Quantitative analysis of the "warm-up" phenomenon in myotonic dystrophy type 1.

To quantitate improvement in hand-grip myotonia and muscle strength (i.e., the "warm-up" phenomenon) in myotonic dystrophy type 1 (DM1), six successive, standardized maximum voluntary isometric contractions (MVICs) were recorded on 2 separate days using a computerized isometric hand-grip myometer in 25 genetically confirmed DM1 patients and in 17 normal controls. An automated computer program placed cursors along the declining (relaxation) phase of the MVICs at 90%, 50%, and 5% of peak force (PF) and calculated relaxation times (RTs) between these points. Mean 90% to 5% RT (a measure of myotonia) rapidly declined from 2.5 s in MVIC 1 to 0.8 s in MVIC 6 (warm-up = 1.7 s) in DM1; in controls, it remained 0.4 s for all six MVICs (warm-up = 0). In DM1, 70% of warm-up occurred between MVIC 1 and 2, almost exclusively in the terminal 50% to 5% phase of muscle relaxation. Day 1 warm-up was highly correlated with the severity of myotonia, and with day 2 warm-up. Improvement in myotonia was not accompanied by either transient paresis or improvement in PF. We conclude that, with this testing paradigm: warm-up of myotonia in DM1 can be reliably measured; is proportional to severity of myotonia; occurs rapidly, being most prominent between the first and second grips; mainly results from shortening of the terminal phase of muscle relaxation; and is not accompanied by significant warm-up in force output.

Leukocyte CTG repeat length correlates with severity of myotonia in myotonic dystrophy type 1.

OBJECTIVE: To quantitate hand muscle myotonia and to assess the relationship between CTG repeat length and myotonia in myotonic dystrophy type 1 (DM1). METHODS: First dorsal interosseous twitch and tetanic contractions evoked by single and 10-Hz ulnar nerve stimulation were recorded with a force transducer in 15 patients with genetically confirmed DM1 and 15 control subjects. An automated computer program analyzed three single and three tetanic recordings per subject on 2 successive days by placing cursors along the declining (relaxation) phase of the force recordings at 90, 50, and 5% of peak force (PF) and calculating relaxation times (RT) between these points. RESULTS: Tetanic and twitch RT was longer and PF lower in patients than subjects. RT (90 to 5%) was above the normal mean + 2.5 SD in 13 tetanic (87%) and 11 (73%) twitch patient recordings. In DM1, prolongation of RT was due mainly to delay in the terminal (50 to 5%), rather than the initial (90 to 50%) phase of relaxation, and was much greater in tetanic than single-twitch recordings. Mean test-retest variability was 19% for tetanic RT and 16% for tetanic PF. In DM1, both tetanic and twitch RT were positively correlated with leukocyte CTG repeat length. CONCLUSIONS: In DM1, myotonia of intrinsic hand muscles can be quantitated reliably by automated analysis of tetanic and twitch RT, targeting, in particular, the terminal phase of muscle relaxation after tetanic stimulation. Severity of hand muscle myotonia depends on CTG repeat length consistent with a "triplet repeat dosage" effect on chloride channel mRNA splicing and function.