Latest Articles for Biology

Learn how sparsification helps manage complex network systems efficiently.

A look into how networks shape our world.

An overview of SFDEs and their applications in various fields.

This article explores how different organisms display unique tile patterns.

Simpler feedback loops can drive biological oscillations through spatial arrangements.

Learn how graph diffusion models transform data generation in science.

A look at microphase separation and its significance in science.

Exploring Voronoi diagrams through Hilbert geometry reveals new insights and applications.

Exploring the unique movement of self-propelling particles in various environments.

Study examines how self-propelled rods form clusters and align through collisions.

Research uncovers complex interactions driving biomolecular condensate formation.

A look at mean reflected McKean-Vlasov stochastic differential equations and their applications.

This study reveals how biological networks evolve and their significance in various fields.

A look into the dynamics of autocatalytic networks across various fields.

A novel approach improves imaging and tracking precision in molecular research.

Physical models make biology more tangible and engaging for learners.

An overview of Hamiltonian cycles and their significance in graph theory.

Study reveals how reaction delays influence patterns in active particles.

Exploring factors influencing the stability of complex systems across various fields.

Introducing a new segmentation technique for improved epigenetic data analysis.

A look into the behavior of random piecewise convex maps and their significance.

Innovative techniques aim to bridge the gap in PPI research across diverse species.

Exploring new insights and applications in the isoperimetric problem across various fields.

GAPPIS combines gel-based and shotgun techniques for improved protein analysis.

This article explores how pathway modules assist in studying biochemical networks.

This study reveals new dynamics in active nematics, enhancing our grasp of biological systems.

Exploring the interactions and stability of dynamic systems across various fields.

Researchers improve microscopy image clarity using modern denoising techniques.

Examining how neurons synchronize and its effects on brain functions.

Research reveals how random noise can lead to unique forms of synchronization.

Improved methods for studying protein interactions using TurboID and PL-MS.

Discover how slime molds recognize their species and interact with their environment.

Gastruloids provide insights into the early stages of mammalian development.

Research shows how chemical signals influence the behavior of active particles.

New light-sheets improve imaging and simplify microscopy setup.

Researchers introduce the Boosting Autoencoder for clearer insights into scRNA-seq data.

An overview of unswitchable graphs and their significance in graph structures.

Examining the role of resetting in subdiffusion and its applications.

Study assesses various tools for detecting short linear motifs in proteins.

Investigating how peptide structure affects electron movement and conductivity.