Agostino Baruzzi

Fatal Familial Insomnia and Dysautonomia with Selective Degeneration of Thalamic Nuclei

The thalamus is affected in diffuse degenerative processes of the nervous system.1 2 3 4 5 However, it has not been established whether a genetically determined degenerative disease may be limited ...

Fatal familial insomnia: Clinical and pathologic study of five new cases

In 1986, we reported two anatomoclinical observations of a familial condition that we called “fatal familial insomnia” (FFI). We now present the pedigree as well as the clinical and neuropathologic findings in five new subjects. The pedigree includes 288 members from six generations. Men and women are affected in a pattern consistent with an autosomal dominant inheritance. The age of onset of the disease varies between 37 and 61 years; the course averages 13 months with a range of 7 to 25 months. Progressive insomnia (polygraphically proven in two cases); autonomic disturbances including hyperhidrosis, hyperthermia, tachycardia, and hypertension; and motor abnormalities including ataxia, myoclonus, and pyramidal dysfunction, were present in every case, but with variable severity and time of presentation. Sleep and autonomic disorders were the earliest signs in two subjects, motor abnormalities were dominant in one, and others had intermediate clinical patterns. Pathologically, all the cases had severe atrophy of the anterior ventral and mediodorsal thalamic nuclei. Other thalamic nuclei were less severely and inconsistently affected. In addition, most of the cases had gliosis of the cerebral cortex, a moderate degree of cerebellar atrophy with “torpedoes,” and severe atrophy of the inferior olivary nuclei. One case also showed spongy degeneration of the cerebral cortex. We conclude that all the lesions were primary, and that FFI is a multisystem disease in which the different structures are primarily affected with different severity. The insomnia appears to correlate best with the major thalamic pathology. The possibility that FFI belongs to the group identified as prion diseases or diseases transmitted by unconventional agents is examined.

Pharmacokinetic interactions between antiepileptic drugs : Clinical considerations

SummaryAntiepileptic drug interactions represent a common clinical problem which has been compounded by the introduction of many new compounds in recent years. Most pharmacokinetic interactions involve the modification of drug metabolism; the propensity of antiepileptic drugs to interact depends on their metabolic characteristics and action on drug metabolic enzymes.Phenobarbital, phenytoin, primidone and carbamazepine are potent inducers of cytochrome P450 (CYP), epoxide hydrolase and uridine diphosphate glucurono-syltransferase (UDPGT) enzyme systems; oxcarbazepine is a weak inducer of CYP enzymes, probably acting on a few specific isoforms only. All stimulate the rate of metabolism and the clearance of the drugs which are catabolised by the induced enzymes.Valproic acid (valproate sodium) inhibits to different extents many hepatic enzyme system activities involved in drug metabolism and is able to significantly displace drugs from plasma albumin. Felbamate is an inhibitor of some specific CYP isoforms and mitochondrial β-oxidation, whereas it is a weak inducer of other enzyme systems.Topiramate is an inducer of specific CYP isoforms and an inhibitor of other isoforms. Ethosuximide, vigabatrin, lamotrigine, gabapentin and possibly zonisamide and tiagabine have no significant effect on hepatic drug metabolism.Apart from vigabatrin and gabapentin, which are mainly eliminated unchanged by the renal route, all other antiepileptic drugs are metabolised wholly or in part by hepatic enzymes and their disposition may be altered by metabolic changes.Some interactions are clinically unremarkable and some need only careful clinical monitoring, but others require prompt dosage adjustment. From a practical point of view, if valproic acid is added to lamotrigine or phenobarbital therapy, or if felbamate is added to phenobarbital, phenytoin or valproic acid therapy, a significant rise in plasma concentrations of the first drug is expected with a corresponding increase in clinical effects. In these cases a concomitant reduction of the dosage of the first drug is recommended to avoid toxicity. Conversely, if a strong inducer is added to carbamazepine, lamotrigine, valproic acid or ethosuximide monotherapy, a significant decrease in their plasma concentrations is expected within days or weeks, with a possible reduction in efficacy. In these cases a dosage increase of the first drug may be required.

Deficit of in vivo mitochondrial ATP production in OPA1-related dominant optic atrophy.

Dominant optic atrophy has been associated with mutations in the OPA1 gene, which encodes for a dynamin‐related GTPase, a mitochondrial protein implicated in the formation and maintenance of mitochondrial network and morphology. We used phosphorus magnetic resonance spectroscopy to assess calf muscle oxidative metabolism in six patients from two unrelated families carrying the c.2708‐2711delTTAG deletion in exon 27 of the OPA1 gene. The rate of postexercise phosphocreatine resynthesis, a measure of mitochondrial adenosine triphosphate production rate, was significantly delayed in the patients. Our in vivo results show for the first time to our knowledge a deficit of oxidative phosphorylation in OPA1‐related DOA. Ann Neurol 2004;56:719–723

Idebenone Treatment In Leber's Hereditary Optic Neuropathy

Sir, We have read with great interest the results presented by Klopstock et al. (2011) concerning the RHODOS study on a clinical trial with idebenone in Lebers hereditary optic neuropathy (LHON) and we would like to share our own experience of idebenone therapy in LHON. Idebenone has been an approved drug (Mnesis®, Takeda Italia Farmaceutici) in Italy since the early 1990s and, after the initial report by Mashima et al . (1992) on its possible efficacy in LHON, we offered this therapeutic option to all of our new consecutive patients with LHON, almost all of whom accepted treatment. Idebenone was given after informed consent following the regulation for ‘off-label’ drug administration and was provided for free by the National Health Service, under the legislation for certified rare disorders. Patients were initially treated with 270 mg/day (Cortelli et al ., 1997; Carelli et al ., 1998 a , b ), but following the reports on idebenone treatment in Friedreich ataxia, the dosages were increased to 540–675 mg/day (Rustin et al ., 1999; Kearney et al ., 2009). To evaluate retrospectively the efficacy of idebenone therapy, we reviewed all of our patients with LHON, idebenone treated and untreated, after approval of the institutional Internal Review Board. Inclusion criteria for treated patients were the initiation of therapy within 1 year after visual loss in the second eye, and for all patients (treated and untreated) age at onset of at least 10 years and a follow-up of at least 5 years. We included only patients treated within 1 year after onset because this is the time frame to reach the nadir of the visual loss and the probability of spontaneous recovery of vision is highest in the following 5 years (Nikoskelainen et al ., 1983; Barboni et al ., 2005, 2010; …

Oxcarbazepine: Pharmacokinetic Interactions and Their Clinical Relevance

Summary: Antiepileptic drug (AED) interactions are a common problem during epilepsy treatment. Oxcarbazepine (OCBZ) is a keto homologue of carbamazepine (CBZ) with a completely different metabolic profile. In humans, the keto group is rapidly and quantitatively reduced to form a mono‐hydroxy derivative (MHD), which is the main active agent during OCBZ therapy. MHD is eliminated by renal excretion, glucuronidation and, marginally, by hydroxylation to a diol derivative. This metabolic profile, and in particular the limited involvement of oxidative microsomal enzymes, suggests that OCBZ may have fewer drug interactions compared with traditional AEDs. This possibility has been investigated in experimental studies and, retrospectively, in data obtained from clinical trials. The capacity of OCBZ to induce microsomal enzymes of the P‐450 family has mostly been examined by use of antipyrine and CBZ kinetics as markers. The results suggest that OCBZ has little enzyme inducing capacity. In clinical trials in which OCBZ was substituted for CBZ, plasma concentrations of concomitant AEDs were increased, possibly as a consequence of total or partial de‐induction. OCBZ interference with other drugs has been evaluated for warfarin, felodipine, and oral contraceptives, three medications strongly influenced by enzyme‐inducing AEDs. OCBZ does not modify the anticoagulant effect of warfarin, whereas some reduction in felodipine concentration and a clinically significant reduction of contraceptive drug levels and efficacy were observed. Polytherapy with established AEDs does not significantly modify OCBZ disposition (MHD kinetics); however, available information is not extensive. Finally, the action on OCBZ kinetics of a group of drugs (verapamil, cimetidine, erythromycin, dextropropoxyphene, and viloxazine) known to inhibit the metabolism of some AEDs has been studied. None of the drugs caused kinetic modification^ likely to be of clinical relevance. OCBZ has a favorable metabolic profile and fewer drug interactions compared with established AEDs. These findings should be confirmed by more clinical trials and use.

Skin nerve α-synuclein deposits: a biomarker for idiopathic Parkinson disease.

Objective:To investigate (1) whether phosphorylated &agr;-synuclein deposits in skin nerve fibers might represent a useful biomarker for idiopathic Parkinson disease (IPD), and (2) the underlying pathogenesis of peripheral neuropathy associated with IPD. Methods:Twenty-one well-characterized patients with IPD were studied together with 20 patients with parkinsonisms assumed not to have &agr;-synuclein deposits (PAR; 10 patients fulfilling clinical criteria for vascular parkinsonism, 6 for tauopathies, and 4 with parkin mutations) and 30 controls. Subjects underwent nerve conduction velocities from the leg to evaluate large nerve fibers and skin biopsy from proximal (i.e., cervical) and distal (i.e., thigh and distal leg) sites to study small nerve fibers and deposits of phosphorylated &agr;-synuclein considered the pathologic form of &agr;-synuclein. Results:Patients with IPD showed a small nerve fiber neuropathy prevalent in the leg with preserved large nerve fibers. PAR patients showed normal large and small nerve fibers. Phosphorylated &agr;-synuclein was not found in any skin sample in PAR patients and controls, but it was found in all patients with IPD in the cervical skin site. Abnormal deposits were correlated with leg epidermal denervation. Conclusions:The search for phosphorylated &agr;-synuclein in proximal peripheral nerves is a sensitive biomarker for IPD diagnosis, helping to differentiate IPD from other parkinsonisms. Neuritic inclusions of &agr;-synuclein were correlated with a small-fiber neuropathy, suggesting their direct role in peripheral nerve fiber damage. Classification of evidence:This study provides Class III evidence that the presence of phosphorylated &agr;-synuclein in skin nerve fibers on skin biopsy accurately distinguishes IPD from other forms of parkinsonism.Objective: To investigate (1) whether phosphorylated α-synuclein deposits in skin nerve fibers might represent a useful biomarker for idiopathic Parkinson disease (IPD), and (2) the underlying pathogenesis of peripheral neuropathy associated with IPD. Methods: Twenty-one well-characterized patients with IPD were studied together with 20 patients with parkinsonisms assumed not to have α-synuclein deposits (PAR; 10 patients fulfilling clinical criteria for vascular parkinsonism, 6 for tauopathies, and 4 with parkin mutations) and 30 controls. Subjects underwent nerve conduction velocities from the leg to evaluate large nerve fibers and skin biopsy from proximal (i.e., cervical) and distal (i.e., thigh and distal leg) sites to study small nerve fibers and deposits of phosphorylated α-synuclein considered the pathologic form of α-synuclein. Results: Patients with IPD showed a small nerve fiber neuropathy prevalent in the leg with preserved large nerve fibers. PAR patients showed normal large and small nerve fibers. Phosphorylated α-synuclein was not found in any skin sample in PAR patients and controls, but it was found in all patients with IPD in the cervical skin site. Abnormal deposits were correlated with leg epidermal denervation. Conclusions: The search for phosphorylated α-synuclein in proximal peripheral nerves is a sensitive biomarker for IPD diagnosis, helping to differentiate IPD from other parkinsonisms. Neuritic inclusions of α-synuclein were correlated with a small-fiber neuropathy, suggesting their direct role in peripheral nerve fiber damage. Classification of evidence: This study provides Class III evidence that the presence of phosphorylated α-synuclein in skin nerve fibers on skin biopsy accurately distinguishes IPD from other forms of parkinsonism.

The ND1 gene of complex I is a mutational hot spot for Leber's hereditary optic neuropathy

A novel mitochondrial DNA (mtDNA) transition (3733G→A) inducing the E143 K amino acid change at a very conserved site of the NADH dehydrogenase subunit 1 (ND1) was identified in a family with six maternally related individuals with Lebers hereditary optic neuropathy (LHON) and in an unrelated sporadic case, all negative for known mutations and presenting with the canonical phenotype. The transition was not detected in 1,082 control mtDNAs and was heteroplasmic in several individuals from both pedigrees. In addition, the mtDNAs of the two families were found to belong to different haplogroups (H and X), thus confirming that the 3733G→A mutation occurred twice independently. Phosphorus magnetic resonance spectroscopy disclosed an in vivo brain and skeletal muscle energy metabolism deficit in the four examined patients. Muscle biopsy from two patients showed slight mitochondrial proliferation with abnormal mitochondria. Biochemical investigations in platelets showed partially insensitive complex I to rotenone inhibition. We conclude that the 3733G→A transition is a novel cause of LHON and, after those at positions 3460 and 4171, is the third ND1 mutation to be identified in multiple unrelated families. This finding shows that, in addition to ND6, the ND1 subunit gene is also a mutational hot spot for LHON. Ann Neurol 2004;56:631–641

Levetiracetam therapeutic monitoring in patients with epilepsy: effect of concomitant antiepileptic drugs.

Background: Lacosamide (LCM) is one of the newer antiepileptic drugs (AEDs) licensed as add-on treatment for partial epilepsy. Data on LCM pharmacokinetics and interactions are limited and partly contradictory. The purpose of this study was to assess the effect of concomitant AED therapy on steady state plasma concentrations of LCM in a population of patients with epilepsy. Methods: Steady state plasma concentrations of LCM were assessed in a cohort of 75 consecutive patients with epilepsy referred to the Laboratory of Clinical Neuropharmacology for AED therapeutic monitoring over 16 months. Plasma LCM concentrations were measured by high-performance liquid chromatography with spectrophotometric detection. Results: Median morning trough plasma concentration-to-weight-adjusted dose ratio of LCM [(mg/L)/(mg/kg/d)] was significantly reduced (0.94 versus 1.35, P < 0.001) in patients treated with LCM plus AED strong inducers of cytochrome P450 metabolism, namely, carbamazepine, phenobarbital, and phenytoin (group A, n = 33), compared with a pool of patients not comedicated with AED strong inducers, predominantly including oxcarbazepine, levetiracetam, lamotrigine, and valproic acid (group B, n = 42). The 2 groups were comparable for age, gender, weight, LCM daily dose, and dosing frequency. LCM plasma concentrations were linearly related to daily drug doses, regardless of concomitant AED therapy, over a dose range from 75 to 600 mg/d, although, at a given drug dose, a large interpatient variability was observed in matched, plasma drug concentration. Conclusions: Our findings confirm, in a real-patient clinical setting, preliminary evidence from randomized, clinical trials showing that carbamazepine, phenobarbital, or phenytoin significantly reduces the overall systemic exposure to LCM. From a practical point of view, patients on concomitant AED strong inducers may require a 30% higher dose of LCM compared with patients not receiving strongly inducing AED cotherapy, to achieve the same plasma drug concentration.

Diurnal Fluctuations in Free and Total Steady‐State Plasma Levels of Carbamazepine and Correlation with Intermittent Side Effects

Summary: The relationship between diurnal fluctuations in free (unbound) and total plasma carbamazepine levels and the appearance of intermittent side effects was investigated in nine epileptic patients receiving chronic therapy with carbamazepine, alone or in combination with phenobarbital. On a three‐times‐daily or four‐times‐daily dosing schedule, both total and free carbamazepine levels fluctuated considerably (on an average, 41 and 45%, respectively, around the mean). Side effects (particularly diplopia and nystagmus) were observed in five patients and showed an intermittent pattern in four. Side effects were never found at total carbamazepine levels<34 μmol/L but invariably appeared at levels >38 μmol/L. At levels between 34 and 38 (μmol/L adverse effects were inconsistently observed. The correlation between plasma carbamazepine levels and manifestations of toxicity was slightly stronger when free rather than total levels were considered. Side effects were always apparent at free levels >7.2 μmol/L. These data underline the limitations of relying on a single drug level determination during the monitoring of carbamazepine therapy and emphasize the necessity of carefully adjusting the dosing schedule, to minimize the appearance of intermittent adverse effects.