An article by Valentina Franco et al at several institutions in Italy and Norway published in the July 2023 edition of Pharmaceutics described a validated method for measuring an antiepileptic medicine from oral fluid in saliva samples collected using Mitra® microsampling devices based on VAMS® technology. Their paper was entitled “Therapeutic Salivary Monitoring of Perampanel in Patients with Epilepsy Using a Volumetric Absorptive Microsampling Technique.”
According to the World Health Organization (WHO), around 50 million people globally are living with epilepsy, with 80% living in low- and middle-income countries. The causes of this neurological disorder can include issues during childbirth, head trauma, infection of the brain, genetic abnormalities, stroke, and brain tumors. It is thought that 25% of epilepsy cases could be averted by taking measures to prevent some of the known causes, such as head injuries, adequate perinatal care, fever-reducing drugs, reducing risk factors around stroke and elimination of parasites in tropical areas, which can lead to brain infections, such as neurocysticercosis.
It is thought that nearly 70% of people living with epilepsy could be seizure free if they had access to appropriate antiseizure medicines. There are roughly 30 antiepileptic drugs (AEDs) currently on the market, one of which is perampanel (PER), an oral suspension medication that is sold under different brand names. The action or mechanism of PER is not fully understood; however, it is known that it acts as a selective antagonist of the postsynaptic ionotropic alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) glutamate receptor. It is also known that the glutamate is a major excitatory neurotransmitter. The current working hypothesis is that the AMPA receptor antagonism can reduce over stimulation of AMPA, thus inhibiting seizures.
In both Europe and the United States, PER is approved as an antiepileptic for adults and children over 12, though the types of seizures the drug is approved for differs with the age of the individual. Clinical trials using healthy volunteers showed that the elimination half-life was 53-136 hours, however, the clearance rate is affected by certain co-medications. For example, if PER is co-administered with another epilepsy drug, carbamazepine, then the total clearance rate of PER increases by three times. Similar effects are also seen when co-medicated with phenytoin or oxcarbazepine. As a result, it is important to therapeutically monitor PER in individuals, especially those on certain comedications.
The paper by Valentina Franco et al references two previously published studies where it is stated that therapeutic drug monitoring (TDM) of PER could be beneficial.
For most therapeutic drug monitoring, plasma is the standard matrix used and venipuncture is the standard means of collecting the required blood samples. Oral fluid (saliva), on the other hand, presents an intriguing potential alternative matrix for TDM. The major advantage of saliva is that the collection method is non-invasive, which is beneficial for needle-phobic and vulnerable cohorts, such as young children. Moreover, oral fluid can be easily collected by non-trained personnel.
However, use of saliva for therapeutic monitoring is not without its challenges. One challenge is that analytes are sometimes at a lower concentration in this matrix, making detection and quantitation challenging. Another challenge involves correlating serum or plasma equivalent values to those found in saliva, though the authors did reference another study where saliva had been successfully correlated with plasma for antiseizure medications. As with all wet matrices, there can also be concerns pertaining to compound stability.
The advantages of this remote microsampling technology are that it enables home sampling, and it is designed to collect and store dried samples that can be sent via standard mail at room temperature with good stability.
The study authors believed this approach was well-suited for convenient, remote, and reliable sampling for TDM. They were further encouraged by case studies in the literature that showed dried blood collection using volumetric absorptive microsampling had been successfully used for antiepileptic research. They also learned that the VAMS technique had been successfully used for alternative fluid collection, including urine and saliva.
With this in mind, Franco et al embarked on their study to validate a dried salivary VAMS assay for TDM of PER.
The researchers conducted a successful validation of salivary monitoring of PER from saliva microsamples using VAMS technology and LC-MS/MS in accordance with European Medicines Agency Guideline on Bioanalytical Method Validation.
Study Highlights Include:
As LC-MS/MS instrumentation continues to improve in terms of sensitivity and specificity, coupling it with microsamples taken from alternative fluids provides an intriguing new avenue for drug and biomarker analysis. The non-invasive nature of saliva sample collection is an attractive option and an important biofluid to consider for future analysis. Moreover, if more studies show corroborative evidence of good correlation between serum and saliva levels, then saliva may play an even greater role in TDM in the future.
Furthermore, coupling LC-MS/MS studies to self-sampling using dried matrix collection devices vastly increases the options patients and study volunteers have for providing high-quality samples to the lab for analysis. This study demonstrates how effective oral fluid (saliva) samples collected on Mitra-VAMS devices can be for such applications.
This blog includes content curated from a published study paper that was summarized for our readers by James Rudge, PhD, Microsampling Technical Director, Trajan. To learn more about the important research discussed here, please visit the original article in Pharmaceutics.
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