Filtro de Aplicações

Raman spectroscopy is used for material characterization by analyzing molecular or crystal symmetrical vibrations and rotations that are excited by a laser, and exhibit vibrations specific to the molecular bonds and crystal arrangements in the molecules. Raman technology is a valuable tool in distinguishing different polymorphs. Examples of portable Raman spectroscopy for identification of polymorphs and in monitoring the polymorphic transiton of citric acid and its hydrated form are presented.

The NanoRam is able to test material through multiple layers of transparent plastic bags. Postive identification of material on PE bags from 1 to 9 layers were obtained, demonstrating minimum interference from the PE bags on the material identification result.

The emergence of counterfeit prescription drugs has become a concern for the pharmaceutical industry. Because of the low concentrations of APIs found in pharmaceutical drugs, normal Raman spectroscopy is typically not sensitive enough to detect the API from the surface of a pill. In this study we develop a surface-enhanced Raman spectroscopy (SERS)-based approach to identify a low-dose of the API alprazolam in a Xanax tablet using a handheld Raman spectrometer. If no SERS peaks consistent with alprazolam are observed from a Xanax tablet, the pill is a suspected fake. The method demonstrates the power of SERS to quickly verify the presence of alprazolam in the tablet for anti-counterfeiting purposes.

Metrohm’s ST Raman technology enables fast, contactless identification of substances through opaque packaging, expanding safe, field-ready use of Raman spectroscopy.

Analytical methods to perform CU testing should ideally be fast, noninvasive and achieved with limited sample preparation. Recently, transmission near-infrared (NIR) spectroscopy and transmission Raman spectroscopy have both been explored as alternative methods for rapid and non-destructive on- and at-line CU testing with no sample preparation. Although quick and nondestructive, transmission NIR spectroscopy suffers from poor chemical selectivity and is sensitive to changes in the testing environment. Transmission Raman spectroscopy combined with chemometric modeling is quickly emerging as a valued technique for CU testing due to its high chemical specificity, which is particularly useful when dealing with complex pharmaceutical formulations that contain multiple components.

This technical note is to demonstrate the NanoRam material identification through dark brown plastic bags. NanoRam is shown to work for material identification inside dark brown polyvinyl bag.

Handheld Raman is used for raw material testing of different sample types and forms. The use of optimized sampling accessories enhances the utility of handheld Raman without compromising data quality or complicating testing.

In this note, we use a model drug, acetaminophen, to demonstrate the capability of QTRam® to quantify low concentrations of API in compressed tablets. QTRam® is a compact transmission Raman analyzer designed specifically for content uniformity analysis of pharmaceuticals in solid dosage forms.

In this case study, a suspected counterfeit Adderall pill was measured directly with a TacticID Mobile using a point-and-shoot adapter. The spectra of the suspected couterfeit pill was found to contain cellulose and caffeine, but not the active ingredient. The TacticiD Mobile with 1064-nm laser excitation provides fluorescence suppression, giving those on the front lines a tool in the fight against dangerous counterfeit drugs.

Benzbromaron is one of the main uricosuric drugs currently used. In addition to sophisticated and expensive LC-MS and GC-MS methods, benzbromaron can be effectively determined by titration with sodium hydroxide solution using a straightforward, fully automated sample preparation method. A high-frequency homogenizer comminutes one or three tablets within 90 or 120 s respectively. The overall analysis time is 8 minutes. Ten-fold determinations with one and three tablets resulted in a benzbromaron content of 99.2 and 98.7 mg per tablet respectively. Increasing the number of tablets from one to three lowers the RSD from 1.36 to 0.88%. These results show an excellent agreement with the benzbromaron content indicated by the manufacturer (approx. 100 mg/tablet).Besides the presented Titrando/homogenizer combination, the other two members of the 815 Robotic Soliprep Sample Processor family offer comprehensive sample preparation possibilities within the fields of IC, HPLC, ICP or voltammetry.

Pharmaceutical analysis guarantees drug safety by providing information on the identity, content, quality, purity, and stability of pharmaceutical products using analytical chemistry. Ion chromatography (IC) offers a broad range of pharmacopeia-compliant applications for quality control, monitoring, and improving drug manufacturing. As a very accurate and versatile technique, IC meets the requirements of many pharmaceutical applications. IC is a USP-accepted standard method for the determination of active pharmaceutical ingredients (APIs), excipients, impurities, pharmaceutical solutions as well as pharmaceutical starting materials, finished pharmaceutical products (FPPs) and even body fluids. This poster describes some typical examples.

This poster presented jointly with USP at AAPS meeting shows the new USP method for zinc as per <591> using Ion Chromatography which is highly selective and sensitive. Selectivity is achieved by separation and further improved with PCR reaction. Sensitivity and wide linear quantification limit make the new USP method ideal for QA/QC. Automated PCR delivery makes the overall method performance easy to validate.

This poster presented jointly with USP at AAPS meeting shows, that we successfully validated an IC method to determine chloride and sulfate in drug substances, potassium bicarbonate and potassium carbonate. The proposed IC method overcomes limitations of the turbidimetry/visual comparison methods.

Diazepam belongs to the 1,4-benzodiazepine group of compounds, which are used for medical purposes as tranquilizers and antidepressants. This Bulletin describes the determination of diazepam in tablets and body fluids (blood, serum, urine) by means of differential pulse polarography. If a Britton-Robinson buffer pH = 2.8 with a methanol volume fraction of 20% is used as the supporting electrolyte then a pronounced reduction peak is obtained at -0.73 V; this allows diazepam concentrations even below 0.05 µg/mL to be determined in blood. The necessary sample preparation steps are also dealt with in this Bulletin.

Cinchocaine (dibucaine) is used in the form of ointments or injection solutions as a local anaesthetic. Its base is soluble in diethyl ether; its hydrochloride, on the other hand, is insoluble in diethyl ether but easily soluble in water. This Bulletin describes the determination of cinchocaine in ointments, creams and injection solutions by means of differential pulse polarography. An acetate buffer pH = 4.8 is used as the supporting electrolyte. The limit of quantitation and the linear working range of the method are given. The necessary sample preparation steps are also dealt with in this Bulletin.

The present Bulletin offers an overview of the multitude of surfactants and pharmaceuticals that can be determined with potentiometric titration. Metrohm provides five different surfactant electrodes for indicating the titration endpoint: the Ionic Surfactant, the High Sense, the Surfactrode Resistant, the Surfactrode Refill and the NIO Surfactant electrode. The manufacture of the respective titrants and their titer determination are described in detail. In addition to this, the Bulletin contains a tabular overview of more than 170 proven applications from the area of surfactant and pharmaceutical analysis. This guideline leads you reliably to your destination: At a glance you can see from the table which surfactant electrode and which titrant are optimally suitable for your product.

The present Application Bulletin contains NIR applications and feasibility studies using NIRSystems devices in the pharmaceutical industry. Qualitative and quantitative analyses of a wide variety of samples are part of this bulletin. Each application describes the instrument that was originally used for the analysis, as well as the system recommended for the analysis and the results that were achieved thereby.

This Application Bulletin compares the unique focusing technology of the portable Metrohm Raman system "Mira" with conventional methods. The method described here is called Orbital Raster Scan (ORS). Experiments show the advantages of ORS technology, using determination and quantification of medicines as an example. It improves the reproducibility of the Raman signals from targeted, active, pharmaceutical ingredients (APIs) in effervescent, cold medicines. Shorter analysis times and an improved, consistent assignment of spectra of the known medicine with the help of a spectral library are further advantages of ORS technology.

Determination of Bethanechol chloride and calcium in tablets using cation chromatography with direct conductivity detection.

Determination of Bethanechol Chloride and HPTA (2-hydroxy-propyl-trimethyl ammonium chloride) besides sodium and calcium using cation chromatography with direct conductivity detection.

Bethanechol is a pharmaceutical compound which is used to treat urinary retention. This API (active pharmaceutical ingredient) can be determined by cation chromatography with direct conductivity detection. A good separation is achieved between bethanechol and its degradation product 2-hydroxy-propyl-trimethyl ammonium (HPTA) and the standard cations. Peak shape and resolution meet the USP requirements for bethanechol.

Tris(hydroxymethyl)aminomethane (TRIS) is often used in life science applications and its purity must be monitored. This analysis is possible with ion chromatography.

Alendronate, also referred to as alendronic acid, is a biphosphonate used to treat osteoporosis. It is the main ingredient in the tablets and is determined in accordance with the Chinese Pharmacopoeia (2015). Separation takes place in the Metrosep A Supp 4 - 250/4.0 column; direct conductivity detection is used for quantification.

Two of the leading pain remedies, aspirin and acetaminophen, are compared with generic samples for content uniformity testing using near-infrared spectroscopy (NIRS). The method of standard addition is used for quantification. To reduce most of the effects that stem from particle size and packing differences, second derivative spectra are used.

This Application Note shows the potential of NIRS as a rapid (< 30 s) and nondestructive screening tool for solid dosage forms (e.g. tablets). NIRS requires neither sample preparation nor solvent use. Interferences that derive from scattering are minimized by converting to second derivative spectra.

Well-mixed active substances for medications are indispensable in the pharmaceutical industry. This applies not only to the pharmaceutical active ingredient but also for lubricants, binding agents, explosives, oxidants and dyes. Analysis of these active ingredients is expensive; they are also only rarely analyzed as a rule. The progress of the mixing procedures can be followed conveniently with NIR spectroscopy, on the one hand using visual comparisons and on the other by means of spectral algorithms. The progress of mixing processes can be predicted in real time with the help of the spectrum when the latter is used.

This Application Note shows that NIR "predictive models" are optimally suitable for the non-destructive measurement of the release profiles of active ingredients from tablets. This is in accordance with the Process Analytical Technology (PAT) initiative of the FDA. The results demonstrate how NIRS considerably reduces the work involved for release studies in the laboratory.

This Application Note shows that visible near-infrared spectroscopy (Vis-NIRS) can be used for the quantification of Baicalin content in herbal supplements. Vis-NIRS is a good alternative to the conventional lab method (HPLC) and can save both cost and time.

This Application Note presents Vis-NIR spectroscopy as a viable alternative to determine API content in cefixime tablets without sample preparation.

Traditionally, catecholamines are separated using reversed-phase chromatography followed by amperometric detection. This Application Note describes the determination of catecholamines in an emergency medication for life-threatening allergic reactions.

Producers of generic brands offer cosmetics, medicines and other goods in competition with name brands, often at a lower price point. This lower cost may reflect a lack of research, development, and advertising costs, but should never imply lower quality, especially in the case of over-the-counter drugs. As an example, Equate (a Walmart brand) effervescent cold tablets promise customers the same active ingredients in the same proportions and with identical effectiveness as Alka-Seltzer, at a much lower price. This Application Note demonstrates that Raman spectroscopy can successfully verify that these competing cold tablets are not identical. The process of ingredient verification involves a p- test, which measures the acceptable variability of a sample spectrum, as compared to a representative training set.

Raman spectrometers use tightly focused beams to produce high resolution spectra, but fail at analyzing heterogeneous substances because they cannot spatially target all components. ORSTM (Orbital Raster Scan) increases the interrogation area on a sample while maintaining high spectral resolution. Effervescent cold medicines, for example, contain many active ingredients in each heterogeneous tablet. Traditional identification and verification techniques require the collection of several spectra at different points on the tablet. Mira spectrometers equipped with ORS capture a large interrogation area in a very short time, analyzing all of the ingredients in a single scan.

Handheld Raman spectrometers are valued for their ability to provide onsite material identification in seconds. In the case of combination pharmaceuticals, a single tablet contains more than one active ingredient in different proportions. MIRA DS is uniquely capable of identifying multiple compounds in such tablets by using Raman to identify the major component and SERS (surface-enhanced Raman spectroscopy) for the minor component. This application describes quick, dual analysis of a prescription medication containing acetaminophen and hydrocodone. The application is easily extrapolated to the study of street drugs.

Undeclared drugs in dietary supplements pose serious health risks. Metrohm’s SERS solutions enable fast, sensitive, on-site detection of adulterants without matrix interference

Fluoride is commonly used in dental products to help prevent tooth decay. If the products are intended to prevent the formation of cavities (carries), then it is regulated by the US Food and Drug Administration (USFDA) as an Over-the-Counter (OTC) Drug. Previously, the assay of Fluoride in oral solution was done by Ion selective electrode and identification was done by tedious wet chemistry method. USP has updated this monograph for Assay and identification tests with Ion Chromatography using L46 packing. The Metrosep A Supp 1 - 250/4.6 column fulfills all USP acceptance criteria. It therefore is a viable alternative separation column for the determination of sodium fluoride in oral solutions.

Sodium fluoride gel for pharmaceutical use needs to comply with USP requirements. The actual monograph (USP 42) uses two different methods for the identification and the assay. Ion chromatography allows the analysis of these two parameters in one single determination. In the course of the USP monograph modernization, this ion chromatographic approach makes this type of analysis even easier.

Stannous fluoride gel for pharmaceutical use needs to comply with USP requirements. The actual monograph (USP 42) utilizes two different methods for the identification and the assay. Ion chromatography allows the analysis of these two parameters within a single determination. In the course of the USP monograph modernization, this ion chromatographic approach makes this type of analysis even easier.

Sodium fluoride and phosphoric acid gel for pharmaceutical use need to comply with USP requirements. The actual monograph (USP 42) uses two different methods for the identification and the assay. Ion chromatography allows the measurement of these two parameters within a single determination. In the course of the USP monograph modernization, this ion chromatographic approach makes this type of analysis even easier.

This Application Note demonstrates square wave voltammetry for sensitive, reproducible quantification of paracetamol using a screen-printed electrode and INTELLO.

Determination of ampicillin in raw and pure products through potentiometric titration with Hg(II) using the combined Au electrode. Keyword: Antibiotics

Determination of total penicillin content through potentiometric titration with Hg(II) using the combined Au electrode. Keyword: Antibiotics

Determination of lidocaine in ointments by potentiometric titration with sodium tetraphenylborate using the NIO surfactant electrode.

Determination of tranexamic acid in injection solutions by nonaqueous potentiometric titration with perchloric acid using a glass electrode.

Determination of benzydamine hydrochloride {1-benzyl-3-[3-(dimethylamino)-propoxy]-1H-indazole hydrochloride} in disinfectant solution by potentiometric titration with sodium tetraphenylborate using the NIO surfactant electrode.

Determination of phenylglycine through nonaqueous potentiometric titration with sodium methylate using a special combined glass electrode. Keyword: Antibiotics

Determination of the antihistamine astemizole in raw products by nonaqueous potentiometric titration with perchloric acid using separate electrodes.

This Application Note describes the photometric determination of bismuth nitrate using the Optrode (520 nm). The sample is titrated with EDTA solution past the endpoint; xylene-orange is used as the indicator. The method for bismuth nitrate fulfills the directives defined in the Ph. Eur. and the USP.

This Application Note looks at the photometric determination of manganese sulfate using the Optrode (610 nm). Manganese is titrated with EDTA; Eriochrome Black T is used as indicator. The method complies with Ph. Eur. and the USP.

This Application Note describes the photometric determination of zinc sulfate using the Optrode at a wavelength of 610 nm. Complexometric titration of zinc requires EDTA as titrant and Eriochrome Black T as indicator. The method fully complies with Ph. Eur. and USP.

This Application Note describes the nonaqueous acid-base titration of ketoconazole in accordance with the European Pharmacopoeia. The Solvotrode easyClean was used as the electrode.

Metformin is one the most commonly used drugs for diabetes type 2 belonging to the group of biguanides. This Application Note describes the determination of metformin hydrochloride assay according to USP using acetic anhydride as solvent.

Esta Nota de Aplicação detalha a determinação da capacidade de neutralização de ácido (ANC) em diversas amostras farmacêuticas em conformidade com os padrões USP<301>.

Sulfonamides are drugs used to treat allergies and cough. They also have some antifungal and antimalarial activities. USP<451> describes nitrite titration method for the determination of numerous pharmacopeial sulfonamide drugs and their dosage forms as well as of other pharmacopeial drugs with, for example, hydrazide (e.g., in isoniazid) and amine ester groups (e.g., in procaine) or amide derivatives of amino acids. Here, for illustrating the analysis of the latter, the assay of the diagnostic agent aminohippuric acid is described.

Determination of N-acetylcysteine and phenylalanine in tablets against sinusitis by anion chromatography with UV/VIS detection according to USP.

Determination of cefazolin in accordance with USP 28-NF 23 (Appendix 2) using RP chromatography and subsequent UV detection. Keyword: Antibiotics

Determination of cloxacillin sodium in accordance with USP 28-NF 23 (Appendix 2) using RP chromatography and subsequent UV detection. Keyword: Antibiotics

Determination of amoxicillin in accordance with USP 28-NF 23 (Appendix 2) using RP chromatography and subsequent UV detection. Keyword: Antibiotics

Determination of theophylline and theobromine according to USP 28-NF 23 (second supplement) using RP chromatography with UV detection.

Determination of valerophenone and ibuprofen according to USP 28-NF 23 (second supplement) using RP chromatography with UV detection.

Determination of ranitidine hydrochloride according to USP 28-NF 23 (second supplement) using RP chromatography with UV detection.

Determination of penicillin G potassium and 2-phenyl acetamide in accordance with USP 28-NF 23 (Appendix 2) using RP chromatography and subsequent UV detection. Keyword: Antibiotics

Determination of cefadroxil in accordance with USP 28-NF 23 (Supplement 2) using RP chromatography with UV detection. Keyword: Antibiotics

Paracetamol is an effective antipyretic and analgesic. Its determination in tablets using reverse phase chromatography and UV detection is quick and easy with the sample preparation described in this Note. The 815 Robotic Soli Prep for LC does everything automatically: from dissolving the tablets, homogenizing and filtering, to 250-nL-Loop injection.

Determination of clothiapine in a pharmaceutical standard.

Determination of artemisinin and artesunate in a standard.

The NanoRam handheld Raman, with a TE-cooled spectrometer, and patented CleanLaze technology packaged in a small, touch-screen operating unit, delivers high quality raw material testing capabilities for pharmaceutical manufacturers.

The NanoRam is a state-of-the-art, handheld Raman spectrometer for the rapid identification of chemicals used in the pharmaceutical manufacturing process. It has been specifically designed for these applications and is fully compliant with all the major global regulatory, safety, and commercial testing agencies applicable to the pharmaceutical industry.

Raman spectroscopy is a valuable tool to provide rapid, specific analysis for identification of raw materials, thus reducing the risk of using substandard or incorrect materials in manufacturing. The utility of handheld Raman increases productivity, and the ability to do full testing without creating bottlenecks in the production process. The integration of the Raman data into a company’s data management system provides a secure means of handling data and results, with reduced risk of transcription errors, and data loss.

Small, fast high-performance Raman spectrometers are now readily available. Three real-life Raman quantitative and semi-quantitative analysis applications are discussed. These applications showcase the versatility of Raman spectroscopy and the potential impact that it can make in various industries such as security, pharmaceutical, and plastics and polymers.

Content uniformity of solid dosage forms can be done nondestructively at the process line using the QTRam portable transmission Raman system.

The pharmaceutical industry is very likely more comprehensively regulated that any other branch of industry. It therefore requires analytic methods that meet the requirements of regulations while at the same time being practical. This applies in particular for large sample quantities, such as are encountered with incoming goods inspections, for example. It is here that particularly rapid and simple analysis methods are called for which make routine analyses simpler and more efficient. This White Paper describes some of the most important regulations in the pharmaceutical analysis and shows how Vis-NIR spectroscopy can solve analytic problems in the pharmaceutical industry in accordance with regulations.

Ion chromatography is a flexible technique with a large selection of intended uses in the pharmaceutical industry. – A few development trends and the latest advances are displayed here.

Chemometrics is a powerful tool widely used for method development in the pharmaceutical industry. This whitepaper describes the lifecycle of multivariate models and summarizes the workflow of the development of chemometrical models according to the new USP chapter <1039>.

A subestimação dos processos de controle de qualidade (CQ) é um dos principais fatores que levam a falhas internas e externas de produtos, que, segundo relatos, causam uma perda de faturamento entre 10–30%. Como resultado, muitas normas diferentes são implementadas para apoiar os fabricantes em seus processos de CQ. No entanto, o tempo para obter resultados e os custos associados aos produtos químicos podem ser excessivos, levando muitas empresas a implementar a espectroscopia de infravermelho próximo (NIRS) em seu processo de CQ. Este documento ilustra o potencial da NIRS e mostra os potenciais de economia de custos de até 90%.

This white paper summarizes the steps involved in converting an existing manual titration procedure to semi-automated or automated titration procedures. It discusses topics such as selecting the right electrode and titration mode. For a better understanding, the discussion topics are illustrated with three examples.

The objective of validation of an analytical procedure is to demonstrate that it is suitable for its intended purpose. Recommendations for the validation of analytical methods can be found in ICH Guidance Q2(R1) Validation of Analytical Procedures: Text and Methodology and in USP General Chapter <1225> Validation of Compendial Procedures. The goal of this white paper is to provide some recommendations for the validation of titration methods.