Quantitative Biology

This study explores machine learning techniques to find new coagulant candidates.

FREED++ shows improved drug generation with enhanced molecular design and performance.

Examining the role of exons in protein structure and evolution.

A new framework enhances drug candidate prediction in biomedical research.

Exploring the differences between cgDNA and cgDNA+ in DNA mechanics studies.

Antimicrobial peptides show potential for treating infections and complex health issues.

A look into protein condensates and their role in cell biology.

A new framework enhances the prediction of protein interactions and functions.

Investigating how cell behavior affects migration and interaction with the extracellular matrix.

This article explores how cell migration is influenced by mechanical properties and vimentin.

This article explores how bacteria adapt to chemical changes in their environment.

Study of swimming organisms and fluid motion in confined spaces.

A new model simulates growth and movement of epithelial cells in tissues.

Improving T cell response predictions through innovative model techniques and data approaches.

This article examines how feedback circuits affect cellular decision-making and stability.

Cell adhesion impacts tissue stability, healing, and cancer spread.

This study reviews vulnerabilities in AI models used for genomic applications.

TEPI improves genome classification using images and taxonomy-aware techniques.

A deep look into gene regulation and its impact on biology.

Analyzing gene expression data's role in cancer classification through machine learning models.

Explore how genome changes impact evolution and diversity.

PhenoLinker enhances the prediction of gene-phenotype associations using advanced AI techniques.

DiscDiff enhances DNA sequence generation using advanced machine learning techniques.

Exploring how machine learning enhances understanding of pancreatic cancer through omics data.

This article explores how proteins shape the body plan of Drosophila larvae.

A novel approach enhances understanding of complex oscillatory systems.

Exploring how chemical interactions respond to changes in concentration and environment.

A new method to study and manage cellular noise through light-controlled gene expression.

Scientists study yeast communication to enhance information exchange for various applications.

Investigating how physics helps understand genetic networks in living organisms.

A new approach improves predictions in biological pathway analysis.

Microorganisms use chemical signals to find food and avoid danger.

A straightforward look at the connections between feelings, bodies, and consciousness.

This article reveals how neurons manage their environment actively.

Discover how deep learning can improve vision restoration technologies.

A new biopotential amplifier improves neural signal capture with low noise and power consumption.

Explore how risk attitudes shape our choices in uncertain situations.

A new approach to memory models using chaotic systems enhances storage and retrieval.

A new approach to studying the complexities of neural networks.

Investigating how physics helps understand genetic networks in living organisms.

A look at how living organisms process information and respond to their environments.

A look at the FitzHugh-Nagumo model and its relevance in various fields.

Innovative methods could reshape how we analyze and apply biological data.

Analyzing RNA structure dynamics for better biological understanding.

Study examines ChatGPT's effectiveness in explaining complex cancer reports to patients.

This article examines the relationship between Petri nets and ODEs in epidemiological studies.

A look at how biological models work together to reveal system interactions.

Dareplane offers solutions for effective adaptive deep brain stimulation experiments.

Research on managing species data reveals new methods for accurate predictions.

A new model uses AI to better predict COVID-19 variants and their spread.

Examining how genetic linkage influences breeding success and trait improvement.

Analyzing food webs reveals how nestedness supports ecosystem health and stability.

Examining the impact of household size and structure on infectious disease transmission.

This study combines genetic and geographic data to better define species boundaries.

A look into how microorganisms compete and survive in controlled environments.

A novel approach merging traditional models with machine learning improves infection predictions.

Research on managing species data reveals new methods for accurate predictions.

A study of how pressure waves impact blood vessel junctions and medical conditions.

This article explores how proteins shape the body plan of Drosophila larvae.

Examining how publication types shape aging research in genetics.

NOSTRA enhances the evaluation of hospital-acquired infections and their sources.

A new method accelerates high-dimensional data visualization using polar quadtree structures.

A novel approach enhances understanding of complex oscillatory systems.

A novel approach merging traditional models with machine learning improves infection predictions.

This study examines how nutrient availability affects ribosome production and degradation.

Understanding how ER shape affects molecule movement and target encounters.

Examining how DNA and proteins interact affects gene regulation.

A look into the complexity of gene expression and its variable nature.

Centrosomes manage microtubules and are crucial during cell division.

Exploring the effects of noise and transcriptional bursting on gene networks.

Research reveals how proteins can be influenced by THz waves for medical applications.

Study reveals how proteins influence membrane shapes and cellular functions.

Examining how blood flows in small vessels aids in understanding health and diseases.

This study investigates how cancer cells invade tissue using a gelatin model.

Research explores spiral wave interactions and their impact on heart rhythms.

Exploring how sponge chambers optimize water pumping and filtering.

Research aims to improve lung function tests for better diagnosis and treatment.

A new model simulates growth and movement of epithelial cells in tissues.

Researchers develop patient-specific models to better study glioblastoma treatment responses.

A new model predicts inhaled medication distribution in lungs with airway disease.