Infrared Thermography for Monitoring of Freeze Drying Processes—Part 2: Monitoring of Temperature on the Surface and Vertically in Cuvettes during Freeze Drying of a Pharmaceutical Formulation

Emteborg, Håkan; Charoud-Got, J.; John, Seghers

doi:10.3390/pharmaceutics14051007

Cited by 4 publications

(14 citation statements)

References 20 publications

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“…If placed outside the chamber on the top of the freeze-dryer, the sensor, through a germanium window, was able to measure the product temperature on the top surface of the upper shelf, the only one that the camera could see [ 40 ]. In order to also measure the whole axial temperature profile, Emteborg et al [ 41 ] used custom-made cuvettes with a germanium window on one side, placed close to an IR mirror with a 45° angle in such a way that the IR radiation from the cuvette was reflected upwards to the IR camera. It is evident that such a system requires strong hardware modifications and is not widely applicable.…”

Section: Resultsmentioning

confidence: 99%

“…The main drawback is represented by the harsh conditions that are experienced by the sensor in the drying chamber, i.e., a temperature that may reach values as low as −40 °C or −50 °C (in the freezing step) during the cycle, a low pressure, and a gas composition that is about 100% water vapor. For these reasons, Emteborg et al [ 40 , 41 ] placed the camera outside the drying chamber, on the top of the freeze-dryer, using a germanium window. In addition, also Van Bockstal et al [ 42 ] placed the infrared camera outside the freeze-dryer, although in their case, a continuous freeze-drying process was monitored.…”

Section: Introductionmentioning

confidence: 99%

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On the Use of Temperature Measurements as a Process Analytical Technology (PAT) for the Monitoring of a Pharmaceutical Freeze-Drying Process

et al. 2023

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The measurement of product temperature is one of the methods that can be adopted, especially in the pharmaceutical industry, to monitor the freeze-drying process and to obtain the values of the process parameters required by mathematical models useful for in-line (or off-line) optimization. Either a contact or a contactless device and a simple algorithm based on a mathematical model of the process can be employed to obtain a PAT tool. This work deeply investigated the use of direct temperature measurement for process monitoring to determine not only the product temperature, but also the end of primary drying and the process parameters (heat and mass transfer coefficients), as well as evaluating the degree of uncertainty of the obtained results. Experiments were carried out with thin thermocouples in a lab-scale freeze-dryer using two different model products, sucrose and PVP solutions; they are representative of two types of commonly freeze-dried products, namely those whose structures are strongly nonuniform in the axial direction, showing a variable pore size with the cake depth and a crust (leading to a strongly nonlinear cake resistance), as well as those whose structures are uniform, with an open structure and, consequently, a cake resistance varying linearly with thickness. The results confirm that the model parameters in both cases can be estimated with an uncertainty that is in agreement with that obtained with other more invasive and expensive sensors. Finally, the strengths and weaknesses of the proposed approach coupled with the use of thermocouples was discussed, comparing with a case using a contactless device (infrared camera).

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

On the Use of Temperature Measurements as a Process Analytical Technology (PAT) for the Monitoring of a Pharmaceutical Freeze-Drying Process

et al. 2023

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“…This contribution introduces a shelf-scale monitoring technique based on infrared thermography for this purpose. We build on earlier techniques that have been employed to monitor the thermal evolution of a large number of vials at the same time during freeze-drying: [25][26][27][28][29] Emteborg et al 25 cut a hole into the top of a freeze-dryer to install an infrared camera for the monitoring of the top-most shelf with 2D resolution. Lietta et al 27 developed a camera module that fits inside a freeze-dryer and monitors the vials from the side, effectively measuring the temperature of the glass vial.…”

Section: Introductionmentioning

confidence: 99%

Visualizing and understanding batch heterogeneity during freeze-drying using shelf-scale infrared thermography

Deck,

Ferru,

Košir

et al. 2024

Preprint

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Freeze-drying is widely used for manufacturing biopharmaceuticals in vials. One significant challenge in process design and optimization is heterogeneity among vials across a batch, which has been difficult to investigate due to the lack of adequate monitoring techniques. Here we leverage infrared thermography to quantify the freezing and drying behavior of all vials, hence enabling comprehensive studies of batch heterogeneity. Surprisingly, the stochasticity of nucleation, commonly considered the main driver of batch heterogeneity, only causes little heterogeneity. Instead, heterogeneity originates from heat transfer between vials: when ice is formed in one vial, the release of latent heat governs the freezing behavior of its neighboring vials. Guided by a mechanistic model and confirmed by experiments, the cooling rate and geometrical arrangement of the vials are identified as main drivers of batch heterogeneity. In conclusion, this contribution reports transformational insights into freeze-drying and supports practitioners in process design and optimization.

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“…First, it is a single-point measurement, and second, the presence of the probe itself affects the drying process [4]. In two previous articles from 2014 and 2022, Emteborg et al described the coupling of an IR camera to a freeze-dryer, thereby measuring the product temperature contact-free and with superior spatial resolution [5,6]. The work from 2014 described the first application of this kind [5].…”

Section: Introductionmentioning

confidence: 99%

Thermal Effect of Probes Present in a Pharmaceutical Formulation during Freeze-Drying Measured by Contact-Free Infrared Thermography

Emteborg,

Charoud-Got

2024

Applied Sciences

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A high-resolution infrared (IR) camera was used for temperature measurements in a pharmaceutical formulation (mannitol/sucrose solution, 4:1%, m/m) during a freeze-drying process. The temperature was measured simultaneously at the surface as well as vertically (e.g., in-depth) along the side of custom-made cuvettes equipped with a germanium (Ge) window. Direct imaging during 45 h from −40 °C to 40 °C took place every 60 s on the surface and on the side with 0.28 × 0.28 mm per IR-pixel providing 2700 thermograms. The spatial resolution per cuvette was approximately 4225 pixels for the surface view (without a probe) and 6825 IR-pixels for the side view. Temperature effects and gradients due to the presence of a Pt100 and a LyoRx-probe in the pharmaceutical formulation were clearly visible and were quantified during the freezing step as well as the primary and secondary drying stages. The temperature was about 3.5 K higher during primary drying as compared to the temperature measured in the same material in adjacent cuvettes without probes. During secondary drying, evaporative cooling of upper layers was clearly visible.

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Infrared Thermography for Monitoring of Freeze Drying Processes—Part 2: Monitoring of Temperature on the Surface and Vertically in Cuvettes during Freeze Drying of a Pharmaceutical Formulation

Cited by 4 publications

References 20 publications

On the Use of Temperature Measurements as a Process Analytical Technology (PAT) for the Monitoring of a Pharmaceutical Freeze-Drying Process

On the Use of Temperature Measurements as a Process Analytical Technology (PAT) for the Monitoring of a Pharmaceutical Freeze-Drying Process

Visualizing and understanding batch heterogeneity during freeze-drying using shelf-scale infrared thermography

Thermal Effect of Probes Present in a Pharmaceutical Formulation during Freeze-Drying Measured by Contact-Free Infrared Thermography

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