Director of Bioengineering

About The Position

Requirements

• Ph.D. in Biophysics, Bioengineering, Computer Science, or a closely relatedfield.
• Deep understanding of Microscopy, modeling in the Life Sciences, and AI/ML applications to biomedical Computer Vision and Omics.
• A demonstrated obsession with process refinement and the ability to pivot engineering strategies based on emergent biological data to progressively improve tissue viability and assay signal-to-noise ratios.
• Hands-on wet-lab and microscopy experience, with a proven ability to design and optimize novel post acquisition suites of tools for processing large image volumes (e.g., light-sheet microscope data).
• Deep understanding of scientific software engineering, ML ops, and AI infrastructure, including cloud and High-Performance Computing (HPC).
• Proven track record of high-impact publications and production pipeline development at top international institutions. Experience bridging fast-paced academic environments with biotech/startup execution.
• Demonstrated history of unlocking funding, mapping strategic multi-year plans, and transitioning AI/Computational teams into dynamic, top-tier internal units while scaling up throughput, accuracy, and output quality.

Responsibilities

• Scalable Architecture: Lead the engineering and operationalization of a highly scalable incubator platform capable of supporting up to 1,000 viable 300-micron by 8x8mm human brain slices per whole-brain run.
• Iterative Quality Enhancement: Design and enforce rigorous feedback loops between end-point omics/imaging data and upstream slice preparation/incubation. Use this data to continuously refine variables (e.g., media composition, flow rates, slice thickness) to relentlessly push the boundaries of tissue health and data yield.
• Automated Fluidics & Dosing: Oversee the deployment of continuous, robotically tracked aspirate-dispense fluid operations, ensuring each slice is managed with a precise, custom drug-dosing protocol over a 1-month survival window.
• Phenomics & Omics Integration: Develop protocols to bridge living slice assays with end-point imaging phenomics and high-throughput omics (e.g., snRNA-seq) to determine the exact cellular and molecular effects of dosed drug molecules.
• Adaptive Pipeline Management: Direct the automated pipeline from slicing and robotic mesh-cradle handling through rapid structural/molecular clearing and imaging protocols. Implement agile Quality Control (QC) gates that treat every batch as an opportunity to iterate and upgrade the baseline quality of the process.
• Advanced Microscopy: Oversee the operation of Light Sheet Microscope clusters, leveraging a combination of autofluorescence structure scans with active antibody staining.
• Targeted Omics & Expansion Retrieval: Develop automated CNC micro-dissection/laser capture (LCM) workflows for spatial transcriptomics/proteomics (Orbitrap/NextSeq) and nanoscale MultiExR (Multiplexed Expansion Retrieval) processing.
• Data Infrastructure: Oversee the capture, streaming, and storage of petabyte-scale data over a 100GbE network fabric.
• Virtual Staining & Registration: Collaborate with the computational biology and AI teams in training and deploying 'Virtual Proteome' AI models that seamlessly register multi-modal informatics and imaging streams into unified representations used for scientific research.
• Culture of Continuous Improvement: Build and mentor a world-class, multi-disciplinary team of imaging specialists, lab operations managers, robotics engineers, data engineers, and computational biologists. Instill a team culture where sub-optimal yields are rapidly analyzed and transformed into actionable, iterative protocol upgrades.
• Budget & Scale: Manage a multi-million dollar CapEx and OpEx budget, driving the facility's scale-up from an 'Alpha' proof-of-concept to an industrial bio-foundry processing 1,000 brains/year.