Randomized Controlled Phase 2a Study of RPh201 in Previous Nonarteritic Anterior Ischemic Optic Neuropathy.

BACKGROUND: No proven treatment exists for nonarteritic anterior ischemic optic neuropathy (NAION), either in the acute or late phase. OBJECTIVE: To assess safety and changes in visual function and structure after RPh201/placebo treatment in participants with previous NAION. DESIGN AND SETTING: Phase 2a, single-site, prospective, randomized, placebo-controlled, double-masked trial (registration NCT02045212). MAIN OUTCOMES MEASURES: Early Treatment Diabetic Retinopathy Study best-corrected visual acuity (BCVA), visual fields, retinal nerve fiber layer, and visual evoked potential at weeks 13, 26, and after a 13-week wash-out ("off-drug") period; and safety. STUDY POPULATION: Twenty-two participants aged 18 years or older with previous NAION. INTERVENTION(S): RPh201 (20 mg) or placebo (cottonseed oil vehicle) administered subcutaneously twice weekly at the study site. RESULTS: Thirteen men and 9 women were randomized, of which 20 completed all visits. The mean (±SD) age was 61.0 ± 7.6 years. In a post hoc analysis, after 26 weeks of treatment, BCVA improved by ≥15 letters in 4/11 (36.4%) eyes with RPh201, compared to 1/8 (12.5%) eyes with placebo (P = 0.24). Overall, 7/11 (63.6%) of participants on RPh201 showed some improvement in BCVA, compared with 3/8 (37.5%) on placebo (P = 0.26). Improvement in BCVA from a calculated baseline was 14.8 ± 15.8 letters for RPh201 and 6.6 ± 15.3 for placebo (P = 0.27). Of the 154 adverse effects (AEs), 52 were considered related to the study procedures/treatment. Across the study and 1,017 injections, the most frequently reported AE was injection site pain (23 events in 5 participants). There were no clinically significant changes in vital signs or laboratory values. CONCLUSIONS: This Phase 2a was designed to assess safety, feasibility, and explore potential efficacy signals in treating previous NAION with RPh201. No safety concerns were raised. The results support a larger trial in patients with previous NAION.

Toxicity and Toxicokinetic Study of Subcutaneously Administered RPh201 in Minipigs.

Mastic gum extracts are widely used as herbal remedies and are being tested for several clinical indications. Nevertheless, information on their safety is limited. RPh201 is an extract of the mastic gum, formulated and stabilized in a proprietary method, which is being developed as a novel drug candidate for neurological indications. The aim of this study was to assess the systemic toxic potential of RPh201, administered twice weekly by subcutaneous injections to minipigs, after 39 weeks of administration followed by a recovery period of 6 weeks. No clinical or dose-related signs were observed, but treatment-related findings were seen at the injection sites of the high-dose animals, composed of abscesses, chronic inflammation, and subcutaneous fibrosis. Abscesses >30 mm in size, graded as marked severity, were confined to the high-dose group and were considered as adverse. Minimal-slight subcutaneous and lymph nodes abscesses seen in control, low, and intermediate doses, related to the vehicle (cottonseed oil), were not considered as adverse. Additionally, minimal-to-slight cystic spaces or vacuolation related to the vehicle were observed in the skin, lymph nodes, kidney, and lungs. These findings were considered not to be adverse. The no-observed-adverse-effect level was considered to be 12.5 mg/kg/occasion.

A First-in-Human Phase 1 Randomized Single and Multiple Ascending Dose Study of RPh201 in Healthy Volunteers.

RPh201 is a drug extracted from gum mastic that has been studied for its anti-inflammatory and antibacterial properties. Preclinical studies of RPh201 demonstrated neuroprotective and neuroenhancing effects. Toxicology studies in animals did not reveal safety concerns or genotoxic effects. This single-center, phase 1, randomized, placebo-controlled, double-masked study in healthy volunteers assessed the safety and tolerability of RPh201, and determined the highest tolerated dose. There were 2 parts: a single ascending dose (SAD) stage, followed by a multiple ascending dose (MAD) stage. Three dosing arms were included in each stage (5 mg, 10 mg, and 20 mg). Safety data in the lower dosing arms were evaluated before higher doses were initiated. Eighteen participants were randomized in the SAD stage: 12 to RPh201 (4 at each dose) and 4 to placebo. Twenty-one participants were randomized in the MAD stage, of which 13 received RPh201. All 18 participants in the SAD stage completed treatment. Sixteen of the 21 participants in the MAD stage completed treatment. The most frequently reported adverse events were local injection site pain and erythema. No deaths or adverse events related to changes in vital signs or electrocardiograms were reported. No occurrences of suicidal behavior or ideation were reported.

Delayed (21 Days) Post Stroke Treatment With RPh201, a Botany-Derived Compound, Improves Neurological Functional Recovery in a Rat Model of Embolic Stroke.

BACKGROUND: Despite the recent advances in the acute stroke care, treatment options for long-term disability are limited. RPh201 is a botany-derived bioactive compound that has been shown to exert beneficial effects in various experimental models of neural injury. The present study evaluated the effect of delayed RPh201 treatment on long term functional recovery after stroke. METHODS: Adult male Wistar rats subjected to embolic middle cerebral artery occlusion (MCAO) were randomized into the following experimental groups (n = 20/group): (1) RPh201 treatment, and (2) Vehicle (cottonseed oil). RPh201 (20 µl) or Vehicle were subcutaneously administered twice a week for 16 consecutive weeks starting at 21 days after MCAO. An array of behavioral tests was performed up to120 days after MCAO. RESULTS: Ischemic rats treated with RPh201 exhibited significant (p < 0.05) improvement of neurological function measured by adhesive removal test, foot-fault test, and modified neurological severity score at 90 and 120 days after MCAO. Immunohistochemistry analysis showed that RPh201 treatment robustly increased neurofilament heavy chain positive axons and myelin basic protein densities in the peri-infarct area by 61% and 31%, respectively, when compared to the Vehicle treatment, which were further confirmed by Western blot analysis. The RPh201 treatment did not reduce infarct volume. CONCLUSION: Our data demonstrated that RPh201 has a therapeutic effect on improvement of functional recovery in male ischemic rats even when the treatment was initiated 21 days post stroke. Enhanced axonal and myelination densities by RPh201 in ischemic brain may contribute to improved stroke recovery.

Advances in microbial biofilm prevention on indwelling medical devices with emphasis on usage of acoustic energy.

Microbial biofilms are a major impediment to the use of indwelling medical devices, generating device-related infections with high morbidity and mortality. Major efforts directed towards preventing and eradicating the biofilm problem face difficulties because biofilms protect themselves very effectively by producing a polysaccharide coating, reducing biofilm sensitivity to antimicrobial agents. Techniques applied to combating biofilms have been primarily chemical. These have met with partial and limited success rates, leading to current trends of eradicating biofilms through physico-mechanical strategies. Here we review the different approaches that have been developed to control biofilm formation and removal, focusing on the utilization of acoustic energy to achieve these objectives.

Toxicity and toxicokinetic study of RPh201 in Sprague-Dawley rats.

Mastic gum is used for health products and in the food industry, and is being tested for several clinical indications. Nevertheless, information on its safety is scarce. Our aim was to test the local and systemic toxicity of RPh201, a botanical extract of gum mastic, and to assess the toxicokinetic profile of the mastic gum constituents masticadienonic acid (MDA) and isomasticadienonic acid (IMDA). 340 Sprague-Dawley rats were administered twice weekly subcutaneously with placebo or different doses of RPh201 for 6 months with an interim group at 3 months and a 4-week recovery group. No systemic toxicity was observed with RPh201. Local injection site reactions were observed in all animals, with comparable severity and frequency in the placebo and high dose groups. However, given the relative increase in tissue reaction in the high dose group, these changes were attributed to RPh201 administration. Nevertheless, considering the minor local irritation effects and clear trend for reversibility, the effects were not judged to be adverse. The toxicokinetic study revealed that the MDA and IMDA exposure increased with dose and the increase was supra-proportional on all days. This study supports a "no observed adverse effect level" (NOAEL) of 300 mg/kg body weight in Sprague-Dawley rats.

Effective prevention of microbial biofilm formation on medical devices by low-energy surface acoustic waves.

Low-energy surface acoustic waves generated from electrically activated piezo elements are shown to effectively prevent microbial biofilm formation on indwelling medical devices. The development of biofilms by four different bacteria and Candida species is prevented when such elastic waves with amplitudes in the nanometer range are applied. Acoustic-wave-activated Foley catheters have all their surfaces vibrating with longitudinal and transversal dispersion vectors homogeneously surrounding the catheter surfaces. The acoustic waves at the surface are repulsive to bacteria and interfere with the docking and attachment of planktonic microorganisms to solid surfaces that constitute the initial phases of microbial biofilm development. FimH-mediated adhesion of uropathogenic Escherichia coli to guinea pig erythrocytes was prevented at power densities below thresholds that activate bacterial force sensor mechanisms. Elevated power densities dramatically enhanced red blood cell aggregation. We inserted Foley urinary catheters attached with elastic-wave-generating actuators into the urinary tracts of male rabbits. The treatment with the elastic acoustic waves maintained urine sterility for up to 9 days compared to 2 days in control catheterized animals. Scanning electron microscopy and bioburden analyses revealed diminished biofilm development on these catheters. The ability to prevent biofilm formation on indwelling devices and catheters can benefit the implanted medical device industry.