Targeted delivery of pharmacological agents into rat dorsal root ganglion.

We sought an optimal method for targeted delivery into dorsal root ganglia (DRGs) for experimental studies, in terms of precision of delivery and avoidance of behavioral disturbances. We examined three approaches for injection into rat DRGs: percutaneous injection without surgical exposure, injection after deep exposure, and injection following deep exposure and partial laminectomy. Coomassie blue and Fast Blue were injected into DRGs for validation. At necropsy, the spread of Coomassie blue and Fast Blue was investigated under stereomicroscope and fluorescent microscope, respectively. We found that percutaneous approach did not provide any successful DRG injections. Deep exposure prior to intraganglionic injection provided variable results, but intraganglionic injection after deep exposure plus partial laminectomy was successful in 100% of attempts. Our subsequent skeletal analysis showed that the anatomical location of DRG is not compatible with successful DRG injection without surgical exposure. Neither of the methods using surgical exposure caused behavioral disturbances. Based on these results we conclude that partial laminectomy offers the most precise method of injecting DRG and does not produce behavioral evidence of nerve damage. Intraganglionic injection after deep exposure alone is less predictable, while percutaneous approaches only allow injection in the peripheral nerve.

The footfault test as a screening tool in the 6-hydroxydopamine rat model of Parkinson's disease.

The administration of 6-hydroxydopamine (6-OHDA) into the nigrostriatal pathway is a rat model of Parkinson's disease (PD). The footfault test is a behavioural task in which rodents have their motor functions assessed. Here, we observed that unilaterally 6-OHDA-lesioned animals show a context-induced ipsilateral rotational behaviour when placed on the footfault apparatus for 3 min and this may be used as index to detect lesioned animals. Our results showed a sensitivity and specificity of 100% for lesions higher than 94% and 64%, respectively (ROC curve: AUC=0.988). A binary logistic regression model showed an expB=1.116 (95% CI, 1.007-1.236) and C=-9.081+/-4.554 (p=0.046) using the nigral tyrosine hidroxylase immunocontent as standard (each unit represents a 10%-lesion extension). Additionally, the footfault test was more sensitive than apomorphine challenging at 1mg/kg when these tests were carried out days apart and it was less sensitive than methylphenidate at 40 mg/kg (sign test, p<0.05). Therefore, the footfault test may be very useful in the PD animal model for screening animals since it is fast and simple and it does not require a drug to induce rotational activity.

Wireless optofluidic brain probes for chronic neuropharmacology and photostimulation.

Both in vivo neuropharmacology and optogenetic stimulation can be used to decode neural circuitry, and can provide therapeutic strategies for brain disorders. However, current neuronal interfaces hinder long-term studies in awake and freely behaving animals, as they are limited in their ability to provide simultaneous and prolonged delivery of multiple drugs, are often bulky and lack multifunctionality, and employ custom control systems with insufficiently versatile selectivity for output mode, animal selection and target brain circuits. Here, we describe smartphone-controlled, minimally invasive, soft optofluidic probes with replaceable plug-like drug cartridges for chronic in vivo pharmacology and optogenetics with selective manipulation of brain circuits. We demonstrate the use of the probes for the control of the locomotor activity of mice for over four weeks via programmable wireless drug delivery and photostimulation. Owing to their ability to deliver both drugs and photopharmacology into the brain repeatedly over long time periods, the probes may contribute to uncovering the basis of neuropsychiatric diseases.

A chronically implantable, hybrid cannula-electrode device for assessing the effects of molecules on electrophysiological signals in freely behaving animals.

We describe a device for assessing the effects of diffusible molecules on electrophysiological recordings from multiple neurons. This device allows for the infusion of reagents through a cannula located among an array of micro-electrodes. The device can easily be customized to target specific neural structures. It is designed to be chronically implanted so that isolated neural units and local field potentials are recorded over the course of several weeks or months. Multivariate statistical and spectral analysis of electrophysiological signals acquired using this system could quantitatively identify electrical "signatures" of therapeutically useful drugs.

A beam-walking apparatus to assess behavioural impairments in MPTP-treated mice: pharmacological validation with R-(-)-deprenyl.

A beam-walking apparatus has been evaluated for its ability to detect motor impairments in mice acutely treated with the dopaminergic neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP, 30 mg/kg, s.c., single or double administration). Mice subjected to MPTP lesioning showed deficits in motor performance on the beam-walking task, for up to 6 days post-MPTP administration, as compared to saline-treated controls. In addition, MPTP-treated mice were detected to have a marked depletion in striatal dopamine levels and a concomitant reduction in substantia nigra (SN) tyrosine hydroxylase (TH) immunoreactivity, at 7 days post-MPTP administration, indicative of dopaminergic neuronal loss. Pre-administration of the potent MAO-B inhibitor R-(-)-deprenyl at 3 or 10 mg/kg, 30 min, s.c, significantly inhibited the MPTP-induced reduction in SN TH-immunoreactivity, striatal dopamine depletions and impairments in mouse motor function. The data described in the present study provides further evidence that functional deficits following an acute MPTP dosing schedule in mice can be quantified and are related to nigro-striatal dopamine function.

Microelectrode array-based system for neuropharmacological applications with cortical neurons cultured in vitro.

Microelectrode arrays (MEAs) provide a means to investigate the electrophysiological behavior of neuronal systems through the measurements from neuronal culture preparations. Changes in activity patterns of neuronal networks are usually detected by applying neural chemicals. Because of the difficulties of fabricating the arrays, and the delicate and less reliable properties of cortical neurons, MEA-based systems with cortical neuronal networks for neurophamacological applications are technically difficult, therefore restricting their utility. Here, we report a new approach to the development of such MEA-based system with sensitive and durable MEAs conveniently fabricated and the culture conditions optimized. Upon growth differentiation, cortical neurons, cultured directly on MEAs, reach a developmentally stable and reliable activity state. With this system, we monitored the global spontaneous activities of neuronal networks and demonstrated the fine discrimination for specific substances and unique property of cortical neurons, which validated both the applicability and necessity of such system in pharmacological bioassay.

An in vivo technique for pharmacological manipulation of Drosophila brain during optical recording.

Drosophila melanogaster, an established model for genetic manipulation, has recently been used for studying olfactory perception, learning, and memory. Some of these important behavioral phenomena have been dissected with defined mutants, some to a single biochemical lesion, expressed in central brain structures known as the mushroom bodies. A previously introduced preparation used a window in the head capsule through which these structures could be imaged using genetically expressed fluorescent calcium sensors while applying physiological odorant stimuli. Unfortunately, technical constraints prevented direct manipulation of the mushroom bodies with this preparation. I describe here a preparation that will allow, for the first time, the direct pharmacological manipulation of these important structures during imaging in the living adult fly. Responses to discreet applications of acetylcholine were reversibly blocked with tubocurare and reversibly eliminated in calcium-free Ringers. This new technique will significantly enhance the usefulness of the Drosophila model system, allowing a more quantitative examination of the mechanisms involved in olfactory learning and memory.

Validation of a mechanical apparatus for the measurement of avian walking.

Recent research has demonstrated that avian species may show an enhanced locomotor response to repeated drug exposure, a phenomenon called sensitization. Further research in this domain is warranted as such results not only establish the generality of previous findings, but may lend to a better understanding of sensitization in general. At present, there are no well-studied measurement devices for automating the measurement of bird movement. The present research evaluated a mechanical device comprised of moveable floor panels to assess its suitability. Evaluations of the device were made over the course of repeated cocaine administration. The results showed that there was high correspondence between the apparatus' responses and human observers' responses to movement by pigeons. The apparatus, furthermore, provided useful data on spatial orientation that revealed individual differences in the response to cocaine beyond those available from a collapsed measure of overall output. In sum, this recording strategy appears a viable instrument for the measurement of avian locomotion.

Applying small quantities of multiple compounds to defined locations of in vitro brain slices.

When studying in vitro brain slices, rapidly applying multiple agonists, antagonists, drugs, or modulatory compounds is a significant technical problem. There are three major ways that multiple compounds are applied to slices: by bath, via a U-tube device, or by pressure application using a "puffer" pipette. Each of these methods has advantages and disadvantages, making each more appropriate for particular purposes. Because puffer pipettes have a small, sharp tip, they are best suited to apply a small quantity of a compound to a well-defined location within the slice. When used in this way, puffer pipettes have two shortcomings. Solution leaking from the tip of the pipette can contaminate the signal, and it is difficult to apply more than one test solution to exactly the same local area of the slice. We describe methods and newly designed devices aimed at overcoming those limitations. Relatively inexpensive approaches are described to apply eight different solutions to the same exact location deep within a brain slice. The validity of the approach is verified by measuring ligand-gated channel currents activated by glutamate (Glu), acetylcholine (ACh), and gamma-amino butyric acid (GABA).

Functional magnetic resonance mapping of intracerebroventricular infusion of a neuroactive peptide in the anaesthetised rat.

Pharmacological magnetic resonance imaging (phMRI) methods map the cerebral haemodynamic response to challenge with psychotropic agents as a surrogate for drug-induced changes in brain activity. However, many neuroactive compounds present low blood-brain barrier penetration and thus systemic administration may result in insufficient brain concentration. Intracerebroventricular (ICV) administration has been long used as an effective way of bypassing the blood-brain barrier in studies with non-brain-penetrant compounds, such as neuropeptides. In order to extend the range of pharmacological substances accessible to phMRI, we have developed methods to map relative cerebral blood volume (rCBV) changes induced by in situ ICV administration of neuroactive agents in the anaesthetised rat. We have applied this method to study for the first time the phMRI response to central administration of a neuropeptide, the metabolically stable and potent NK1 receptor agonist GR-73632. ICV administration of 4.2 pmol of GR-73632 produced a rapid onset and sustained rCBV increase in several brain structures, such as the amygdala, the caudate putamen and the cortex. These results demonstrate the feasibility of phMRI as a tool to study the functional correlates of brain activity induced by central administration of neuroactive agents.

Quantitative in vitro phosphor imaging using [3H] and [18F] radioligands: the effects of chronic desipramine treatment on serotonin 5-HT2 receptors.

Traditionally, autoradiography of neuroreceptors is performed in vitro using tritiated ligands and low sensitivity X-ray film, requiring long exposure times. In vivo imaging of neuroreceptors using positron emission tomography (PET) suffers poor spatial resolution, but in vitro PET autoradiography is difficult with film due to the short half-life of the isotopes. Storage phosphor screens provide an extremely sensitive alternative to film. To demonstrate and validate quantitative in vitro phosphor imaging with PET and tritiated ligands, we treated rats chronically with the antidepressant desipramine, which results in decreased binding to serotonin 5-HT(2) receptors. Serotonin 5-HT(2) binding decreased significantly in all cortical regions examined as measured by both [(3)H]ketanserin and [(18)F]setoperone. The data from the two radioligands were not significantly different, and the distribution of the receptors was in agreement with previous reports. We also present data on the reusability of tritium-sensitive phosphor screens, and show that the use of simple corrections allows receptor binding data with PET ligands to be compared across different days. The results indicate that phosphor imaging is a valid, fast, and quantifiable technique for measuring neuroreceptor regulation, and that it provides an excellent tool to corroborate in vivo PET data in vitro at higher resolution.

The inebri-actometer: a device for measuring the locomotor activity of Drosophila exposed to ethanol vapor.

Drosophila melanogaster can be used as a model organism for probing the genetic basis for alcohol sensitivity. In this paper, we describe a new device, the inebri-actometer, which measures the locomotor activity of up to 128 individual flies simultaneously. The device consists of 128 pairs of emitter/detector photodiodes connected in series through a computer interlink. A single fly is placed in each of the 128 chambers and humidified air or air containing variable amounts of ethanol vapor is pumped through the chambers. When a fly blocks the infrared signal transmitted by an emitter photodiode, the computer records one movement for that fly. We present preliminary results showing the effect of ethanol on the activity of wild-type Oregon R Drosophila. Five preliminary runs with 95% ethanol vapor revealed that this concentration induces an approximately 3- to 4-fold increase in locomotor activity which peaks at about 5 min after the addition of ethanol vapor. This is followed by a gradual decrease in activity leading to a nearly total cessation of movement after 30 min. Statistically significant dose-related activity increases were obtained for ethanol concentrations of 8, 19, 50, and 100% of maximum, assessed in two replications at each dose. Unlike the complete suppression of locomotion seen in the last 10 min of the session at maximum ethanol exposure, the initial stimulation effect at the 19% concentration was maintained across the 30-min session.

Simple behavioral methods to assess the effect of drugs or toxins on sensory experience.

When behavioral pharmacologists/toxicologists study conditioned taste aversions (CTAs), or other conditioned responses, as a means to investigate the effects of various drugs or toxins on a learned response, failure to discover a CTA is frequently attributed to the treatment's influence on the associative process. This kind of analysis may fail to identify drug-induced sensory changes that may influence conditioned stimulus (CS) or unconditioned stimulus (US) saliency. The current paper outlines a simple method by which a drug's influence on CS or US sensation may be determined. Further, illustrative data are provided regarding how N-methyl-D-aspartate (NMDA) receptor blockade modulates taste and the sensation of malaise. Ketamine (an NMDA receptor antagonist) has been reported to block CTAs in both neonatal and adult rats. The current experiments evaluated ketamine's ability to modulate the taste of a frequently employed CS (saccharin HCl=SAC) or the aversive aspects of a common US (Lithium Chloride=LiCl). Rats normally exhibit a preference for 0.3% SAC over 0.6% SAC and will suppress consumption of these liquids following an injection of LiCl. We report that ketamine did not markedly antagonize these consummatory patterns nor did it disrupt spontaneous locomotor movements. Taken together, these findings point to ketamine's limited ability to change the sensory capacities required for CTA formation. Investigators interested in determining the underlying causes of drug-induced CTA blockade may choose to employ paradigms similar to the one used here.

Natural segmentation of the locomotor behavior of drug-induced rats in a photobeam cage.

Recently, Drai et al. (J Neurosci Methods 96 (2000) 119) have introduced an algorithm that segments rodent locomotor behavior into natural units of 'staying in place' (lingering) behavior versus going between places (progression segments). This categorization, based on the maximum speed attained within the segment, was shown to be intrinsic to the data, using the statistical method of Gaussian Mixture Model. These results were obtained in normal rats and mice using very large (650 or 320 cm) circular arenas and a video tracking system. In the present study, we reproduce these results with amphetamine, phencyclidine and saline injected rats, using data measured by a standard photobeam tracking system in square 45 cm cages. An intrinsic distinction between two or three 'gears' could be shown in all animals. The spatial distribution of these gears indicates that, as in the large arena behavior, they correspond to the difference between 'staying in place' behavior and 'going between places'. The robustness of this segmentation over arena size, different measurement system and dose of two psychostimulant drugs indicates that this is an intrinsic, natural segmentation of rodent locomotor behavior. Analysis of photobeam data that is based on this segmentation has thus a potential use in psychopharmacology research.

A new method for drug application using electrolysis of water.

A micropipette for drug application using the electrolysis of water is described. The drug solution is applied from the tip of a micropipette by the pressure of the hydrogen and oxygen gas that are produced by electrolysis of water in the micropipette. The amount of the drug applied is proportioned to the applied current and time of electrolysis. This method is simple, reliable and effective for the application of any kind of drug.

Evaluation of neuronal cell death by laser scanning cytometry.

We developed a method in which laser scanning cytometry (LSC) is applied to evaluate cell viability. Neuronal cell death induced by glutamic acid, serum potassium deprivation and 3-nitropropionic acid was studied in cerebellar granule cells by neutral red assay (NR) and LSC, using propidium iodide (PI) as fluorescent dye. PI labeled the nuclei of dead neurons and increased fluorescence was measured using a laser scanning cytometer. Similar levels of damage for each injury were detected by NR or LSC. The protocol presented here, provides a fast and sensitive assay for the analysis of neuronal viability using LSC, and can be used to study new neuroprotective drugs in neuronal cell cultures.

An economically constructed and durable intracerebral cannula system for small rodents.

An easily constructed cannula system is described for applying experimental substances to the brain of freely moving mice. Stainless steel tubing surrounded by a nylon insulator cap glued to the skull provides an economical and durable system which requires little preparation.

[Use of the antisense oligonucleotide technique in neuropsychopharmacology research].

The technique using antisense oligonucleotides has been widely used in the study of specific functions of targeted protein molecules. This technique has enabled us to perform experiments which were previously impossible in the field of neuropsychopharmacology. Some chemically modified oligonucleotide analogues (i.e., phosphorothioate, S-oligo), which are relatively nuclease-resistant, are now available. However, the molecular mechanisms of action, pharmacokinetics, and kinetics of cellular uptake of antisense oligonucleotides, have not yet been fully understood. Recently, a number of reports have described the use of antisense oligonucleotides in inhibiting gene expression in the living brain, using intact laboratory animals. In the present article, after a brief discussion of mechanisms of action of antisense oligonucleotides, the methodological aspects of antisense experiments using the "mini osmotic pump" as the oligonucleotide delivery system are reviewed. The choice, design, mode of delivery, and dose are also discussed. In particular, we address the advantages and disadvantages of the antisense oligonucleotide technique as well as the control experiments required. This technique is a powerful method and one of the most important tools in neuropsychopharmacology research.

The development of an implantable catheter system for chronic or intermittent convection-enhanced delivery.

Convection-enhanced delivery (CED) is a promising technique for the administration of therapeutic agents such as cytotoxics, neurotrophins and enzymes to the brain. In this study we describe the development of an implantable catheter system that is compatible with long-term intermittent CED. Catheters made from fused silica, PEEK or carbothane, and of various internal and external diameters were implanted in the striatum of rats and assessed for patency at 21 or 28 days. A high-rate of catheter blockage was observed with all fused silica and PEEK catheters. Carbothane catheters with an outer diameter of 0.6mm and an inner diameter of 0.35 mm had significantly lower rates of blockage (P≤0.01). Carbothane catheters were then implanted into 4 Large White/Landrace pigs and 4 NIH miniature pigs and infusions undertaken at monthly intervals to evaluate catheter patency and infusate distribution. Catheter patency was demonstrated for a maximum period of 163 days in one animal. Widespread and reproducible intraputamenal CED could be achieved with intermittent drug delivery at flow-rates as high as 5 µl/min. Problems were encountered using the pig model due to catheter distortion from rapid animal growth. In conclusion, it is possible to achieve intermittent high-flow CED with a chronic implanted carbothane catheter with a low rate of catheter blockage.

Modulating amygdala responses to emotion: evidence from pharmacological fMRI.

The use of functional MRI (fMRI) in combination with pharmacological challenges has increased exponentially in recent years, motivated by the idea not only to elucidate the neurochemical foundations of human emotional and cognitive faculties, but also to optimize human brain function in healthy individuals and identify novel drug targets, with the ultimate goal to design more specific pharmacological therapies for the various disorders of human emotion and cognition. In particular, emotional responding of the amygdala has become a central interest, and pharmacological fMRI has been used to specifically probe, and modulate, amygdala activation in response to facial expressions of emotion and emotionally laden scenes. This article reviews recent fMRI experiments manipulating the amygdala's physiological response to such stimuli by pharmacological means and lays a particular focus on monoaminergic, glutamatergic, GABAergic, and hormonal/peptidergic challenges.