Biomedical Engineer

As a Biomedical Engineer at Pilgrim, you will be a hands‑on member of our engineering team, driving the design, development, and integration of hardware systems that support complex scientific workflows. This is not a theoretical or routine R&D role—you’ll own projects end‑to‑end, exploring design options, prototyping aggressively, and refining systems through iterative testing. You will move fluidly between CAD, prototyping, experimental evaluation, and integration work, supporting a wide range of engineering challenges informed by both engineering principles and practical experience working with biology.

• Conduct targeted literature review and technical scouting to understand prior approaches, evaluate alternatives, and identify methods that can be improved or integrated.

• Design and develop components and subsystems in CAD (Fusion 360 preferred), including housings, fixtures, flow structures, reagent interfaces, thermal/optical elements, and integration features.

• Prototype parts using 3D printing (FDM/SLA), benchtop machining, laser cutting, bonding, and other rapid fabrication methods; iterate quickly based on test results.

• Develop and integrate fluidic structures such as channels, manifolds, valves, seals, pumps, and reagent‑delivery elements for consistent, reliable operation.

• Explore experimental approaches to meet system requirements, comparing designs, materials, and fabrication pathways based on performance, manufacturability, and integration constraints.

• Test hardware subsystems and interfaces—flow behavior, fouling/contamination, sealing, thermal response, mechanical reliability—and refine designs based on observed failure modes.

• Collaborate with scientists and engineers to ensure hardware supports stable workflows, predictable performance, and practical operation.

• Work with electrical and firmware teams to integrate sensors, heaters, pumps, LEDs/photodiodes, actuators, and other instrumentation into cohesive systems.

• Apply DFM/DFA principles, tolerance analysis, and validation testing (fit checks, flow/pressure/thermal behavior) to guide designs toward production intent.

• Maintain disciplined documentation across CAD revisions, design decisions, test data, and integration results.

• Contribute to system‑level architecture discussions, proposing mechanical and fluidic strategies informed by research and experimental outcomes.

• B.S. in Biomedical Engineering, Mechanical Engineering with relevant experience, Bioengineering, or a related hands‑on engineering field.

• Portfolio or project examples demonstrating CAD design, prototyping, and iterative hardware development.

• Strong proficiency in CAD (Fusion 360 preferred; Solid Works/Onshape acceptable), including assemblies, tolerancing, and parametric design.

• Hands‑on prototyping experience with 3D printing, laser cutting, bonding/sealing methods, tubing/fittings, and benchtop fabrication tools.

• Understanding of workflows involving fluids, sample handling, reagent compatibility, contamination control, and precision fluid manipulation.

• Experience developing or working with fluidic architectures—channels, chambers, manifolds, seals, valves, or flow structures.

• Comfort integrating simple electromechanical elements such as sensors, heaters, pumps, or optical modules.

• Ability to diagnose fluidic and mechanical failure modes and iterate quickly under real constraints.

• Clear communication and the ability to work effectively across engineering and scientific teams.

• Experience with microfluidics, cartridge‑style consumables, or diagnostic hardware.

• Exposure to thermal control, optics, low‑volume flow systems, or fluid simulation tools.

• Familiarity with materials used in fluidic and instrumentation hardware (PP, PTFE, silicones, optical plastics, laminates).

• Background in ruggedized or field‑deployable scientific instrumentation.

• Hands‑on experience with assembly, testing, or root‑cause analysis of integrated systems.