist independently examined 50 patients age 6 to 85 years of age ( mean age 45) with a systolic murmur I / VI or greater. The cardiologists were separated from the patients by a partition. An independent examiner instructed the patients in the maneuvers and supervised the implementation of them.
Sapira, JD. The art and science of bedside diagnosis. (Urban & Schwarzenberg, Baltimore-Munich) 1990.

55. Results for Systolic Murmur
Maneuvers--result in increased murmur
Murmur
Sens(%)
Spec(%)
LR+
LR-
Inspiration
Right-sided
100 88
8.3
Valsalva
HCM 65 96
16.25
0.36
Squat to stand 95 84
5.9
0.06
Handgrip
Mitral regurgitation, VSD 68 92
8.5
0.35
Transient arterial occlusion 78 -
Maneuvers--result in decreased murmur
stand to squat
Leg elevation 85 91
10.63
0.16 75
3.4
0.2

56. Wiggers Diagram Summary
Phase
EKG
Heart sounds
Aortic valve
Mitral valve A
Atrial systole P
S4*
closed
open B
Ventricular systole - Isovolumetric/isovolumic contraction
QRS
S1 ("lub") C1
Ventricular systole - Ejection 1 - C2
Ventricular systole - Ejection 2 T D
Ventricular diastole - Isovolumetric/isovolumic relaxation
S2 ("dub") E1
Ventricular diastole - Ventricular filling 1
S3* E2
Ventricular diastole - Ventricular filling 2

57. Cardiac References
"The Cardiovascular System." Bates, B. A Guide to Physical Examination and History Taking. 9h Ed
Aronow, WS, and I Kronzon. Correlation of prevalence and severity of valvular aortic stenosis determined by continuous-wave Doppler echocardiography with physical signs of aortic stenosis in patients 62 to 100 years with aortic systolic ejection murmurs. Am J Cardiol (4):
Badgett RG, CR Lucey, CD Mulrow, DL Simel, D Rennie. Can the clinical examination diagnose left sided heart failure in adults? JAMA 1997; 277:
"Choudhry NK, Etchells EE. Does This Patient Have Aortic Regurgitation? JAMA. 1999; 281:2231.
Etchells E, C Bell, K Robb, DL Simel, and D Rennie. Does this patient have an abnormal systolic murmur? JAMA 1997; 277:
Fye, WB. Disorders of the heartbeat: A historical overview from antiquity to the mid-20th century. Am J Cardiol 1993; 72:
Gaeschke, R, GH Guyatt, DL Sackett for the Evidence-Based Medicine Working Group. Users' guides to the medical literature. VI. How to use an article about a diagnostic test. A: Are the results of the study valid? JAMA :
McGee S. Evidence based physical diagnosis. WB Saunders Co
McMichael, J. History of atrial fibrillation : Harvey - de Senac - Laennec. Br Heart J 1982; 48:
Sapira, JD. The art and science of bedside diagnosis. (Urban & Schwarzenberg, Baltimore-Munich) 1990.

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