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Related Concept Videos

Positron Emission Tomography01:29

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Positron emission tomography (PET) is a medical imaging technique involving radiopharmaceuticals — substances that emit short-lived radiation. Although the first PET scanner was introduced in 1961, it took 15 more years before radiopharmaceuticals were combined with the technique and revolutionized its potential.
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The average temperature of Earth is the subject of much current discussion. Earth is in radiative contact with both the Sun and dark space; it receives almost all its energy from the radiation of the Sun and reflects some of it into outer space. Dark space is very cold, about 3 K, so Earth radiates energy into it. For instance, heat transfer occurs from soil and grasses, the rate of which can be so rapid that frost can occur on clear summer evenings, even in warm latitudes.
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Related Experiment Video

Updated: Mar 27, 2026

Proton Therapy Delivery and Its Clinical Application in Select Solid Tumor Malignancies
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FLASH Particle Radiotherapy.

Jufri Setianegara1, Ioannis I Verginadis, Constantinos Koumenis

  • 1Department of Radiation Oncology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA.

Cancer Journal (Sudbury, Mass.)
|March 25, 2026
PubMed
Summary
This summary is machine-generated.

FLASH radiotherapy, an ultrahigh dose rate radiation technique, shows promise in reducing normal tissue damage while controlling tumors. Integrating this with particle therapy may improve cancer treatment outcomes and patient quality of life.

Keywords:
FLASH radiotherapynormal tissue sparingparticle therapy

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Area of Science:

  • Oncology
  • Radiation Oncology
  • Medical Physics

Background:

  • FLASH radiotherapy delivers radiation at ultrahigh dose rates, potentially reducing normal tissue toxicity.
  • Current radiotherapy techniques can cause severe side effects, limiting treatment efficacy.
  • Particle therapy (protons, heavy ions) offers physical and biological advantages in radiation delivery.

Purpose of the Study:

  • To explore the potential of FLASH particle therapy in improving the therapeutic ratio for cancer treatment.
  • To highlight the advantages of combining FLASH dose rates with particle therapy for enhanced normal tissue sparing and dose escalation.
  • To outline the requirements for clinical implementation and widespread adoption of FLASH particle therapy.

Main Methods:

  • Review of emerging evidence on FLASH radiotherapy and particle therapy integration.
  • Discussion of physical and biological advantages of FLASH particle therapy.
  • Identification of key areas for advancement: mechanistic understanding, beam delivery, quality assurance, and adaptive strategies.

Main Results:

  • FLASH radiotherapy demonstrates potential for significant normal tissue toxicity reduction.
  • FLASH particle therapy offers enhanced normal tissue sparing and potential for safe dose escalation.
  • Clinical integration requires further research into biological mechanisms and technological advancements.

Conclusions:

  • FLASH particle therapy presents a promising advancement in radiation oncology.
  • Further research, technological development, and clinical trials are necessary for widespread adoption.
  • Successful implementation could lead to improved cancer treatment outcomes and patient quality of life.