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Biopharmaceutical Factors Influencing Drug Product Design: Overview01:22

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Rational drug product design integrates knowledge of the drug’s physicochemical properties, formulation components, manufacturing techniques, and intended route of administration. Each factor influences the drug’s performance, including how it is released, absorbed, and eliminated in the body.The physicochemical properties of a drug—such as solubility, stability, and particle size—affect its compatibility with excipients and the choice of dosage form. Excipients, though...
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Needs-Based Innovation in Interventional Radiology: The Biodesign Process.

Jonathan D Steinberger1, Lyn Denend2, Dan E Azagury2

  • 1Dotter Interventional Institute, Oregon Health & Science University, Portland, OR.

Techniques in Vascular and Interventional Radiology
|July 5, 2017
PubMed
Summary
This summary is machine-generated.

Identifying unmet clinical needs is key for medical technology innovation. Interventional radiologists can leverage their expertise to develop novel solutions, increasing the success of new medical devices.

Keywords:
Medtechbiodesigninnovationmedical devicesneeds-basedprocessproduct developmentunmet need

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Area of Science:

  • Medical Innovation
  • Health Technology Development
  • Clinical Needs Assessment

Background:

  • Innovation in healthcare requires effective strategies for market entry.
  • The Stanford Biodesign process emphasizes understanding unmet clinical needs for ideation.
  • Identifying and validating unmet needs can de-risk development projects.

Purpose of the Study:

  • To highlight the importance of unmet clinical needs in medical innovation.
  • To position interventional radiology as a field suited for developing novel solutions.
  • To discuss strategies for successful technology development in healthcare.

Main Methods:

  • Review of innovation processes in medical technology.
  • Analysis of the role of unmet clinical needs in product development.
  • Examination of the historical contributions and capabilities of interventional radiology.

Main Results:

  • The Stanford Biodesign process provides a framework for needs-based innovation.
  • Addressing unmet needs early enhances the likelihood of successful technology adoption.
  • Interventional radiologists possess unique skills for identifying and solving clinical challenges.

Conclusions:

  • A deep understanding of unmet clinical needs is crucial for successful medical innovation.
  • Interventional radiologists are well-positioned to drive innovation due to their clinical insights and technical background.
  • Adopting a needs-based approach can lead to disruptive innovations with significant clinical and economic benefits.