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Semi-Automation in Inhaler Testing - Exploring the Potential & Practicalities
Citation: Pereira J, Borda D鈥櫭乬ua R, Copley M, Sipitanou A, 鈥淪emi-Automation in Inhaler Testing 鈥 Exploring the Potential & Practicalities鈥.
翱狈诲谤耻驳顿别濒颈惫别谤测,听, pp 53鈥57.
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INTRODUCTION
The automation of discrete steps of cascade impactor analysis offers opportunities to address variability in inhaler testing, while simultaneously reducing health and safety concerns and improving analyst productivity. The ability of cascade impaction to generate drug-specific aerodynamic particle size distribution data (APSD) for orally inhaled products (OIPs) is central to its utility, but necessitates systematic drug recovery from each stage of the impactor, and from the surfaces of other accessory components that complete the test set-up. This laborious task accounts for much of the manual effort associated with cascade impaction measurements and is a primary focus for automation. The rewards can be significant; however, such changes raise questions of equivalence to manual methods, which must be robustly answered prior to the adoption of automated methodologies.
鈥淎 back-to-back comparative study of manual and automated drug recovery carried out by 四色AV 鈥 demonstrates statistical equivalence between the methods and highlights a reduction in analyst bench time of about 40%.鈥
In this article, we consider the semi-automation of cascade impactor testing focusing on those tasks, notably aspects of drug recovery that are easily tackled using off-the-shelf solutions. A back-to-back comparative study of manual and automated drug recovery carried out by 四色AV, a leading contract development and manufacturing organisation, demonstrates statistical equivalence between the methods and highlights a reduction in analyst bench time of about 40%.
THE CASCADE IMPACTION WORKFLOW
A cascade impactor is a precision instrument that fractionates a sample on the basis of particle inertia, which is a function of particle size and velocity. The workflow associated with producing drug-specific aerodynamic particle size distribution (APSD) data for an OIP can therefore be split into two discrete elements: size fractionation of the dose (by the impactor) followed by drug recovery and quantitation, to determine the drug deposition profile.
The cascade impactor test set-up for any specific application is defined with reference to the device under test and the purpose of analysis, for example, whether the aim is to generate more clinically realistic data for research and product development, or to confirm batch-to-batch consistency for product release. A detailed discussion of cascade impactor test set-up and the issues associated with method development lies beyond the scope of this article, but is well covered by Bonam听et al听(2008).1
Once a test set-up has been established, routine analysis is initiated by actuating the device to release a dose into the impactor. A vacuum pump draws the sample-laden air through the stages of the impactor at a constant, defined volumetric flow rate, causing the deposition of particles above a certain cut-off diameter on the collection surface of each stage; each subsequent stage captures progressively smaller particles. Multiple actuations are frequently required to ensure a quantifiable amount of drug on each collection surface and to guarantee method repeatability.
At the end of this first part of the analysis, multiple doses of the drug product are distributed, depending on the exact test set-up, across: the mouthpiece adaptor (MA), the induction port (IP) 鈥 the interface between the device and the impactor 鈥 the pre-separator (PS) when used, each stage of the impactor, and the micro-orifice collector (MOC) or final filter.
鈥淭he product-specific nature of cascade impactor test set-ups and the complexity of the measurement process directly influence the feasibility of end-to-end automation, which is rarely, if ever, cost effective. Conversely, automating specific steps with off-the-shelf solutions can be highly beneficial.鈥
Completion of the analysis involves the rigorous recovery of samples from each of these surfaces. This involves wetting and rinsing each surface to dissolve the deposited sample with a suitable solvent and produce solutions of an adequate concentration for assay, typically via liquid chromatography (LC). The resulting data are converted into APSD metrics specifically for the API, typically using dedicated software.
The product-specific nature of cascade impactor test set-ups and the complexity of the measurement process directly influence the feasibility of end-to-end automation, which is rarely, if ever, cost effective. Conversely, automating specific steps with off-the-shelf solutions can be highly beneficial. The cost of such solutions is far more accessible than a bespoke automation project and they can deliver significant improvements in day-to-day practice, reducing analyst fatigue and stress, and the risk of repetitive strain injury (RSI) by eliminating time-consuming repetitive tasks. Critically, automation can improve data quality, accuracy and integrity by eliminating the effect of operator-to-operator variability and handling errors.
For many organisations, the number of samples lost due to simple but impactful handling errors is significant and results in, at best, repeat analyses and, at worst, a costly, time-consuming investigation. For example, automated shake-and-fire systems ensure highly repeatable device actuation in metered dose inhaler (MDI) testing by applying a consistent, well-defined device use regime (between actuations), shaking protocol and actuation force profile. This can help to significantly reduce variability in the delivered dose and, by extension, the whole measurement.2听More generally, for all OIPs it is the process of drug recovery that is most amenable to automation, with off-the-shelf solutions ranging from simple rinsing devices through to sophisticated systems for complete automation.
FOCUSING ON DRUG RECOVERY
Developing a robust, optimised method for drug recovery involves the careful consideration of issues such as:
- Which solvent is most appropriate 鈥 while highly volatile solvents may be essential to achieve complete dissolution, solvent evaporation can compromise pipetting and the delivery of accurate solvent volumes. Furthermore, volatility enhances the risk of sample concentration due to solvent loss during storage or the drug recovery process.
- How much solvent should be used 鈥 high solvent volumes ease complete drug dissolution by improving sink conditions, but simultaneously reduce drug concentration, potentially compromising the accuracy of the assay. Wide variation in the amount of drug that deposits on any given stage of the impactor can make it difficult to ensure complete dissolution of the drug at high loadings while simultaneously ensuring that the sample has a concentration above the limit of detection (LOD)/limit of quantification (LOQ) for stages on which drug deposition is minimal. This issue can be especially challenging for products with more than one active ingredient. There is also a positive environmental impact in lowering solvent content for extraction purposes.
- The best method to promote rapid and effective drug dissolution 鈥 to ensure complete dissolution, the drug and solvent must be in contact for an adequate length of time. Agitation accelerates dissolution and helps to ensure complete surface wetting; the application of ultrasonics is an option for less easily dissolved actives.
- What equipment to use to minimise sample degradation 鈥 any container in which recovered drug solutions are going to be held, including vials used for analysis, requires careful consideration to avoid, for example, sample loss to vial walls, absorption of the active from the solution and/or solvent evaporation.
A validated drug recovery method may be entirely manual but, where this is the case, analysis will necessarily involve a number of repetitive activities that are either significantly prone to error or physically arduous, or indeed both. Prime examples include pipetting and agitation of a specific test component with a defined aliquot of solvent. With these tasks, even simple devices, such as automated pipettes or rocking/rinsing devices, can make a major difference. For example, the Sample Preparation Unit Model SPU 2000 automates internal rinsing of the USP/PhEur induction port and the Next Generation Impactor (NGI) pre-separator, delivering consistent wetting of the internal surfaces and reproducible dissolution via the application of a defined agitation pattern for a set period of time.
Semi-automation with simple devices of this type is typically low cost and low risk, and the economic payback can be attractive, with analysts freed for higher value activities. On the other hand, more sophisticated off-the-shelf solutions, such as the NGI Assistant, can prove an even more beneficial investment over the long term. Systems which automate multiple steps of the drug recovery process may be associated with higher capital expenditure but can deliver more substantial gains by simultaneously addressing multiple sources of measurement variability. The NGI Assistant automates drug recovery from the point of solvent dispensation and drug dissolution through to the presentation of sample solutions in industry-standard vials, ready for liquid chromatography (LC) analysis, thereby eliminating any requirement for manual pipetting, agitation or LC sample preparation.
In the following study, predominantly manual analysis was compared with more fully automated analysis using this system to demonstrate a) the time savings are accessible and b) whether the data generated are strictly equivalent.
CASE STUDY: COMPARING MANUAL AND SEMI-AUTOMATED DRUG RECOVERY FOR CASCADE IMPACTOR TESTING OF A DPI
APSD data for a TwinCaps庐听single-use dry powder inhaler (DPI) were generated using two different methods for drug recovery (Figure 1): an essentially manual recovery method aided by an automated solution for agitation of the solvent in the NGI collection cup tray (NGI Gentle Rocker) and a fully automated recovery with an NGI Assistant. Testing was carried out using an in-house method developed in accordance with the relevant general chapter of the PhEur.3听An NGI with USP/PhEur induction port and pre-separator was used with a test flow rate of 38 L/min, determined on the basis of a 4 kPa pressure drop across the device. A mixed solvent was used for drug recovery (details not specified) and the resulting solutions were quantified using an HPLC system (MA, US). HPLC was carried out using a silica-based column with a mixed aqueous and organic mobile phase (flow rate 0.8 mL/min) and an injection volume of 100 渭L.
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