T wave: Difference between revisions

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===Overview===
===Overview===
In 1954 [[George Burch]] described T wave abnormalities as [[myocardial ischemia]] mimics in patients with a variety of acute cerebral insults. His classic paper <ref>http://circ.ahajournals.org/content/9/5/719.full.pdf</ref> published in May 1954 popularized the term '''Cerebral T waves'''. The T waves were described as large,were similar to those seen in early [[myocardial isehemia]], and were reported to revert to normal with improvement of the clinical condition,or changed to the pattern of any underlying heart disease present prior to the intracranial insult.
In 1954 [[George Burch]] described T wave abnormalities as [[myocardial ischemia]] mimics in patients with a variety of acute cerebral insults. His classic paper <ref>http://circ.ahajournals.org/content/9/5/719.full.pdf</ref> published in May 1954 popularized the term '''Cerebral T waves'''. The T waves were described as large,were similar to those seen in early [[myocardial isehemia]], and were reported to revert to normal with improvement of the clinical condition,or changed to the pattern of any underlying heart disease present prior to the intracranial insult.
They usually appear as diffuse giant T-wave inversions or large, upright T-waves or sometimes as flat T-waves.


===Etiological Theories===
===Etiological Theories===

Revision as of 18:36, 30 May 2012

Schematic representation of normal ECG

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List of terms related to T wave

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor-In-Chief: Cafer Zorkun, M.D., Ph.D. [2]

Overview

The T wave represents the repolarization (or recovery) of the ventricles. The interval from the beginning of the QRS complex to the apex of the T wave is referred to as the absolute refractory period. The last half of the T wave is referred to as the relative refractory period (or vulnerable period).

Orientation of T waves

Normal Orientation

General

  • Normally upright in leads 1 and 2 and in the chest leads over the left ventricle.

Precordial Leads

  • Lead V1 may have a positive, negative, or biphasic T wave.
  1. The T wave in V1 may be inverted at any age (is more often inverted than upright) and the T in V2 can normally be inverted.
  2. When the T in V1 is upright, it is almost never as tall as the T in V6.
  • In infants and young children precordial T waves may be inverted.
  • In adult males it is considered abnormal if the T waves are inverted as far to the left as lead V3.
  • In adult females the T in V3 may be shallowly inverted.

aVF

  • Normally upright in aVL and aVF if the QRS is > 5 mm tall but may be inverted if the R waves are smaller.
  • It is not uncommon to have an isolated negative T wave in lead III, aVL, or aVF. Cardiologists are often asked to consult pre-operativley on the patient with the isolated flipped T in lead III.

aVR

  • Normally inverted in aVR.

In The Presence of Conduction Delay

  • When a conduction abnormality (e.g., left bundle branch block,right bundle branch block, or a paced rhythm) is present, the T wave should be deflected opposite the terminal deflection of the QRS complex. This is known as appropriate T wave discordance.

Differential Diagnosis of Inverted or Negative T waves:

Morphology of T waves

Shape

Notched

Differential diagnosis of the sharp, tented or pointed T wave

  • Tall or "tented" symmetrical T waves may indicate hyperkalemia.
  • One of the earliest electrocardiographic finding of acute myocardial infarction is sometimes the hyperacute T wave, which can be distinguished from hyperkalemia by the broad base and slight asymmetry.
  • T waves can be sharply pointed in ischemia as well.

Height

The T wave is normally not taller than > 5 mm in any standard lead and not taller than > 10 mm in any precordial lead.

Differential diagnosis of the tall T wave:

Differential diagnosis of the short or flat T wave:

Cerebral T waves

Overview

In 1954 George Burch described T wave abnormalities as myocardial ischemia mimics in patients with a variety of acute cerebral insults. His classic paper [1] published in May 1954 popularized the term Cerebral T waves. The T waves were described as large,were similar to those seen in early myocardial isehemia, and were reported to revert to normal with improvement of the clinical condition,or changed to the pattern of any underlying heart disease present prior to the intracranial insult. They usually appear as diffuse giant T-wave inversions or large, upright T-waves or sometimes as flat T-waves.

Etiological Theories

Originally the cause was thought to be preexisting coronary artery disease exacerbated by the physiological demands of the critical illness. However in many cases the autopsy studies of the heart showed no macroscopic evidence of significant coronary artery stenosis or myocardial infarction.

Hironosuke et al[2] proposed widespread focal myocytolysis due to overstimulation of sympathetic centres in the hypothalamus leading to release of catecholamines which could damage myocardial cells either by inducing constriction of the myocardial microcirculation, thus leading to focal ischemia, or by a direct toxic effect, as the mechanism which result in the ECG changes seen in Subarachnoid hemorrhage. After studying the characteristic pattern of focal myocardial lesions, some researchers proposed that the damaging catecholamines are released from intramyocardial nerve endings rather than from the general(systemic) circulation.[3]

Rogers et al[4] produced increases and decreases in the amplitude of the T wave in cats by stimulating the right and left sides of the hypothalamus and stellate ganglia, respectively. They suggested that the mechanism is unilateral alteration of sympathetic tone to the heart.

Examples

References

  1. http://circ.ahajournals.org/content/9/5/719.full.pdf
  2. Sakamoto H, Nishimura H, Imataka K, Ieki K, Horie T, Fujii J (1996). "Abnormal Q wave, ST-segment elevation, T-wave inversion, and widespread focal myocytolysis associated with subarachnoid hemorrhage". Japanese Circulation Journal. 60 (4): 254–7. PMID 8726174. Retrieved 2012-05-30. Unknown parameter |month= ignored (help)
  3. Baroldi G. Pathologic evidence of myocardial damage following acute brain injuries. In: Di Pasquale G, Pinelli G, eds. Heart-Brain Interactions. New York, NY: Springer-Verlag
  4. Rogers MC, Abildskov JA, Preston JB (1973). "Neurogenic ECG changes in critically ill patients: an experimental model". Critical Care Medicine. 1 (4): 192–6. PMID 4764357. |access-date= requires |url= (help)

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