Research Articles
The Invisible World Beneath Our Implants: How Nanoscale Patterns Guide Bone Healing
Discover how nanoscale surface patterns on medical implants influence bone cell behavior and osseointegration success.
The Invisible Architects: How Protein Networks Shape Our Red Blood Cells
Discover how the sophisticated protein network in red blood cells enables their remarkable functions and what this means for medical science.
The Invisible Tug-of-War: How Actin's Push and Pull Guides Cell Movement
Exploring how spatial elasticity patterns of actin filaments dictate cellular migration behaviors in health and disease.
The Actin Tug-of-War: How Cellular Proteins Gelsolin and Nm23-H1 Clash to Stop Cancer's Spread
Discover how the interaction between Gelsolin and Nm23-H1 proteins could unlock new metastasis-blocking therapies in cancer treatment.
The Invisible Gym: How a Single Workout Reprograms Your Muscles at the DNA Level
Discover how acute exercise induces immediate epigenetic changes through DNA methylation, reprogramming your muscles at the genetic level.
The Amoeba's Dance: How a Microfluidic Microscope Sheds Light on a Genetic Mystery in Dictyostelium
Exploring how microfluidic devices revealed the role of the FRY gene in Dictyostelium discoideum's cell behavior and adhesion mechanisms.
The Thorny Enigma: How Misshapen Blood Cells Reveal Brain Secrets
Exploring neuroacanthocytosis (NA) - rare genetic disorders where thorny red blood cells coincide with progressive neurological decline and what they reveal about brain function.
The Cellular Symphony: How Protein Acetylation Conducts Longan Embryo Development
Discover how protein acetylation regulates longan embryo development through somatic embryogenesis, revealed by cutting-edge proteomic and acetylomic studies.
The Leaky Gatekeeper: How an Ancient Herb Heals the Brain's Fortress After Stroke
Discover how Erigeron breviscapus, an ancient herb, repairs blood-brain barrier damage after stroke through its unique molecular mechanisms.
The Silent Guardians: How a "Domesticated" Jumping Gene Stabilizes Our Genome
Discover how the domesticated jumping gene L1TD1 stabilizes our genome by controlling LINE-1 retrotransposons and its implications for cancer and neurodegenerative diseases.