- Wiring: excitation LED and optogenetic connector
- Connecting the sensor and interface PCBs
- Cable and yarn for sensor PCB (image board)
- Wiring: LED to interface PCB
- Assembling mechanical parts, lenses and filters
- Making a DAQ cable
- How to modify the UCLA DAQ for use with NINscope
- How to make the optogenetic LED probe
- Mounting a NINscope
- LabMaker sells interface/sensor/exc. LED PCB assemblies, baseplates and a modified DAQ v3.2 that is fully compatible with NINscope (https://www.labmaker.org/collections/neuroscience/products/ninscope).
- OpenEphys sell a new DAQ v3.3. box that is cross-compatible with NINscope, UCLA v3/v4 miniscopes (https://open-ephys.org/ninscope/ninscope-daq).
- Jason Rosenberg provides 3D printed parts (https://www.rosenbergindustries.com).
- 🆕 NEUROGIG will provide NINscope either fully assembled, or as a kit (https://neurogig.com/ninscope).
For a parts list with components and links to manufacturers please visit our NINscope parts list spreadsheet. This list will be updated to reflect availability of components. https://drive.google.com/open?id=1j7zTo7a2k-jmMWEIm5uMFHZk3aub0za10LsDC2N34rI
Printed circuit boards used in NINscope were designed in KiCAD. Check the Hardware wiki page for more info: https://github.com/ninscope/Hardware/wiki
LabMaker sells the electronics (PCBs,excitation LED print w/ cabling), baseplates and DAQ box for NINscope here.
We have 3D printed the microscope housing using an EnvisionTec Micro Plus Advantage printer with RCP-30 resin (requires coating afterwards) and a Formlabs Form 2 printer using RS-F2-GPBK-04 black resin. Parts for NINscope can be directly order through Jason Rosenberg https://www.rosenbergindustries.com
The assembly of optics resembles that of the first-gen. UCLA miniscope, with a few differences. First the excitation, emission and dichroic optical filters are 500 µm (although emission filter can also be 1 mm) and therefore thinner and more fragile. The emission filter is glued on to the plano-convex lens with optical bonding glue (NOA81, Norland Products) and lowered into the lower half of the NINscope housing.
For more details see: https://github.com/ninscope/Hardware/wiki/5.-Mechanical-assembly-NINscope
In case of dust particles or other particulates dropping on the CMOS sensor one we recommend the use of 'Sticky Swabs' (ideal-tek, https://www.ideal-tek.com/public/doc/Sticky-swabs-leaflet_Ideal-tek.pdf) to remove them without causing damage to the sensor.
We recommend using a laptop with SSD drive for respectively mobility and optimal disk write speeds. Despite this we have tested operating NINscope on a variety of systems including a MacBook Pro laptop running MacOS Mojave (R2015, i7, SSD), Mac Mini running MacOS High Sierra (R2014, i5, 5400 rpm HD), Dell PC Z240 running Windows 7(i7, NVMe SSD Samsung MZVLW256), a NUC7i5BNH running Windows 10 (i5, SSD Crucial MX500), a Linux Workstation running Ubuntu 18.04 (Intel Xeon, SSD) and a Dell PC OptiPlex 3050 SFF running Ubuntu 18.04 (i5, SSD) and an HP Zbook Studio G3 laptop running Ubuntu 20.04 (i7, SSD).
UVC-compliant USB webcams are supported. We have successfully tested Logitech webcams inlcuding the C920 HD pro cam. PS3 Eye webcams are currently not supported as they are not UVC-compliant.
SMA to BNC cables can be purchased directly, e.g.: https://nl.mouser.com/ProductDetail/Johnson-Cinch-Connectivity-Solutions/415-0028-048?qs=sGAEpiMZZMufBZYvsU%2Fbe5IX9y1Z%252BxjUbtuL98E%2Fl5g%3D. This allows for triggering the acquisition with an external trigger, or logging the miniscope frames during acquisition.