GS 3: Science & TechnologyGS 3: Environment & EcologyPrelims

Malaria parasites corkscrew through skin while finding a way to the liver, PgII

Malaria parasites' corkscrew motion through skin, driven by 'colored noise', enhances navigation to liver, Heidelberg study reveals.

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Key Highlights:

  • Malaria parasites use helical (corkscrew-like) motion to navigate through the skin to reach the liver after a mosquito bite.
  • Researchers at Heidelberg University studied this movement in synthetic hydrogels, publishing their findings in Nature Physics on November 24.
  • The study found that parasites move almost exclusively on right-handed helices in 3D environments.
  • A mathematical model showed that helical motion helps parasites travel farther in noisy environments compared to straight-line movement.
  • The model identified time scales of 20 seconds for one helical turn and 100 seconds for the helix axis to maintain direction.

Detailed Insights:

  • Malaria parasites face challenges from environmental noise and internal fluctuations that can disrupt their orientation.
  • The helical path's radius matches the size of small blood vessels, aiding navigation.
  • The study used an Ornstein-Uhlenbeck (OU) process to model rotational noise, mimicking internal processes within the parasite.
  • The model showed that helical motion allows parasites to maintain a stable direction despite internal fluctuations.
  • This research complements earlier studies on sperm cells and algae, where helical swimming aids movement in chemical gradients.
  • The findings suggest that helical motion is a robust evolutionary strategy for efficient travel in noisy environments.
  • The model could inspire the design of micro and nanobots for effective navigation in complex tissues for medical applications.

Scientific/Technical Concepts Involved:

  • Helical Motion: Movement in a corkscrew-like path, characterized by a constant turn and forward motion.
  • Ornstein-Uhlenbeck (OU) Process: A mathematical model describing noise that is partly predictable, mimicking internal biological processes.
  • Chiral Active Particle: A particle that tends to twist around in a fixed direction as it moves forward.
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