Low‐Cost Noninvasive Real‐Time Imaging for Tubular Continuous‐Flow Crystallization

Jiang, Mo; Braatz, Richard D.

doi:10.1002/ceat.201600276

Cited by 28 publications

(20 citation statements)

References 30 publications

(68 reference statements)

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“…Small glycine crystals (about 0.11 mm) generated under Condition 4 (the dark particles in Figure 8d) were circulated in the whole slug geometry. This behavior was consistent with the past observation that particles of a few hundred microns were able to circulate evenly inside the slurry slug of an aspect ratio of ~1 [9,58]. However, millimeter-sized glycine crystals performed differently in the slugs whose dimension was on the same length scale (e.g., the tubing ID was less than four-times larger than the average crystal size).…”

Section: Large Crystal Behavior Inside Slugssupporting

confidence: 91%

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Continuous Generation of Millimeter-Sized Glycine Crystals in Non-Seeded Millifluidic Slug Flow

Mou

Yang

et al. 2019

Crystals

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Millimeter-sized α-glycine crystals were generated from continuous non-seeded cooling crystallization in slug flow. The crystallization process is composed of three steps in sequence: slug formation, crash-cooling nucleation, and growth. Stable uniform slugs of three different aspect ratios (slug length/tubing inner diameter) were formed, by adjusting the flow rates of both the solution and air streams. Besides supersaturation, the slug aspect ratio can also affect primary nucleation outcome. Stable slug flow can accommodate a relative supersaturation (C/C*) of up to 1.5 without secondary nucleation. Large glycine crystals can grow to millimeter size within 10 min, inside millimeter-sized slugs without reducing the slug quality.

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Section: Large Crystal Behavior Inside Slugssupporting

confidence: 91%

“…The front is protruding more than the tail end[57]. Larger liquid flow rate and smaller air flow rate would reduce the length of the slurry slug[58]. Scale bar: 0.5 mm.…”

mentioning

confidence: 99%

Continuous Generation of Millimeter-Sized Glycine Crystals in Non-Seeded Millifluidic Slug Flow

Mou

Yang

et al. 2019

Crystals

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“…Jiang et al used an imaging method based on a stereomicroscope and a video camera for suspension quality evaluation [18]. Later, they refined this method as a real-time imaging method [20]. Due to the microscope placed in top view, however, the influence of gravity on the growing crystals was not taken into account.…”

Section: Introductionmentioning

confidence: 99%

Flow Map for Hydrodynamics and Suspension Behavior in a Continuous Archimedes Tube Crystallizer

et al. 2021

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The Archimedes Tube Crystallizer (ATC) is a small-scale coiled tubular crystallizer operated with air-segmented flow. As individual liquid segments are moved through the apparatus by rotation, the ATC operates as a pump. Thus, the ATC overcomes pressure drop limitations of other continuous crystallizers, allowing for longer residence times and crystal growth phases. Understanding continuous crystallizer phenomena is the basis for a well-designed crystallization process, especially for small-scale applications in the pharmaceutical and fine chemical industry. Hydrodynamics and suspension behavior, for example, affect agglomeration, breakage, attrition, and ultimately crystallizer blockage. In practice, however, it is time-consuming to investigate these phenomena experimentally for each new material system. In this contribution, a flow map is developed in five steps through a combination of experiments, CFD simulations, and dimensionless numbers. Accordingly, operating parameters can be specified depending on ATC design and material system used, where suspension behavior is suitable for high-quality crystalline products.

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“…The image analysis probe gave results similar to those of the FBRM measurements. Moreover, Jiang and Braatz described a low-cost system with effective monitoring and controlling ability for continuous crystallization processes. It was composed of a basic stereo microscope and video camera for imaging and characterization of l -asparagine monohydrate crystals in real time.…”

Section: Process Control Of Crystalline Pharmaceutical Productsmentioning

confidence: 99%

“…The authors claimed that each of the above three systems had been experimentally validated, and all were consistent with their polymorph selection design principle. However, because of the uncontrollability of the nucleation process, the existence of back-mixing in the MSMPR crystallizer and the nonideal 43 cyclosporin, 23,42 isothiocyanate, 44,45 prexasertib monolactate monohydrate, 46 L-alanine, 21 aliskiren hemifumarate, 47 carbamazepine, 48 D-/L-threonine, 49 albuterol, 50 azithromycin, 50 melitracen hydrochloride 51,52 continuous plug flow crystallizer benzoic acid, 26,53 acetaminophen, 54 triacylglycerol, 55−58 griseofulvin, 59 brivaracetam, 60,61 ketoconazole, 62 paracetamol, 63 acetylsalicylic acid, 64 flufenamic acid 62 continuous oscillatory baffled crystallizer L-glutamic acid, 28 biuret, 65 paracetamol, 66 melamine, 67 butyl paraben, 68 urea, 65 adipic acid, 69 α-lactose monohydrate, 70 salicylic acid, 71 aspirin 72 continuous segmented flow crystallizer L-asparagine monohydrate, 32,73,74 60 conducted a series of studies on brivaracetam in continuous-flow tubular crystallization, applying two crystallization strategies. With the cooling crystallization strategy, the extreme cooling condition of 20 °C/s was implemented, and high supersaturation was generated to obtain the desired crystal form.…”

Section: Polymorphism In Continuousmentioning

confidence: 99%

Recent Progress in Continuous Crystallization of Pharmaceutical Products: Precise Preparation and Control

Macaringue

et al. 2020

Org. Process Res. Dev.

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Crystallization, as a solid−liquid separation process, is employed to purify and isolate a great diversity of crystalline pharmaceutical products. In recent years, continuous crystallization has attracted increasing attention because of the product and process robustness as well as higher productivity. In this work, we review the use of novel continuous crystallizers or modified conventional continuous crystallizers for the preparation of polymorphs, chiral enantiomers, solvates/hydrates, cocrystals, and spherical crystals. In addition, the theoretical framework and verification of the model-based control approaches are demonstrated. The application of process analytical technology tools in classical feedback loop control strategies in continuous crystallization is also discussed. Despite all this, the application of continuous crystallization still remains challenging because of the existence of drawbacks such as fouling and blockages. Therefore, a systematic discussion should be done before continuous crystallization is more widely applied.

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Low‐Cost Noninvasive Real‐Time Imaging for Tubular Continuous‐Flow Crystallization

Cited by 28 publications

References 30 publications

Continuous Generation of Millimeter-Sized Glycine Crystals in Non-Seeded Millifluidic Slug Flow

Continuous Generation of Millimeter-Sized Glycine Crystals in Non-Seeded Millifluidic Slug Flow

Flow Map for Hydrodynamics and Suspension Behavior in a Continuous Archimedes Tube Crystallizer

Recent Progress in Continuous Crystallization of Pharmaceutical Products: Precise Preparation and Control

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