Thermoreversible Switchlike Electrocatalytic Reduction of Tizanidine Based on a Graphene Oxide Tethered Stimuli-Responsive Smart Surface Supported Pd Catalyst.

In this work, a graphene oxide (GRO)-based temperature-sensitive smart catalytic support material was developed by tethering biodegradable and hydrophilic poly(N-vinylcaprolactam) (PVCL) on a GRO (i.e., GRO-PVCL) surface. GRO-PVCL-supported palladium catalyst (i.e., Pd/GRO-PVCL) was then prepared for tizanidine (TZN) electroreduction. The impact of a temperature-sensitive smart surface on the electrochemical and electrocatalytic properties was examined. Moreover, when the large surface area, excellent electron transfer, and electrochemical catalysis abilities of GRO were combined with the responsive characteristics of PVCL, temperature-triggered reversible electrocatalysis of TZN with enhanced sensitivity has been proved. Results designated that GRO-PVCL exposed the hydrophilic surface at 20 °C, resulting in Pd NPs highly dispersed on the GRO-PVCL surface. Subsequently, the wettability of the Pd catalyst surface arbitrarily adapted to hydrophobicity at 40 °C, which highly enhanced the TZN reduction on the catalyst in electrochemical detection. The synergistic effect amid Pd and GRO-PVCL on Pd/GRO-PVCL improved the electrocatalytic activity of TZN. The detection of TZN with the Pd/GRO-PVCL modified electrode ranged from 0.02 to 276 µM with a low detection limit of 0.0015 µM at 40 °C. The Pd/GRO-PVCL modified electrode also possesses excellent stability, reproducibility, and anti-interference ability. Lastly, the modified electrode attained good recovery results in human urine and human plasma samples for the determination of TZN and also pharmacokinetics study in rat plasma.

Synthesis and carbonic anhydrase activating properties of a series of 2-amino-imidazolines structurally related to clonidine1.

The Carbonic Anhydrase (CA, EC 4.2.1.1) activating properties of histamine have been known for a long time. This compound has been extensively modified but only in few instances the imidazole ring has been replaced with other heterocycles. It was envisaged that the imidazoline ring could be a bioisoster of the imidazole moiety. Indeed, we report that clonidine, a 2-aminoimidazoline derivative, was found able to activate several human CA isoforms (hCA I, IV, VA, VII, IX, XII and XIII), with potency in the micromolar range, while it was inactive on hCA II. A series of 2-aminoimidazoline, structurally related to clonidine, was then synthesised and tested on selected hCA isoforms. The compounds were inactive on hCA II while displayed activating properties on hCA I, VA, VII and XIII, with KA values in the micromolar range. Two compounds (10 and 11) showed some preference for the hCA VA or VII isoforms.

Development of Solid Self-Microemulsifying System of Tizanidine Hydrochloride for Oral Bioavailability Enhancement: In Vitro and In Vivo Evaluation.

The aim of the present investigation was to formulate self-microemulsifying drug delivery system (SMEDDS) tablets to enhance the oral bioavailability of tizanidine hydrochloride. SMEDDS was prepared by using Capmul G as the oil phase, Tween 20 as the surfactant, and propylene glycol as the co-surfactant. The optimized formulation was characterized by dilution test, % transmittance, thermodynamic stability, dye solubility, assay, globule size, zeta potential, and TEM. A dye solubility test confirmed the formation of o/w microemulsion. Optimized formulation of SMEDDS had a drug content of 98 ± 0.75% (3.2± 0.3 mg) and droplet size of 96.61 ± 2.3 nm. Dilution and centrifugation tests indicated the physical stability of the formulation. The optimized SMEDDS was mixed with Neusilin as adsorbent, microcrystalline cellulose as diluent, and magnesium stearate as flow promoter, and compressed into tablets. The prepared tablets passed the tests of weight variation, hardness, friability, and assay. In vitro dissolution test indicated sustained release of tizanidine hydrochloride from the SMEDDS tablet for a period of 4 h. In vivo pharmacokinetic studies performed on male New Zealand rabbits showed a 4.61-fold increase in bioavailability compared with the marketed formulation. Thus, the developed SMEDDS tablet proved to be capable of enhancing oral bioavailability of tizanidine hydrochloride. Graphical abstract.

Development and Stability Control of Pediatric Oral Tizanidine Hydrochloride Formulations for Hospital Use.

Tizanidine hydrochloride is a centrally acting skeletal muscle relaxant used in the treatment of spasticity. This drug is sold only as tablets or capsules, which highlights the need to develop oral liquid formulations that allow administration to children and adults with impaired swallowing. This study aim was to develop and improve tizanidine hydrochloride liquid formulations from raw material and to evaluate their stability. A stability-indicating high performance liquid chromatography method was validated for two formulations developed. Fifteen formulations were developed containing syrup and fifteen containing sodium carboxymethyl cellulose as vehicles, to select the two most suitable for stability testing. The formulations were prepared in triplicate and placed in amber polyethylene terephthalate and glass bottles, which were stored under three different conditions: at room temperature (15-30°C), under refrigeration (2-8°C), and at 40°C. The physicochemical and microbiological stability of formulations were evaluated, applying high performance liquid chromatography and microbiological count. The studied formulations at 15-30°C, 2-8°C, and 40°C can be used for a period of 70 days, and all parameters are inside of recommended specifications, enough to allow its use in the context for which it was developed, the application in hospital. The formulations developed in this work have simple components to avoid adverse reactions in vulnerable populations. Results of this study could be applied as a reference for hospital use; once it demonstrated the reliability of storage time interval and proper conditions for use.

Formulation design, characterization and in vitro drug release study of orodispersible film comprising BCS class II drugs.

Fast dissolving orodispersible film (ODF) was prepared for concurrent administration of biopharmaceutical classification system (BCS) class II drugs, i.e., meloxicam (MX) and tizanidine (TZ), using natural (xanthan gum), semisynthetic (hydroxypropyl methylcellulose and hydroxyethyl cellulose) and synthetic (polyvinyl alcohol) polymers. Compatibility of the ingredients of ODFs was ascertained through Fourier transform infra-red spectroscopy and differential scanning calorimetry. ODFs were characterized through disintegration time, pH of the surface of film, tensile strength, folding endurance, % elongation and content uniformity (MX and TZ) which were found in the range between 17±1.3-56±3.1 s, 5.11±0.07-6.28±0.05, 14.721±1.2-33.084±3.1 N/m2, > 100, 3.33±0.53-10.04±0.77 % and 98.01-99.34 % (MX) and 97.48-99.03 % (TZ), respectively. The values of moisture uptake, moisture loss and loss on drying of all formulations were in the range from 1.06±0.09-7.51±0.93 %, 0.06±0.01-2.3±0.08 % and 0.008±0.002-0.03±0.03 %, respectively. In vitro drug release study in simulated saliva fluid of pH 7.4 has shown that > 90 % MX and TZ was released within 5 min. Visual inspection, scanning electron microscope and X-ray diffraction analysis of all ODFs expressed their smooth surfaces. ODF prepared from xanthan gum (F5) exhibited better physicochemical and mechanical properties as compared to other formulations.

Physicochemical stability of extemporaneously prepared clonidine solutions for use in neonatal abstinence syndrome.

WHAT IS KNOWN AND OBJECTIVE: Extemporaneously prepared clonidine admixture is increasingly used for the management of neonatal abstinence syndrome. However, its stability beyond 15 minutes at room temperature is currently unknown. Therefore, healthcare professionals must prepare clonidine admixtures multiple times a day while the treatment is indicated, resulting in subsequent limitations and problems. The aim of this study was to investigate the physicochemical stability of clonidine in commonly used pharmaceutical diluents at clinically relevant concentrations and temperatures. METHODS: Glass bottles (n = 18) and plastic syringes (n = 18) containing 0.5 and 5 µg/mL of clonidine in either 5% glucose, 10% glucose or 0.9% normal saline were prepared and stored at 4°C for 7 days and at 35°C for 24 hours, respectively. Aliquots were withdrawn at predefined time points and analysed for the concentration of clonidine, changes in pH and colour, and particle content. RESULTS AND DISCUSSION: No evidence of particle formation, or colour or pH change was observed throughout the study period. Clonidine retained more than 98% of its initial concentration when stored in the tested diluents at 4°C for 7 days and at 35°C for 24 hours. WHAT IS NEW AND CONCLUSION: Our findings will allow healthcare professionals to prepare weekly dose of clonidine in glass bottles for storage in a refrigerator. The daily required dose of clonidine can be drawn aseptically from the glass bottle each day and stored in a plastic syringe at room temperature. Clonidine present in a plastic syringe can be administered via the nasogastric route 4-6 times a day. This practice would not only save nursing time and avoid delays in the timely administration of clonidine, but also reduce the risk of potential medication errors as well as preparation-associated costs.

Validation of a HPLC/MS method for simultaneous quantification of clonidine, morphine and its metabolites in human plasma.

A high-performance liquid chromatography-tandem mass spectrometry method was developed and validated for the simultaneous quantification of morphine, morphine's major metabolites morphine-3-glucuronide and morphine-6-glucuronide, and clonidine, to support the pharmacokinetic analysis of an ongoing double-blinded randomized clinical trial that compares the use of morphine and clonidine in infants diagnosed with neonatal abstinence syndrome. Plasma samples were processed by solid-phase extraction and separated on an Inertsil ODS-3 (4 µm) column using an 0.1% formic acid in water-0.1% formic acid in methanol gradient. Detection of the analytes was conducted in the positive multiple reaction monitoring mode. The range of quantitation was 1-1000 ng/mL for morphine, morphine-3-glucuronide and morphine-6-glucuronide, and 0.25-100 ng/mL for clonidine. Intra-day and inter-day accuracy and precision were ≤15% for all analytes across the quantitation range. Extraction recovery rates were ≥94% for morphine, ≥90% for M3G, ≥87% for M6G and ≥ 79% for clonidine. Matrix effect ranged from 85-94% for clonidine to 101-106% for M3G. The method fulfilled all predetermined acceptance criteria and required only 100 µL of starting plasma volume. Furthermore, it was successfully applied to 30 clinical trial plasma samples.

Physicochemical and microbiological stability of two news oral liquid formulations of clonidine hydrochloride for pediatric patients.

Pediatric patients present changing physiological features. Because of the lack of land suitable for commercial management, pediatric specialties very often need to prepare extemporaneous formulations to improve the dosage and administration of drugs for children. Oral liquid formulations are the most suitable for pediatric patients. Clonidine is widely used in the pediatric population for opioid withdrawal, hypertensive crisis, attention deficit disorders and hyperactivity syndrome, and as an analgesic in neuropathic cancer pain. The objective was to study the physicochemical and microbiological stability and determine the shelf life of an oral solution containing 20 µg/mL clonidine hydrochloride in different storage conditions (5 ± 3 °C, 25 ± 3 °C, and 40 ± 2 °C). Using raw material with excipients safe for all pediatric age groups, two oral liquid formulations of clonidine hydrochloride were designed (with and without preservatives). Solutions stored at 5 ± 3 °C (with and without preservatives) were physically and microbiologically stable for at least 90 days in closed containers and for 42 days after opening. Two oral solutions of clonidine hydrochloride 20 µg/mL were developed for pediatric use from raw materials that are readily available and easy to process, containing safe excipients that are stable over a long period of time.

Toward Higher Sensitivity in Quantitative MALDI Imaging Mass Spectrometry of CNS Drugs Using a Nonpolar Matrix.

Tissue-specific ion suppression is an unavoidable matrix effect in MALDI mass spectrometry imaging (MALDI-MSI), the negative impact of which on precision and accuracy in quantitative MALDI-MSI can be reduced to some extent by applying isotope internal standards for normalization and matrix-matched calibration routines. The detection sensitivity still suffers, however, often resulting in significant loss of signal for the investigated analytes. An MSI application considerably affected by this phenomenon is the quantitative spatial analysis of central nervous system (CNS) drugs. Most of these drugs are low molecular weight, lipophilic compounds, which exhibit inefficient desorption and ionization during MALDI using conventional polar acidic matrices (CHCA, DHB). Here, we present the application of the (2-[(2 E)-3-(4- tert-butylphenyl)-2-methylprop-2-enylidene]malononitrile) matrix for high sensitivity imaging of CNS drugs in mouse brain sections. Since DCTB is usually described as an electron-transfer matrix, we provide a rationale (i.e., computational calculations of gas-phase proton affinity and ionization energy) for an additional proton-transfer ionization mechanism with this matrix. Furthermore, we compare the extent of signal suppression for five different CNS drugs when employing DCTB versus CHCA matrices. The results showed that the signal suppression was not only several times lower with DCTB than with CHCA but also depended on the specific tissue investigated. Finally, we present the application of DCTB and ultrahigh resolution Fourier transform ion cyclotron resonance mass spectrometry to quantitative MALDI imaging of the anesthetic drug xylazine in mouse brain sections based on a linear matrix-matched calibration curve. DCTB afforded up to 100-fold signal intensity improvement over CHCA when comparing representative single MSI pixels and >440-fold improvement for the averaged mass spectrum of the adjacent tissue sections.

Stability study of a clonidine oral solution in a novel vehicle designed for pediatric patients.

Clonidine hydrochloride is administered to opioid-addicted mothers' neonates to reduce neonatal abstinence syndrome. It is prescribed off-label to neonates at 0.5-1 µg/kg/6 h, alone or in combination. The commercially injectable form of clonidine-Catapressan® 0.15 mg/mL-is being orally given after an appropriate dilution in water. However, this practice is not suitable for a perfectly safe and accurate administration. The objectives were to design a 10 µg/mL oral solution of clonidine hydrochloride in Inorpha® and to study the stability of this solution by a validated stability-indicating liquid chromatography (LC) method. The chemical, physicochemical and microbiological stability of the compounded formulation stored at 5 ± 3 °C and 25 ± 2 °C was tested over 60 days. The LC method used is specific, linear, accurate and precise. Upon storage between 2 and 8 °C according to classical and 'in use' schedules, the concentrations of clonidine and potassium sorbate (preservative) were found to be between 90.0 and 110.0% of the initial concentration, the pH between 4.4 and 4.7 and no microbial growth was noted. The stability of clonidine hydrochloride oral solution in Inorpha® sets the basis for individualized, easy and safe administration of clonidine in pediatric populations.

Molecular structure of clonidine: gas-phase electron diffraction, single-crystal X-ray diffraction and quantum chemical studies.

This study presents the first determination of the molecular structure of the antihypertensive drug clonidine in the gas phase using gas electron diffraction (GED). The refinement was supported by quantum chemical calculations (QCs). The tautomeric and conformational distribution was investigated theoretically, providing an explanation for the presence of the single conformer in the gas phase. The molecular conformation of clonidine has been shown to have a nearly perpendicular arrangement of the phenyl and imidazolidine rings as described by the torsion angle C2-N6-C7-C8 = -72(6)°. The following structural parameters were obtained (bond lengths in Angstroms and bond angles in degrees with 3σ in parentheses): r(CHH-CHH) = 1.549(7), r(CHH-NH)av = 1.470(7), r(NH-C)av = 1.388(2), r(C[double bond, length as m-dash]N) = 1.286(7), r(C-N) = 1.388(2), r(C[partial double bond, bottom dashed]C)av = 1.403(2), r(C-Cl)av = 1.737(2); ∠(NH-C-NH) = 108.1(11), ∠(CHH-NH-C)av = 109.7(12), ∠(CHH-CHH-NH)av = 100.9(12), ∠(C-N[double bond, length as m-dash]C) = 122.5(12), ∠(CCl[partial double bond, bottom dashed]C[partial double bond, bottom dashed]CCl) = 114.9(2), and ∠(CH[partial double bond, bottom dashed]CCl[partial double bond, bottom dashed]C)av = 123.1(2). The standard enthalpy of formation of clonidine in the gas phase was calculated using G4 theory with both atomisation and isodesmic reaction approaches, yielding the corresponding value of . The molecular structure of clonidine in the solid phase was determined using X-ray diffraction (XRD). Clonidine crystallizes in the monoclinic space group P21/c as a twinned crystal. The imino-tautomer, as an equimolar mixture of the two conformers with geometries close to the enantiomeric pair, is present in the solid phase. The identical conformers are linked into centrosymmetric dimers by paired N-HN hydrogen bonds. The geometries of gaseous and solid clonidine differ especially in the immediate vicinity of the intermolecular hydrogen bonds formed in the crystal.

Mini-tablet combination for sustained release of clonidine hydrochloride and hydrochlorothiazide: Preparation and pharmacokinetics in beagle dogs.

Mini-tablets are increasingly gaining attention in solid dosage form design as multiple-unit systems combining different active compounds and providing a single or combined pattern of modified release for polypharmacy or combined treatments. A combination therapy of clonidine hydrochloride and hydrochlorothiazide achieves effective blood pressure control and reduction in adverse effects. However, the combination formulation of immediate release must be taken several times a day, which causes noticeable fluctuation of blood pressure and inconveniences to the patients. The present study was performed to develop a mini-tablet combination for sustained release of clonidine hydrochloride and hydrochlorothiazide independently, in which the two drugs and fraction doses were formulated into separate mini-tablets with different release patterns. The mini-tablets were prepared by a direct compression method followed by filling into capsules and the factors that affected drug release were addressed. Further, studies of the pharmacokinetics were performed in beagle dogs. Finally, in vivo-in vitro correlations of the sustained release systems and bioequivalence with conventional preparations were evaluated. The mini-tablet combination released the two drugs over 24h in vivo with a steady plasma concentration, a markedly lower Cmax, extended Tmax and better bioavailability. In conclusion, sustained releases of the two drugs were obtained with this mini-tablet combination, which offers a feasible formulation and promising development value for hypertensive patients who need long-term therapy.

Multimodal perineural analgesia with combined bupivacaine-clonidine-buprenorphine-dexamethasone: safe in vivo and chemically compatible in solution.

OBJECTIVES: The use of adjuvants in regional anesthesia has increased. However, there are knowledge gaps pertaining to 1) in vivo local tissue effects of these adjuvants; and 2) chemical compatibility and solubility of these drugs in solution with each other and with local anesthetics. This study addresses these gaps in knowledge. DESIGN: In vivo rat safety/toxicopathology study and analytical chemistry study. SETTING: Collaborating Good Laboratory Practice laboratories under the direction of the university-based principal investigator. METHODS: Single-injection formulations of clonidine, buprenorphine, and dexamethasone were combined with either bupivacaine or midazolam, and were administered to groups of rats. Post-injection behavior was monitored to assess changes related to the block. A continuous infusion of bupivacaine, clonidine, and dexamethasone was administered to another group of rats, and behavioral effects were recorded. After 15 days, rats were sacrificed and their nerves/dorsal root ganglia were examined by the pathologist. Samples of combined drug solutions were processed at an analytical chemistry laboratory for compatibility, solubility, and stability. RESULTS: Each of the single-injection formulations produced reversible sensory and/or motor block. None of the study drugs caused damage to any of the nerve segments or related tissue. The text describes the concentrations at which compatibility and solubility of the combined drug solutions were achieved. CONCLUSIONS: Four-drug single-injection formulations are described that 1) had compatible and stable concentrations in solution; and 2) produced reversible nerve block without causing long-term motor or sensory deficits or damage to sciatic nerves/dorsal root ganglia.

Effects of various excipients on tizanidine hydrochloride tablets prepared by direct compression.

This study was conducted to assess the effects of various excipients in 10 different Tizanidine hydrochloride tablet dosage forms that were prepared by direct compression method (DC). Various excipients are available for DC method; we selected those excipients that are used commonly in tablet manufacturing. The excipients used included lactose anhydrous, di-basic calcium phosphate anhydrous, starch, talc, sodium carboxy methyl cellulose, polyvinyl pyrrolidone (PVP), silicon dioxide (Aerosil), stearic acid, magnesium stearate and microcrystalline cellulose (Avicel). These tablets were then evaluated by performing different pharmacopoeial and non-pharmacopoeial tests (i.e. diameter, hardness, thickness, weight variation, disintegration and assay). It was observed that Formulations B, D and H of Tizanidine hydrochloride gave best results within USP specified limits for the tests employed among all the formulations whereas Formulations F and G showed poor friability, disintegration and dissolution profiles rendering starch in combination of talc and sodium carboxy-methyl cellulose unsuitable for Tizanidine hydrochloride tablet formulations. With the present approach, more studies can be designed using other active ingredients and excipients to get an optimal and cost effective product.

Physicochemical and Microbiological Stability of Compounded Clonidine Hydrochloride Oral Liquid Dosage Forms in PCCA Base, SuspendIt®.

Clonidine Hydrochloride is a centrally acting alpha-agonist hypotensive agent available as tablets for oral administration in three dosage strengths: 0.1 mg, 0.2 mg and 0.3 mg. A review of the therapeutic uses of clonidine hydrochloride reveals the need for flexibility in dosing. This flexibility is readily achieved using an oral liquid dosage form. However, no commercial liquid dosage form of clonidine hydrochloride currently exists. An extemporaneously compounded suspension from pure drug powder would provide a flexible, customizable option to meet unique patient needs with convenient and accurate dosing options. The purpose of this study was to determine the physicochemical and microbiological stability of extemporaneously compounded clonidine hydrochloride suspensions in the PCCA Base, SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. The study design included two clonidine hydrochloride concentrations to provide stability documentation over a bracketed concentration range for eventual use by compounding pharmacists. A robust stability-indicating high-performance liquid chromatographic assay for the determination of the chemical stability of clonidine hydrochloride in PCCA SuspendIt was developed and validated. Suspensions of clonidine hydrochloride were prepared in PCCA SuspendIt at 20-mcg/mL and 100-mcg/mL concentrations, selected to represent a range within which the drug is commonly dosed. Given the potent nature of the drug, a 2% triturate of clonidine hydrochloride in microcrystalline cellulose was used to prepare the samples. Samples were stored in amber plastic prescription bottles at two temperature conditions (5°C and 25°C). Samples were assayed initially, and on the following time points (days): 7, 14, 28, 42, 63, 91, 119 and 182. Physical data such as pH, viscosity and appearance were also noted. Microbiological stability was tested. All measurements were obtained in triplicate. A stable extemporaneous product is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period and is protected against microbial growth. Using this criterion, no significant degradation of the clonidine hydrochloride was observed over the 182-day test period for either concentration under refrigerated conditions. Drug concentrations were at, or above 94.6% of initial values. However, at room temperature the concentration of the 20-mcg/mL samples dropped below 90% after 119 days. No microbial growth was observed. pH values remained fairly constant. The viscosity of the suspensions allowed easy re-dispersal of the drug particles upon shaking. This study demonstrates that clonidine hydrochloride is physically, chemically, and microbiologically stable in PCCA SuspendIt for 182 days in the refrigerator and for 119 days at room temperature at both concentrations studied, thus providing a viable, compounded alternative for clonidine hydrochloride in a liquid dosage form, with an extended BUD to meet patient needs.

New sustained-release intraarticular gel formulations based on monolein for local treatment of arthritic diseases.

Inflammatory osteoarthritis (OA) is characterized by painful and destructive inflammatory flares of a single joint, mainly in the back, the knees, the wrists or the hips. Monoarthritis is generally treated by intraarticular (IA) injections of corticosteroids or hyaluronic acid (HA). However, due to their toxicity, the chronic use of corticosteroids should be avoided. The aim of this work was to develop a new slow-release formulation for a parenteral route of administration (e.g., IA). The development's strategy was based on the use of amphiphilic ingredients such as glyceryl monooleate (GMO), which is able to generate viscous crystalline phase structures upon contact with an aqueous fluid (e.g., synovial fluid) to sustain the drug activity over weeks. Clonidine (CLO) was suggested as a small and hydrophilic model drug and HA as a hydrophilic viscoelastic scaffold. Thermal analyses showed that the stability of GMO, HA, and CLO in mixtures with a ratio of 1:1 (wt/wt) was not affected in comparison with the raw materials. In order to obtain a formulation presenting suitable syringeability and containing GMO, CLO, and HA, two elements were found to be essential: a minimum of about 15% (wt/wt) water content and the use of co-solvents such as ethanol (ET) and propylene glycol (PG), approved by the FDA for parenteral use. Several developed gels presented pseudoplastic flow behavior. Moreover, the best composition provided an in vitro release of CLO for about 1 week that was similar to a cubic reference formulation, described by many authors as presenting poor syringeability but the best sustained-release capacity.

Tizanidine and tizanidine hydrochloride: on the correct tautomeric form of tizanidine.

A crystallization series of tizanidine hydrochloride, used as a muscle relaxant for spasticity acting centrally as an α(2)-adrenergic agonist, yielded single crystals of the free base and the hydrochloride salt. The crystal structures of tizanidine [systematic name: 5-chloro-N-(imidazolidin-2-ylidene)-2,1,3-benzothiadiazol-4-amine], C(9)H(8)ClN(5)S, (I), and tizanidine hydrochloride {systematic name: 2-[(5-chloro-2,1,3-benzothiadiazol-4-yl)amino]imidazolidinium chloride}, C(9)H(9)ClN(5)S(+)·Cl(-), (II), have been determined. Tizanidine crystallizes with two almost identical molecules in the asymmetric unit (r.m.s. deviation = 0.179 Å for all non-H atoms). The molecules are connected by N-H···N hydrogen bonds forming chains running along [2 ̅11]. The present structure determination corrects the structure determination of tizanidine by John et al. [Acta Cryst. (2011), E67, o838-o839], which shows an incorrect tautomeric form. Tizanidine does not crystallize as the usually drawn 2-amino-imidazoline tautomer, but as the 2-imino-imidazolidine tautomer. This tautomer is present in solution as well, as shown by (1)H NMR analysis. In tizanidine hydrochloride, cations and anions are connected by N-H···Cl hydrogen bonds to form layers parallel to (100).

Stability evaluation of compounded clonidine hydrochloride oral liquids based on a solid-phase extraction HPLC-UV method.

The present study aimed to assess the stability of clonidine hydrochloride oral liquids (20-µg/mL) prepared from two different generic tablets in Ora-Blend and stored in amber plastic bottles. Physical and chemical stabilities were evaluated over a period of 90 days at 25°C. Analytical challenges were overcome with the development of a new extraction procedure based on solid phase extraction to ensure efficient clonidine hydrochloride quantification. The absence of physical instabilities, evaluated by qualitative and quantitative measurements (static multiple light scattering), as well as the absence of chemical instabilities, evidenced by a stability-indicating HPLC-UV method, confirmed that a beyond-use date of 90 days was appropriate for these compounded oral liquids.

Dissociation of water on the surface of organic salts studied by X-ray photoelectron spectroscopy.

Water dissociation has important implications for numerous chemical processes. Although extensively studied on metals and to some extent on inorganic salts, this phenomenon has not yet been shown to occur on organic surfaces. Herein, the ability of two crystalline organic hydrochloride salts to induce water dissociation at their surface was demonstrated. Using a modified X-ray photoelectron spectroscopy setup, the oxygen lacking crystalline organic salts were exposed to high water vapor pressures within an environment sealed from ambient air. Thus, the O(1s) peak resulting from exposure to water vapor at room temperature could be unambiguously assigned to dissociated water, a phenomenon previously unreported with organic material. Both powder and single crystal samples were investigated, to determine the effect of defects on the extent of dissociation. Dissociation was shown to be dependent on the level of defects present at the surface. The presence of highly reactive dissociated water on organic surfaces has important implications for the solid state chemical stability of these substances.

Formulation of two-drug controlled release non-biodegradable microparticles for potential treatment of muscles pain and spasm and their simultaneous spectrophotometeric estimation.

The objective of this study was to formulate stable and controlled release microparticles for simultaneous delivery and UV spectrophotometric detection in combined dosage of an non-steroidal anti-inflammatory drug (NSAID) (nimesulide, NMS) and a spasmolytic agent (tizanidine, TZN) to maintain plasma concentration that may increase patients compliance, improved therapeutic efficacy, The aim was also to reduce severity of upper GI side effects of NMS because of alteration in delivery pattern via slow release of drug from microparticles and to increase the benefits of spasticity and disability for spastic patients by administering TZN in a modified release formulation as these two drugs are often prescribed in combination for the management of pain associated with muscles spasm. Ethyl cellulose was used as a retardant polymer. Drug-polymer and drug-drug compatibility study were conducted by different analytical tests. Microparticles were prepared by coacervation thermal change method. The prepared microparticles were characterized for their micromeritics and drug loading. The prepared microparticles were light yellow, free flowing and spherical in shape. The drug-loaded microparticles showed 87% and 91% entrapment efficiency of NMS and TZN, respectively, and release was extended up to 10 h. The infrared spectra, differential scanning calorimetry thermograms and XRD spectra showed the stable character of both the drugs in the drug-loaded microparticles. The in vitro release study of microparticles was performed in phosphate buffer pH 6.8. Linearity was observed in the concentration range of 5.0-30.0 microg/mL of NMS and 0.5-3.0 microg/mL of TZN. The microparticles have a potential for the prolongation and simultaneous delivery of the NIM and TIZ. The proposed UV method for simultaneous detection can be used for routine analysis of combined dosage form.