Membrane Chamber

Membrane Chamber

  • Upright or inverted microscope access to a well perfused, perfectly flat and transparent in vitro slice preparation
  • Slice viability increased beyond 16 hours as demonstrated with LFP recordings
  • High mechanical stability, high flow rate and Bernoulli effect to optimise nutrient access for slices
  • Quick replacement of membrane discs and chamber designed for easy cleaning

The MC is a new design of in vitro slice recording chamber (Hill & Greenfield 2010). Brain slices are submerged on a completely flat, transparent semi-permeable membrane. This offers for the first time ideal conditions for inverted microscopy of in vitro preparations. The utilisation of a membrane with a high molecular weight cut-off ensures all nutrients and oxygen can flow freely for optimum perfusion. The design of the flow path is such that rates up to 20ml/min can be used without inducing mechanical noise. A further advantage is that the high speed flow of oxygenated aCSF directly underneath and across the semi-permeable membrane exerts a Bernoulli effect, resulting in a pressure difference between the upper and lower surfaces of the membrane.

This in turn causes a significant movement of nutrients and oxygen downwards through the semipermeable membrane, increasing the availability to the slice especially on the underside and thereby surpassing passive slice perfusion techniques. The active flow downward through the membrane keeps the slice from floating and makes it mechanically stable. The transparent membrane offers ideal conditions for imaging through a glass coverslip window on the underside of the chamber with an inverted microscope whilst the upper chamber is exposed for microelectrode access. Alternatively there is sufficient access from above for upright microscopes to allow immersion objectives to be used and allow access with microelectrodes from the front and sides.

Schematic

A peristaltic pump delivers pulsatile flow at high speed in the range 15ml / min (A) into a reservoir containing a buffer (B) which induces turbulence and reduces pulsation. Smoothed laminar flow passes through the infra chamber (C) directly below the surface of the semipermeable membrane (E) carrying the slice preparation. A Bernoulli effect produces a pressure difference between the upper and lower surfaces resulting in a net movement downwards (arrows) through the membrane and also increases access to slice preparation. A glass coverslip window allows for optical access (D) from below. Fluid exits into the supra chamber (F) and leaves from the chamber through a buffered exit for smooth outflow with a pump or vacuum line.

Specifications

Size:
100mm diameter X 10mm thickness

Material:
Clear acrylic

Coverslip Base:
22mm X 150um thickness, borosilicate glass. Attached to base of chamber with silicone rubber sealant.

Inlet Tube:
10X32 UNF fitting.

Exit Tube:
Stainless steel hypodermic tubing

Dead Space:
Approx 4ml between in and out ports