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Related Concept Videos

Methods of reducing fever01:22

Methods of reducing fever

The signs and symptoms of fever include hot and dry skin, flushed face, thirst, muscle aches, anorexia, headache, tachycardia, tachypnea, and fatigue. Elevated body temperature is reduced using two methods: pharmacological and nonpharmacological. Proper identification and treatment of the root cause of a fever is of utmost importance.
Pharmacological Methods of Reducing Fever:

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Optimizing lyophilization primary drying: A vaccine case study with experimental and modeling techniques.

Jeff Najarian1, Efimia Metsi-Guckel1, Harshil K Renawala1

  • 1Merck & Co., Inc., Rahway, NJ 07065, USA.

International Journal of Pharmaceutics
|April 25, 2024
PubMed
Summary
This summary is machine-generated.

Optimizing lyophilization cycles for vaccines involves aggressive drying, challenging traditional methods. This study found that exceeding the collapse temperature (Tc) can safely reduce drying times by 45% while maintaining vaccine quality.

Keywords:
CollapseDried layer resistanceFreeze-drying microscopyLyophilizationModelingPrimary drying

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Area of Science:

  • Pharmaceutical Sciences
  • Chemical Engineering
  • Biotechnology

Background:

  • Lyophilization (freeze-drying) is crucial for vaccine stability and shelf-life.
  • Optimizing primary drying time is key to reducing overall lyophilization cycle length.
  • Conventional methods often lead to sub-optimal, lengthy drying cycles.

Purpose of the Study:

  • To optimize the primary drying time of a vaccine formulation.
  • To evaluate thermal characteristics, temperature profiles, and critical quality attributes (CQAs).
  • To develop a more reliable method for determining macroscopic collapse temperature in vials.

Main Methods:

  • Differential Scanning Calorimetry (DSC) and Freeze-Drying Microscopy (FDM) to determine critical temperatures (Tg', Tc).
  • Manometric Temperature Measurement (MTM) to assess product resistance (Rp) and temperature profiles.
  • First principles modeling for heat and mass transfer to generate a primary drying design space.

Main Results:

  • Aggressive drying conditions, exceeding the FDM-determined collapse temperature (Tc), reduced drying time by ~45% without compromising CQAs.
  • Product temperature drop post-primary drying correlated with the degree of macroscopic collapse.
  • A more representative macroscopic collapse temperature (Tcm) was determined using quantitative analysis of temperature, resistance, and visual cake appearance.

Conclusions:

  • Accurate determination of macroscopic collapse in vials is critical for process optimization.
  • Pursuing aggressive lyophilization drying, tailored to specific product characteristics, can significantly reduce cycle times.
  • Integrating experimental data with modeling techniques enables efficient development and optimization of lyophilization processes.