Lisa D. Coles

N-acetylcysteine boosts brain and blood glutathione in gaucher and Parkinson diseases

Objective This study aimed to determine if the antioxidant N-acetylcysteine (NAC) is able to alter peripheral and central redox capabilities in patients with Parkinson disease (PD) or Gaucher disease (GD). Methods The study included nondemented adult subjects: 3 with PD, 3 with GD, and 3 healthy controls. Baseline brain glutathione (GSH) concentrations were measured using 7-T magnetic resonance spectroscopy (MRS). Baseline blood reduced-to-oxidized GSH ratios were determined for each subject. Brain GSH concentrations and blood redox ratios were then determined during and at specified time points after a single, 150-mg/kg NAC infusion. Results N-acetylcysteine increased blood GSH redox ratios in those with PD and GD and healthy controls, which was followed by an increase in brain GSH concentrations in all subjects. Conclusions This is the first demonstration that with MRS, it is possible to directly measure and monitor increases in brain GSH levels in the human brain in response to a single, intravenous administration of NAC. This work shows the potential utility of MRS monitoring, which could assist in determining dosing regimens for clinical trials of this potentially useful antioxidant therapy for PD disease, GD, and other neurodegenerative disorders.

Canine status epilepticus: A translational platform for human therapeutic trials

Current treatment of human status epilepticus (SE) relies on drugs developed for chronic treatment of epilepsy. Many potent compounds have been discovered in animal models of SE. But they may never be useful for chronic treatment of epilepsy and thus not available for human use. Naturally occurring canine SE may become a translational platform for evaluating these compounds for eventual use in human trials. A pilot study of levetiracetam in canine SE demonstrated a 56% response rate compared to 10% for placebo. Based on these results we have obtained an NIH R‐21 to further evaluate canine SE as a translational platform for developing new approaches for treating human SE.

Estradiol and progesterone-mediated regulation of P-gp in P-gp overexpressing cells (NCI-ADR-RES) and placental cells (JAR)

The effect of progesterone and estrogen treatment on the expression and function of P-glycoprotein (P-gp) was evaluated in JAR cells and a P-gp overexpressing cell line, NCI-ADR-RES. Western blot analysis and real-time Q-PCR were used to evaluate P-gp protein and MDR1 mRNA expression respectively in the cells following incubation with progesterone (P4) and/or beta-estradiol (E2). Cellular uptake studies of the P-gp substrates, saquinavir and paclitaxel, were performed to evaluate function. Treatment with either E2 or P4 resulted in a significant increase in P-gp protein levels in the NCI-ADR-RES cells at concentrations of or greater than 100 nM or 10 nM, respectively. JAR cells also had increased levels of P-gp with 100 nM of P4 but were much more sensitive to E2 showing increased P-gp at a concentration of 1 nM. Furthermore, E2 or P4 treatment resulted in a significant decrease in cellular uptake of the P-gp substrates tested in these cells lines. Based on mRNA quantitation, a transient increase (2-fold) in MDR1 levels was observed at 8 h postincubation with either E2 or P4, while MDR1 levels remained high in the JAR cells treated with E2 for 72 h postincubation. The addition of actinomycin D, a transcription inhibitor negated the increase in P-gp by P4 and E2. P4 and E2 increase P-gp expression and function in NCI-ADR-RES and JAR cells with the ERalpha-expressing cells (JAR) much more sensitive to E2. Furthermore, transcriptional regulation by E2 and P4 likely contributes to the modulation of P-gp levels.

Distribution of Saquinavir, Methadone, and Buprenorphine in Maternal Brain, Placenta, and Fetus During Two Different Gestational Stages of Pregnancy in Mice

Efflux transporters such as P-glycoprotein (P-gp) play a critical role in the maternal-to-fetal and blood-to-brain transfer of many drugs. Using a mouse model, the effects of gestational age on P-gp and MRP expression in the placenta and brain were evaluated. P-gp protein levels in the placenta and brain were greater at mid-gestation (gd 13) than late-gestation (gd 18). Likewise, brain MRP1 levels were greater at mid-gestation, whereas, placental levels were greater at late-gestation. To evaluate these effects on drug disposition, concentrations of [(3)H]saquinavir, [(3)H]methadone, [(3)H]buprenorphine, and the paracellular marker, [(14)C]mannitol were measured in plasma, brain, placenta, and fetal samples after i.v. administrations to nonpregnant and pregnant mice. Following i.v. administration, [(3)H]saquinavir placenta-to-plasma and fetal-to-plasma ratios were significantly greater in late-gestation mice versus mid-gestation. Furthermore, late-gestation mice experienced significant increases in the [(3)H]saquinavir and [(3)H]methadone brain-to-plasma ratios 60 min after dosing relative to mid-gestation (p < 0.05). No significant differences were observed in these tissue-to-plasma ratios for buprenorphine or mannitol. Repeated dosing (three doses, once daily) decreased the differential uptake of [(3)H]saquinavir in brain but potentiated it in the fetus. These results suggest that differential expression of P-gp and possibly MRP1 contributes to the gestational-induced changes in brain and fetal uptake of saquinavir.

Feasibility Study of a Caregiver Seizure Alert System in Canine Epilepsy

A device capable of detecting seizures and alerting caregivers would be a major advance for epilepsy management, and could be used to guide early intervention and prevent seizure-related injuries. The objective of this work was to evaluate a seizure advisory system (SAS) that alerts caregivers of seizures in canines with naturally occurring epilepsy. Four dogs with epilepsy were implanted with a SAS that wirelessly transmits continuous intracranial EEG (iEEG) to an external device embedded with a seizure detection algorithm and the capability to alert caregivers. In this study a veterinarian was alerted by automated text message if prolonged or repetitive seizures occurred, and a rescue therapy protocol was implemented. The performance of the SAS caregiver alert was evaluated over the course of 8 weeks. Following discontinuation of antiepileptic drugs, the dogs experienced spontaneous unprovoked partial seizures that secondarily generalized. Three prolonged or repetitive seizure episodes occurred in 2 of the dogs. On each occasion, the SAS caregiver alert successfully alerted an on call veterinarian who confirmed the seizure activity via remote video-monitoring. A rescue medication was then administered and the seizures were aborted. This study demonstrates the feasibility of a SAS to alert caregivers to the occurrence of prolonged or repetitive seizures and enables rescue medications to be delivered in a timely manner. The SAS may improve the management of human epilepsy by alerting caregivers of seizures, enabling early interventions, and potentially improving outcomes and quality of life of patients and caregivers.

Interaction of N-acetylcysteine and Cysteine in Human Plasma

N-acetyl-L-cysteine (NAC), a well-known antioxidant, has been successfully used as adjuvant therapy for late-stage childhood cerebral adrenoleukodystrophy (c-ALD); however, the mechanisms of NAC action are poorly understood. Previous research indicates that NAC serves as a precursor to L-cysteine (Cys), the rate-limiting substrate in the biosynthesis of glutathione (GSH), a potent, endogenous antioxidant. We hypothesized that NAC acts by liberating protein-bound Cys in plasma in an NAC concentration-dependent manner, which increases unbound Cys available for GSH biosynthesis. Human plasma was incubated for 1 h with varying, clinically relevant concentrations of NAC (0-1000 µg/mL). The effect of this interaction over time was evaluated by incubating plasma for 5-90 min with 100 µg/mL NAC. Unbound and bound Cys and NAC were separated by ultrafiltration, and concentrations were measured using high-performance liquid chromatography-mass spectrometry. Significant increases in unbound Cys were observed with increasing NAC concentrations. Also, Cys plasma protein binding decreased from 85% (10 µg/mL NAC) to approximately 0% (1000 µg/mL). Total endogenous Cys was 66% unbound at 5 min after incubation. These results demonstrate that NAC liberates endogenous, protein-bound Cys in human plasma at clinically relevant NAC concentrations. A greater understanding of NAC actions will aid in the optimization of NAC therapy including its use in c-ALD.

Intravenous Administration of Stable-Labeled N-Acetylcysteine Demonstrates an Indirect Mechanism for Boosting Glutathione and Improving Redox Status

There is an increasing interest in using N-acetylcysteine (NAC) as a treatment for neurodegenerative disorders to increase glutathione (GSH) levels and its redox status. The purpose of this study was to characterize the biosynthesis of NAC to GSH using a novel stable isotope-labeled technique, and investigate the pharmacodynamics of NAC in vivo. Female wild-type mice were given a single intravenous bolus dose of 150 mg kg(-1) stable-labeled NAC. Plasma, red blood cells (RBC), and brain tissues were collected at predesignated time points. Stable-labeled NAC and its metabolite GSH (both labeled and unlabeled forms) were quantified in blood and brain samples. Molar ratios of the reduced and oxidized forms of GSH (GSH divided by glutathione disulfide, redox ratio) were also determined. The elimination phase half-life of NAC was approximately 34 min. Both labeled and unlabeled GSH in RBC were found to increase; however, the area under the curve above baseline (AUCb0-280 ) of labeled GSH was only 1% of the unlabeled form. These data indicate that NAC is not a direct precursor of GSH. In addition, NAC has prolonged effects in brain even when the drug has been eliminated from systemic circulation.

Canine status epilepticus treated with fosphenytoin: A proof of principle study

There are a limited number of marketed intravenous antiepileptic drugs (AEDs) available to treat status epilepticus (SE). All were first developed for chronic therapy of epilepsy, not specifically for SE. Epilepsy and canine SE (CSE) occur naturally in dogs, with prevalence, presentation, and percentage of refractory cases similar to human epilepsy. The objective of this study was to determine if CSE treated with fosphenytoin (FOS) results in a similar responder rate as for people.

A Pilot Study Assessing Pharmacokinetics and Tolerability of Oral and Intravenous Baclofen in Healthy Adult Volunteers

Our objective was to characterize baclofen pharmacokinetics and safety given orally and intravenously. Twelve healthy subjects were enrolled in a randomized, open-label, crossover study and received single doses of baclofen: 3 or 5 mg given intravenously and 5 or 10 mg taken orally with a 48-hour washout. Blood samples for baclofen analysis were collected pre-dose and at regular intervals up to 24 hours post-dose. Clinical response was assessed by sedation scores, ataxia, and nystagmus. Mean absolute bioavailability of oral baclofen was 74%. Dose-adjusted areas under the curve between the oral and intravenous arms were statistically different (P = .0024), whereas area under the curve variability was similar (coefficient of variation: 18%-24%). Adverse effects were mild in severity and not related to either dose or route of administration. Three- and 5-mg intravenous doses of baclofen were well tolerated. Seventy-four percent oral bioavailability indicates that smaller doses of intravenous baclofen are needed to attain comparable total drug exposures.

Repeated‐Dose Oral N‐Acetylcysteine in Parkinson's Disease: Pharmacokinetics and Effect on Brain Glutathione and Oxidative Stress

Parkinsons disease (PD) is associated with oxidative stress and decreased nigral glutathione (GSH), suggesting that therapies that boost GSH may have a disease‐modifying effect. Intravenous administration of a high dose of N‐acetylcysteine (NAC), a well‐known antioxidant and GSH precursor, increases blood and brain GSH in individuals with PD and with Gaucher disease and in healthy controls. To characterize the pharmacokinetics of repeated high oral doses of NAC and their effect on brain and blood oxidative stress measures, we conducted a 4‐week open‐label prospective study of oral NAC in individuals with PD (n = 5) and in healthy controls (n = 3). Brain GSH was measured in the occipital cortex using 1H‐MRS at 3 and 7 tesla before and after 28 days of 6000 mg NAC/day. Blood was collected prior to dosing and at predetermined collection times before and after the last dose to assess NAC, cysteine, GSH, catalase, malondialdehyde (MDA) and 4‐hydroxynonenal (4‐HNE) concentrations and the reduced‐to‐oxidized GSH ratio (GSH/ glutathione disulfide [GSSG]). Symptomatic adverse events were reported by 3 of the 5 subjects with PD. NAC plasma concentration–time profiles were described by a first‐order absorption, 1‐compartment pharmacokinetic model. Although peripheral antioxidant measures (catalase and GSH/GSSG) increased significantly relative to baseline, indicators of oxidative damage, that is, measures of lipid peroxidation (4‐HNE and MDA) were unchanged. There were no significant increases in brain GSH, which may be related to low oral NAC bioavailability and small fractional GSH/GSSG blood responses. Additional studies are needed to further characterize side effects and explore the differential effects of NAC on measures of antioxidant defense and oxidative damage.