Toxicidad de memantina intravítrea en retina de conejos / Intravitreal memantine retinal toxicity in rabbits

OBJETIVO: Valorar histopatológicamente si existe toxicidad en la retina de conejos, posterior a la aplicación intravítrea de memantina. MÉTODOS: Se utilizaron 16 ojos de 16 conejos raza Nueva Zelanda de 3 kg, divididos en 4 grupos de 4 conejos cada uno. Al grupo A se le aplicó una dosis de 70 ng/ml de memantina intravítrea, al grupo B se le aplicó una dosis de 150 ng/ml de memantina intravítrea, al grupo C se le aplicó una dosis de 400 ng/ml de memantina intravítrea, y al grupo D se le aplicó 1 ml de solución salina balanceada. Se enucleó el ojo inyectado en la mitad de cada grupo a los 15 días, y el resto del grupo se enucleó a los 30 días posterior a la inyección. Posterior a la enucleación, cada ojo fue colocado en formaldehido al 10%. Se realizó análisis histopatológico a cada uno de los ojos enucleados. Los animales fueron tratados de acuerdo a los estatutos de la Association for Research on Vision and Ophthalmology (ARVO). RESULTADOS: Los grupos A, B y D no presentaron alteraciones histopatológicas tras 15 y 30 días de enucleación. El grupo C presentó alteración a nivel de la capa de fotorreceptores a los 15 y 30 días posterior a la enucleación. CONCLUSIONES: La memantina intravítrea a dosis de 70 mg/dl y 150 mg/dl no es tóxica a nivel estructural en la retina. La memantina a dosis de 400 mg/dl es tóxica a nivel estructural en la retina. La memantina podría ser considerada en el futuro para el tratamiento de distrofias de retina. Diversos estudios deberán ser realizados al respecto

OBJECTIVE: To histologically evaluate whether the intravitreal application of memantine produces retinal toxicity in rabbits. METHODS: A cross-sectional design, experimental, descriptive study was performed on 16 eyes of 16 New Zealand rabbits of 3 kg, divided in 4 groups of 4 rabbits. A dose of 70 ng/ml of intravitreal memantine was administered in Group A, a dose of 150 ng/ml in Group B, a dose of 400 ng/ml in Group C, and Group D received 1 ml of balanced salt solution. The injected eye of half of each group was enucleated 15 days after the injection, and the rest within 30 days after injection. Following enucleation, each eye was placed in 10% formaldehyde. Histopathological analysis was performed on all enucleated eyes. The animals were treated according to the guidelines of the Association for Research on Vision and Ophthalmology (ARVO). RESULTS: Groups A, B and D did not show any histopathological changes after their enucleation at 15 and 30 days. Group C showed changes in the photoreceptor layer after enucleation at 15 and 30 days. CONCLUSIONS: In our study, it was observed that memantine concentrations at 70 ng/ml and 150 ng/ml are safe when administered intravitreally; however, doses of 400 ng/ml produced retinal structural changes. This research should continue to assess its clinical usefulness

Intravitreal memantine retinal toxicity in rabbits.

OBJECTIVE: To histologically evaluate whether the intravitreal application of memantine produces retinal toxicity in rabbits. METHODS: A cross-sectional design, experimental, descriptive study was performed on 16 eyes of 16 New Zealand rabbits of 3 kg, divided in 4 groups of 4 rabbits. A dose of 70 ng/ml of intravitreal memantine was administered in Group A, a dose of 150 ng/ml in Group B, a dose of 400 ng/ml in Group C, and Group D received 1 ml of balanced salt solution. The injected eye of half of each group was enucleated 15 days after the injection, and the rest within 30 days after injection. Following enucleation, each eye was placed in 10% formaldehyde. Histopathological analysis was performed on all enucleated eyes. The animals were treated according to the guidelines of the Association for Research on Vision and Ophthalmology (ARVO). RESULTS: Groups A, B and D did not show any histopathological changes after their enucleation at 15 and 30 days. Group C showed changes in the photoreceptor layer after enucleation at 15 and 30 days. CONCLUSIONS: In our study, it was observed that memantine concentrations at 70 ng/ml and 150 ng/ml are safe when administered intravitreally; however, doses of 400 ng/ml produced retinal structural changes. This research should continue to assess its clinical usefulness.

Comparison of Pharmacological Potency and Safety of Glutamate Blocker IEM-1913 and Memantine.

Adamantane-containing glutamate blocker IEM-1913 (1-amino-4-(1-adamantane-amino)-butane dihydrochloride) equals to memantine in antiparkinsonian potency, but surpasses it in anticonvulsive, antidepressant, and analgesic activities. Moreover, its use is less toxic and safer. IEM-1913 produces significant pharmacological effects at a wide concentration diapason (0.03-1.00 mg/kg), while memantine is effective within a narrow range only (15-20 mg/kg). High pharmacological efficacy and low toxicity of IEM-1913 can be explained by the fact that in contrast to monocationic selective NMDA antagonist memantine, the dicationic glutamate blocker IEM-1913 produces a combined block of cerebral NMDA and AMPA receptors.

Solid lipid nanoparticles loaded with lipoyl-memantine codrug: preparation and characterization.

Solid lipid nanoparticles (SLNs) are considered very attractive drug-delivery systems (DDS) able to enhance the efficacy of some therapeutic agents in several pathologies difficult to treat in a conventional way. Starting from these evidences, this study describes the preparation, physicochemical characterization, release, and in vitro cytotoxicity of stealth SLNs as innovative approach to improve solubility and absorption through the gastrointestinal tract of lipoyl-memantine (LA-MEM), a potential anti-Alzheimer codrug. Physico-chemical properties of LA-MEM loaded SLNs have been intensively investigated. Differential scanning calorimetry (DSC) was used to clarify the state and crystalline structure of the formulation. The results obtained from particles size analysis, polydispersity (PDI), and zeta potential measurements allowed the identification of the optimized formulation, which was characterized by a drug-lipid ratio 1:5, an average intensity diameter of 170nm, a PDI of 0.072, a zeta potential of -33.8mV, and an entrapment efficiency of 88%. Moreover, in vitro stability and release studies in both simulated gastric fluid (SGF) and simulated intestinal fluid (SIF), and preliminary in vitro cytotoxicity studies revealed that LA-MEM loaded SLNs could represent potential candidate for an in vivo investigation as DDS for the brain since it resulted devoid of citotoxicity and able to release the free codrug.

Cutaneous analgesia after subcutaneous injection of memantine and amantadine and their systemic toxicity in rats.

The purpose of the study is to find subcutaneous equianalgesic doses of memantine, amantadine and bupivacaine and use these doses to quantify the cardiovascular and central nervous system toxicity of these agents after intravenous administration. Memantine, amantadine and bupivacaine, a local anesthetic, in a dose-related fashion were determined for cutaneous analgesia by a block of the cutaneous trunci muscle reflex in rats, and equipotent doses were calculated. Following rapid intravenous infusion of equianalgesic bupivacaine, memantine, amantadine and saline (vehicle) in rats, we observed the onset time of seizure, apnea and impending death, and monitored mean arterial blood pressure and heart rate. Memantine and amantadine elicited dose-dependent cutaneous analgesia. At the 50% effective dose (ED(50)), the rank of potencies was bupivacaine [1.8 (1.7-2.0)]>memantine [19.1 (17.6-21.8)]>amantadine [36.1 (32.0-40.3)] (P<0.05). On ED(25), ED(50) and ED(75) basis, the duration caused by bupivacaine was similar to that caused by memantine or amantadine. At equianalgesic doses, the infusion time of memantine or amantadine required to induce seizure, impending death, and apnea was longer than that of bupivacaine during rapid intravenous infusion (P<0.01). The decreasing slope in mean arterial blood pressure and heart rate was slower with memantine and amantadine when compared with bupivacaine at equivalent doses (P<0.01). Our data showed that memantine and amantadine (i) were equal to bupivacaine at producing durations of cutaneous analgesia but (ii) were less likely than bupivacaine to cause cardiovascular and central nervous system toxicity.

Gantrez AN nanoparticles for ocular delivery of memantine: in vitro release evaluation in albino rabbits.

AIM: To prepare and evaluate the in vitro release of memantine-loaded poly(anhydride) (Gantrez®) nanoparticles (NPs). The clinical safety and retinal toxicity caused by unloaded NPs after sub-Tenon and intravitreal ocular injections were also evaluated. METHODS: Preparation and characterization of this type of NP as well as the in vitro release study are described. Twenty-three healthy New Zealand rabbits were used for clinical and histological assessment after sub-Tenon and intravitreal ocular injections of unloaded NPs. RESULTS: The amount of drug associated with NPs was 55 µg of memantine/mg of NP. The release profile of memantine from this type of NPs was characterized by an initial burst effect, followed by continuous release of the drug for at least 15 days. No relevant complications were found during the clinical follow-up. The histological evaluation suggested that Gantrez NPs are well tolerated after sub-Tenon ocular injection and that signs of inflammation during the first days after intravitreal ocular injections can be considered a normal reaction of the eye's defence mechanism.

Effects of memantine on neuronal structure and conditioned fear in the Tg2576 mouse model of Alzheimer's disease.

Memantine, an uncompetitive NMDA receptor antagonist used for the treatment of Alzheimer's disease (AD), has been hypothesized to have neuroprotective properties. However, the similarity of its mechanism of action to other NMDA receptor antagonists has led to concerns that it may also have neurotoxic effects. To assess both the neuroprotective and neurotoxic potential of memantine in a mouse model of AD (Tg2576 mice), we used quantitative light and electron microscopy to investigate the effects of long-term (6 months) administration of memantine (5, 10 and 20 mg/kg) on plaque deposition and neuronal morphology in the hippocampus and overlying cortex. A fear-conditioning paradigm was used to evaluate the behavioral consequences of any observed changes in structure. Administration of the two higher doses of memantine (10 and 20 mg/kg) was associated with a significant decrease in beta-amyloid (Abeta) plaque deposition, increases in synaptic density and the appearance of degenerating axons; the latter two effects were independent of genotype. Administration of the lowest dose of memantine (5 mg/kg) was associated with a significant decrease in Abeta plaque deposition and a significant increase in synaptic density, but not a significant increase in degenerating axons. However, memantine did not significantly improve behavioral deficits associated with genotype in a fear-conditioning paradigm at any dose. These results suggest that chronic memantine administration may have both neuroprotective and neurotoxic effects in a mouse model of AD.

Donepezil markedly potentiates memantine neurotoxicity in the adult rat brain.

The NMDA antagonist, memantine (Namenda), and the cholinesterase inhibitor, donepezil (Aricept), are currently being used widely, either individually or in combination, for treatment of Alzheimer's disease (AD). NMDA antagonists have both neuroprotective and neurotoxic properties; the latter is augmented by drugs, such as pilocarpine, that increase cholinergic activity. Whether donepezil, by increasing cholinergic activity, might augment memantine's neurotoxic potential has not been investigated. In the present study, we determined that a dose of memantine (20mg/kg, i.p.), considered to be in the therapeutic (neuroprotective) range for rats, causes a mild neurotoxic reaction in the adult rat brain. Co-administration of memantine (20 or 30 mg/kg) with donepezil (2.5-10mg/kg) markedly potentiated this neurotoxic reaction, causing neuronal injury at lower doses of memantine, and causing the toxic reaction to become disseminated and lethal to neurons throughout many brain regions. These findings raise questions about using this drug combination in AD, especially in the absence of evidence that the combination is beneficial, or that either drug arrests or reverses the disease process.