Maximize efficiency with this scalable protocol for high-throughput neuronal cell plating, ensuring best cell attachment and electrophysiology recordings.

Maximize efficiency with this scalable protocol for high-throughput neuronal cell plating, ensuring best cell attachment and electrophysiology recordings.

Instructions for setting up, handling and maintaining the MaxOne Tissue Holder and Perfusion System for reliable acute tissue recording on the MaxOne System.

Acute recordings of spinal cord organoids generated via a commercially available kit from ACROBiosystems, performed on MaxTwo 6-Well Plate with Liquid Holder.

This webinar presents how combining transcription factor overexpression with developmental signaling modulation enables the generation of diverse human neuron types. It highlights large-scale single-cell transcriptomics and functional profiling approaches used to link neuronal identity with activity, connectivity, and maturation.

This protocol describes the preparation, slicing, and recovery of human brain organoid sections optimized for high-density electrophysiological recordings on MaxWell Biosystems platforms

Unlock the potential of MaxTwo, a multiwell HD-MEA system offering unmatched resolution, high throughput, and exceptional sensitivity to maximize cell functional assays.

Explore MaxOne, a powerful high-density microelectrode array (HD-MEA) system for precise, multi-level electrophysiological recordings and stimulation of electrogenic cells.

Introducing the first fully integrated multiwell MEA perfusion system, MaxTwo Perfusion system ensures continuous medium flow and high-resolution data for advanced cell research.

Learn how combining MaxTwo Multi-Well High-Density MEA technology with FUJIFILM hiPSC-derived neurons enables advanced investigation of neurodegenerative disease mechanisms, including comparative analyses of Parkinson’s, ALS, and FTD models versus healthy controls. The talk also highlights how optimized HD-MEA assays detect subtle functional phenotypes to precisely characterize disease models.

Label-Free Functional Characterization of Human iPSC-Derived Neurons at Subcellular Resolution

This guide explains how to process MaxLab Live recordings to extract single-neuron activity using SpikeInterface for spike sorting and DeePhys for downstream functional analysis.

The Importance Of High-Density Microelectrode Arrays For Recording Multi-Scale Extracellular Potential And Label-Free Characterization Of Network Dynamics in iPSC-Derived Neurons

Next Generation Electrophysiology for Functional Characterization of Human Neural Organoids and Assembloids

Learn how micro- and nano-channel PDMS platforms enable directional neuronal network fabrication at single-neuron resolution and support personalized disease modeling using patient-derived cells. The talk also demonstrates how biophysical modeling and information-theoretic analysis of neuronal networks on a chip reveal synaptic receptor alterations and altered information flow in glioblastoma-infiltrated networks.

Acquire functional HD-MEA recordings from your brain organoids in no time with this unique and easy-to-use protocol.

Optimize your experiments with the MaxOne User Guide: step-by-step setup, safety, maintenance, and troubleshooting for the MaxOne HD-MEA system.

Guide for cell culture with MaxOne & MaxOne+Chips.

Learn how to use the MaxLab Live API, opening the door to custom, programmable, and integrated experimentation with MaxWell Biosystems' high-density microelectrode array (HD-MEA) systems.

Learn how inter-regional connectivity underlies complex brain functions and how neural organoid networks can model these circuits in vitro. The talk highlights how HD-MEAs enable detailed analysis of organoid network activity and functional connectivity.

This manual provides a complete guide to using MaxLab Live software, from setup and data acquisition to analysis and multiplate workflows.

Optimize your experiments with the MaxTwo User Guide: step-by-step setup, safety, plate handling, maintenance, and troubleshooting for the MaxTwo HD-MEA system.

Use this brain organoid plating protocol for MaxOne+& MaxOne to achieve optimal attachment and enable longitudinal electrophysiology recordings of your neural organoids.

Follow this easy-to-use neuronal cell plating protocol for MaxOne,ensuring optimal cell growth and attachment with clear step-by-step instructions.

Use this Brain Organoid Plating Protocol for MaxTwo to achieve high-throughput, longitudinal electrophysiology recordings of your neural organoids.

Find important guidelines on PDMS applications and learn how to culture and record from engineered neuronal networks on MaxWell Biosystems' HD-MEA platforms.

Culturing Human iPSC-derived Mixed Neurons on Multielectrode Arrays: MaxTwo Multiwell MEA

SynFire®iN plating protocol and chemical long-term potentiation on MaxWell Biosystems Multi-Well High-Density Microelectrode Array (HD-MEA)

Guidelines for handling MaxTwo well plates.

This guide outlines the principles of electrical stimulation and provides recommendations for safe and effective use with MaxWell Biosystems’ products.

Longitudinal Functional Profiling of HumaniPSC-derived Frontotemporal Dementia Neuronson HD-MEAs

Plating organoids on MaxTwo Multiwell Plates has never been so easy, thanks to our detailed step-by-step instructions, with practical tips at key stages.

Discover helpful tips for optimizing your organoid and spheroid cultures and their recordings on the MaxOne and MaxTwo systems.

Co-culturing ioMotor Neurons and rat cortical astrocytes for HD-MEA

Experience MaxOne⁺, the next generation ready-to-use HD-MEA chip with enhanced cell adhesion, superior signal quality, and powerful stimulation for peak performance.

This document provides a detailed guide for analysing exported metrics from MaxLab Live using GraphPad.

Unlock MaxLab Live’s API module: real-time data access, custom workflows, external integrations, and advanced stimulation control for enhanced experimental capabilities.

Plating organoids on MaxOne Chips has never been so easy, thanks to our detailed step-by-step instructions, with practical tips at key stages.

This quick guide explains how to set up the MaxTwo Perfusion System.

This document describes decontamination steps for the MaxTwo system.

User guide for setting up the Digital Input Extension Board (DigiPins) to synchronize external events with MaxOne recordings using Python scripts.

This document describes the decontamination steps to follow before returning the MaxOne system.

This document describes the protocol to plate and maintain cardiomyocytes using MaxOne.

Long-term Characterization of Quick-NeuronTMExciatory - Human iPSC-derived Neurons with High-Density Microelectrode Arrays

Capture high-density electrophysiology recordings from acute cerebellar brain slices with the MaxOne Tissue Holder and Perfusion System for stable, reproducible results.

Episcopic brightfield imaging of neuronal cells on high-densitymicroelectrode arrays enables prediction of cell region through AI learning

See how easy it is to apply the Breathe-Easy® sealing membranes on our MaxTwo Multiwell Plates, minimizing evaporation and ensuring optimal conditions for your sample.

Just a single tiny drop is all it takes to get the best out of your iPSC-derived neuronal cultures or primary cell cultures on MaxOne Chips.

Just a single tiny drop to get the best from your iPSC-derived neuronal cultures or primary cell cultures on MaxTwo Multiwell Plates.

Just a small drop is all it takes to get the most out of your iPSC-derived neuronal cultures or primary cell cultures on MaxOne Chips.

Just a small drop to get the best from your iPSC-derived neuronal cultures or primary cell cultures on MaxTwo Multiwell Plates.

This guide explains how to install the decompression library required to read MaxLab Live recordings with external tools.

Capture high-density electrophysiology recordings from acute brain slices with the MaxOne Tissue Holder and Perfusion System for stable, reproducible results.

Long-term functional characterization of SynFire®iNs and astrocytes co-cultured on MaxTwo multi-well high-density microelectrode arrays

Explore axonal insights with the AxonTracking Assay: high-resolution, label-free HD-MEA recordings for automated, long-term tracking using MaxOne and MaxTwo.

Developing next-generation in-vitro phenotypic assays for Huntington's disease by combining precision reprogrammed hiPSC-derived disease models with high-density microelectrode arrays.

This protocol describes how to exchange the Exchangeable Pin Connectors of the MaxOne Recording Unit

Instructions for proper handling of the MaxOne chip holder during experiments