Long-term MRI and clinical follow-up of symptomatic and presymptomatic carriers of dysferlin gene mutations.

We report the results of a longitudinal study involving MRI and clinical follow-up in nine siblings from four families with Miyoshi myopathy (MM). All individuals carried pathogenic dysferlin gene (DYSF) mutations with six of them suffering from symptomatic disease and three being presymptomatic. In presymptomatic subjects, MRI was sensitive to detect alterations in muscle tissue years before disease onset. The first MRI alteration to disclose was evidence for myoedema in dorsal compartment muscles of the legs followed by fatty degeneration. Moreover, MRI changes anticipated the topography of subsequent clinical muscle involvement and progressed from distal to proximal dorsal leg muscles. In symptomatic subjects, MRI changes reflected the pattern and severity of clinical muscle involvement. MRI evidence, however, suggests that muscle involvement is much more prominent in early disease stages than clinically seen. Clinical follow-up up to 8 years made evident that MM onset occurs at a mean age of 18.4 years. The most prominent initial deficit was impaired tiptoe gait due to muscle plantarflexor dysfunction followed by impaired dorsiflexor function. Dorsal compartments were predominantly affected not only in distal but also in proximal leg muscles, and a more rapid progression was noticed during the early phase of the disease. Our data suggest that MRI is a helpful diagnostic tool for an early diagnosis of MM and other distal myopathies since it provides sensitive and topographic information about initial and even preclinical muscle involvement. This is of particular relevance in Miyoshi myopathy because distinct CK elevation is present long before its clinical onset and often misdiagnosed as "idiopathic".

Topography of cerebral atrophy in early Huntington's disease: a voxel based morphometric MRI study.

OBJECTIVES: To analyse grey matter changes in early stages of Huntington's disease using magnetic resonance imaging (MRI) and the technique of voxel based morphometry (VBM). METHODS: Forty four patients with a molecularly confirmed clinical diagnosis of Huntington's disease based on the presence of motor signs were included in the study. Patients were clinically rated using the Unified Huntington's Disease Rating Scale; all were in early clinical stages of the disease (that is, Shoulson stages I and II). High resolution volume rendering MRI scans (MP-RAGE) were acquired. MRI data were volumetrically analysed in comparison to an age matched normal database by VBM, using statistical parametric mapping (SPM99). RESULTS: In Huntington's disease, robust regional decreases in grey matter density (p<0.001, corrected for multiple comparisons)-that is, atrophy-were found bilaterally in striatal areas as well as in the hypothalamus and the opercular cortex, and unilaterally in the right paracentral lobule. The topography of striatal changes corresponded to the dorso-ventral gradient of neuronal loss described in neuropathological studies. Stratification according to clinical severity showed a more widespread involvement extending into the ventral aspects of the striatum in the group of more severely affected patients. CONCLUSIONS: The topography of cerebral volume changes associated with Huntington's disease can be mapped using VBM. It can be shown that cerebral grey matter changes co-vary with clinical severity and CAG repeat length.

Imaging and neurochemical markers for diagnosis and disease progression in ALS.

Based on the development of a transgenic animal model, an increasing number of experimental strategies have revealed the potential to modify the selective degeneration of motor neurons, a feature unique to motor neuron diseases such as amyotrophic lateral sclerosis (ALS). The translation of this success into therapeutic effects in human diseases is a challenge of the future. For this purpose, tools must be developed which serve as diagnostic and surrogate markers for diagnosis and disease progression. Currently, to understand the pathogenesis of the spinal cord disease, the focus remains on more traditional electrodiagnostic techniques. For the characterization of the involvement of brain structures, imaging techniques are increasingly explored. This review focuses on the use of imaging techniques as surrogate markers for the involvement of the brain in motor neuron disorders, but also tries to point out that the final goal will be the development of cheap biochemical markers for the screening of populations at risk.

Proton magnetic resonance spectroscopy of the motor cortex in 70 patients with amyotrophic lateral sclerosis.

OBJECTIVE: To evaluate proton magnetic resonance spectroscopy for detection and monitoring of upper motoneuron degeneration in patients with amyotrophic lateral sclerosis. METHODS: Seventy patients with amyotrophic lateral sclerosis according to the El Escorial criteria were compared with 48 healthy control subjects. Single-volume proton magnetic resonance spectroscopy (echo time, 272 milliseconds; repetition time, 2000 milliseconds) was performed in both motor cortices for detection of N-acetylaspartate (NAA), phosphocreatine + creatine ([P]Cr), and choline-containing compounds (Cho) to calculate the metabolite ratios NAA/Cho, NAA/(P)Cr, and Cho/(P)Cr. In addition, absolute metabolite concentrations of NAA, (P)Cr, and Cho were obtained in 30 patients and 15 controls with the unsuppressed water signal used as an internal reference. RESULTS: Absolute concentrations of NAA (P<.001) and (P)Cr (P<.05) were reduced in motor cortices of patients, whereas Cho concentrations remained unchanged. The NAA/Cho and NAA/(P)Cr ratios were reduced in all El Escorial subgroups (P<.001). The Cho/(P)Cr ratio was elevated in patients with definite amyotrophic lateral sclerosis (P<.05). Metabolite ratio changes corresponded to the lateralization of clinical symptoms and were weakly correlated with disease duration and disease severity. In follow-up observations of 16 patients during a mean (+/-SD) of 12.1 +/- 8.7 months, NAA/Cho dropped by 9.1% (P<.01), and Cho/(P)Cr increased by 7.0% (P<.01). Changes of metabolite ratios were significantly correlated with progression of disease severity. CONCLUSIONS: Measurement of NAA concentrations and NAA/Cho ratios appear to be most suitable for detection of motor cortex degeneration by single-volume proton magnetic resonance spectroscopy. Reduced NAA/Cho ratios correspond to aspects of the clinical presentation and reflect disease progression in follow-up measurements.

Proton magnetic resonance spectroscopy in Kennedy syndrome.

OBJECTIVE: To seek regional metabolite abnormalities in patients with Kennedy disease (KD) using proton magnetic resonance spectroscopy. DESIGN: Nine patients with KD showing the typical phenotype without clinical signs of upper motor neuron involvement were compared with 17 male, age-matched, healthy control subjects. Relative metabolite concentrations for N-acetyl (NA) groups, choline-containing groups (Cho), phosphocreatine (Cr), and lactate (Lac) were determined in the brainstem and the motor region. RESULTS: Pathologic Lac signals suggesting impaired energy metabolism were absent in patients and controls. In the brainstem area, patients with KD showed a significant reduction in the NA/Cho metabolite ratio (P = .01). In the motor region, NA/Cho (P = .04) and NA/Cr (P = .03) ratios were significantly reduced. The reduction of the NA/Cho ratio in the motor region mainly resulted from decreased metabolite ratios in 3 patients. Changes in metabolite ratios did not correlate with the number of trinucleotide cytosine-adenine-guanine repeats from leukocytes. Because of the relatively small sample size due to the rarity of KD, these results should be considered preliminary. CONCLUSIONS: Spectroscopic data fail to provide further evidence for altered energy metabolism in KD. Metabolite changes in the brainstem indicate a reduction of the neuronal marker NA or elevated Cho. These findings may reflect neuronal loss or gliosis consistent with the known pathologic features. In a subset of patients, altered metabolite ratios best explained by neuronal loss suggest subclinical involvement of the motor region. The extent of metabolite changes does not correlate with the trinucleotide repeat length.

Proton magnetic resonance spectroscopy of the primary motor cortex in patients with motor neuron disease: subgroup analysis and follow-up measurements.

OBJECTIVES: To determine the motor cortex degeneration in patients with amyotrophic lateral sclerosis (ALS) using proton magnetic resonance spectroscopy, and to prove that proton magnetic resonance spectroscopy is suited to monitor the course of disease with follow-up examinations. MATERIALS AND METHODS: We studied 33 patients with ALS whose conditions were diagnosed according to the El Escorial World Federation of Neurology criteria. Nine patients with ALS were followed up for up to 2 years. The control group included 20 healthy volunteers and 4 patients with multifocal motor neuropathy. Proton magnetic resonance spectroscopy determined levels of the brain metabolites N-acetylaspartate (NAA), choline, inositol-containing compounds, glutamate/glutamine, and phosphocreatine. RESULTS: Patients with ALS showed a significant reduction in the NAA-choline (P <.001) and NAA-phosphocreatine (P <.005) metabolite ratios and significantly elevated choline-phosphocreatine (P <.005) ratios compared with controls. Inositol-phosphocreatine ratios were also elevated in case patients, but the increase was less pronounced (P <.05). No differences in glutamate/glutamine-phosphocreatine ratios were detected between case patients and controls. An analysis of subgroups demonstrated less significant differences in NAA-choline metabolite ratios (P<.05), even in patients with pure lower motor neuron syndrome (suspected ALS). No changes in metabolite T1 and T2 relaxation times were observed. Patients with multifocal motor neuropathy showed normal metabolic ratios. Progressive alterations in affected metabolite ratios could be documented in the follow-up examinations. CONCLUSIONS: Spectroscopic changes in the motor cortices of patients with ALS correspond with a reduction in levels of NAA and an elevation in levels of choline and inositol compounds. Since NAA is exclusively expressed in neurons, the observed decrease of NAA reflects neuronal loss or dysfunction. Inositol and choline are associated with plasma membrane metabolism, so the release of these compounds may be related to membrane disorders.

[31P-mr spectroscopy of peripheral skeletal musculature under load: demonstration of normal energy metabolites compared with metabolic muscle diseases]. / 31P-MR-Spektroskopie der peripheren Skelettmuskulatur unter Belastung: Darstellung des normalen Energiestoffwechsels im Vergleich zu metabolischen Muskelerkrankungen.

PURPOSE: 31P-MR spectroscopy of skeletal muscle under exercise was used to obtain the range of normal variation and comparison was made for different neuromuscular diseases. METHODS: 41 examinations of 24 volunteers and 41 investigations in 35 patients were performed on 1.5 T MR systems (Gyroscan 515 und S15/ACSII, Philips). Localised 31P-MR spectra of the calf muscle were obtained in time series with a resolution of 12 s. RESULTS: Two types of muscle energy metabolism were identified from the pattern of spectroscopic time course in volunteers: While the first group was characterised by a remarkable decline to lower pH values during exercise, the second group showed only small pH shifts (minimum pH: 6.48 +/- 0.13 vs 6.87 +/- 0.07, p < 10(-6)) although comparable workload conditions were maintained. The pH-values correlated well with blood lactate analysis. Patients with metabolic disorders and chronic fatigue syndrome (CFS) showed decreased resting values of PCr/(PCr + Pi) and increased pH levels during exercise. PCr recovery was significantly delayed (0.31 vs 0.65 min-1, p < 0.00005) in metabolic muscle disorders but was normal in CFS patients. CONCLUSION: Findings in volunteers indicate utilisation of different metabolic pathways which seems to be related to the fibre type composition of muscle. Reduced resting levels for PCr/(PCr + Pi), altered pH time courses, and decreased PCr recovery seem to be helpful indicators for diagnosis of metabolic muscle disorders.

ALS.

The cause of ALS is not known but there are four main hypotheses about its etiology. First, an excess of extracellular glutamate in the CNS of patients with ALS resulting from a defect in glutamate reuptake may have excitotoxic effects on motor neurons. Clinical trials suggest the antiglutamate agent riluzole improves survival of patients with the disease. Second, ALS may be an autoimmune disease, but immunologically-based treatments have been unsuccessful. The third hypothesis is that ALS results from a lack of neurotrophic growth factors. Preliminary results from clinical trials indicate recombinant human insulin-like growth factor I offers therapeutic promise. Finally, familial ALS is sometimes linked to a gene encoding a Cu/Zn-binding superoxide dismutase; the mutations in ALS are thought to result in gain of function of dismutase activity. The involvement of superoxide dismutase in sporadic ALS is unclear.

Muscle phosphofructokinase deficiency in two generations.

Phosphofructokinase (PFK) is the key regulatory enzyme of glycolysis. Patients lacking the muscular isoform of PFK typically present with myopathy and compensated hemolysis (glycogenosis type VII or Tarui's disease). Since 1965 about 30 cases of muscular PFK deficiency have been reported. In most cases family history suggests a recessive inherited trait. We describe a family of Ashkenazi Jewish origin with two members in subsequent generations suffering from muscular PFK deficiency. The propositus, a 19-year-old male patient presented with weakness, myalgias and exercise intolerance since early infancy. His father also had early fatigue on exercise with myalgias; the mother and a 12-year-old brother were asymptomatic. Muscle biopsy of both the propositus and his father showed increased glycogen storage and absent histochemical stain for PFK. Biochemical studies of muscle revealed a markedly decreased PFK activity and DNA analysis of the muscle PFK gene revealed compound heterozygosity in both cases. This is the first description of proven muscle PFK deficiency (glycogenosis type VII) in two subsequent generations.