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                              3.6  Dynamics of Reentry in a Fixed Pathway



               Reentry of the cardiac action potential is thought to be the most common mechanism of

        clinical arrhythmias, including atrial flutter and fibrillation, and ventricular arrhythmias following
        myocardial ischemia or infarction. During normal cardiac excitation, the excitation wave becomes
        extinct before the next wave arrives. This behavior results from the refractoriness of cardiac cells
        that lasts longer than the excitation period, insuring rhythmic periodicity and repetitive activation
        sequence on every beat.



               Under pathological conditions, the excitation wave may encounter a zone of conduction
        block. It might be forced to rotate around it to reenter the region of pre-block excitation and re-

        excite it in a repetitive cyclical fashion. The rotating wavefront can emanate excitation waves that
        capture the surrounding tissue, causing an arrhythmia. This mechanism, in which the rotating
        action potential plays the role of an “excitatory oscillator” is called reentry or circus movement.
        For the reentrant wavefront to encounter an excitable tissue that is no longer refractory in the
        pre-block region, the rotation time must be longer than the refractory period. Thus, slow

        conduction velocity facilitates reentry. In the space domain, the concept of wavelength was
        defined as λ=θT, where θ is conduction velocity and T the refractory period. As long as λ is smaller

        than the length of the reentry pathway, an excitable gap exists between the head and tail of the

        circulating wave and reentry is stable at a constant cycle length (frequency) of rotation. If λ is
        longer than the reentry pathway, the wavefront encounters refractory tissue and reentry cannot
        be sustained. When λ is similar in length to the reentry pathway, complex dynamics arise.


               In the heart, reentry occurs in three-dimensional space. The reentry pathway can be fixed

        or constantly changing. The reentrant action potential may propagate around an inexcitable
        obstacle (e.g. naturally occurring orifices) on a fixed anatomical pathway (“anatomical reentry”)
        or may reside in a region of the myocardium that is excitable in its entirety (“functional reentry”).

        Dynamically, anatomical reentry is the simplest form of reentrant excitation. Many of the funda-
        mental concepts and mechanistic insights into reentry were obtained from early experimental
        studies in rings of excitable tissue. 231-234  A canine isolated tricuspid ring preparation 235,236,237  was
        used to obtain both extracellular and intracellular (microelectrode) recordings from all segments
        of the pathway during reentry, relating action potential properties to the dynamics of reentry.

        A theoretical equivalent to the experimental ring preparation can be constructed by connecting
        “head” and “tail” of the 1-dimensional multicellular fiber model.    222  Reentry is initiated by a
        premature stimulus in the vulnerable window of an action potential generated by a primary

        stimulus (Figure 3.20).


               The duration of the reentrant action potential depends on the frequency of excitation and
        the degree of head-tail interaction. Figure 3.21A shows reentrant action potentials in different size
        rings, decreasing in size from top row (600 cells) to bottom row (50 cells) of the figure. As ring size