The browser you are using is not supported by this website. All versions of Internet Explorer are no longer supported, either by us or Microsoft (read more here:

Please use a modern browser to fully experience our website, such as the newest versions of Edge, Chrome, Firefox or Safari etc.

Portrait of Tommy Nylander. Photo: Kennet Ruona

Tommy Nylander


Portrait of Tommy Nylander. Photo: Kennet Ruona

Morphologies and Structure of Brain Lipid Membrane Dispersions


  • Viveka Alfredsson
  • Pierandrea Lo Nostro
  • Barry Ninham
  • Tommy Nylander

Summary, in English

This study aims to explore the variety of previously unknown morphologies that brain lipids form in aqueous solutions. We study how these structures are dependent on cholesterol content, salt solution composition, and temperature. For this purpose, dispersions of porcine sphingomyelin with varying amounts of cholesterol as well as dispersions of porcine brain lipid extracts were investigated. We used cryo-TEM to investigate the dispersions at high-salt solution content together with small-angle (SAXD) and wide-angle X-ray diffraction (WAXD) and differential scanning calorimetry (DSC) for dispersions in the corresponding salt solution at high lipid content. Sphingomyelin forms multilamellar vesicles in large excess of aqueous salt solution. These vesicles appear as double rippled bilayers in the images and as split Bragg peaks in SAXD together with a very distinct lamellar phase pattern. These features disappear with increasing temperature, and addition of cholesterol as the WAXD data shows that the peak corresponding to the chain crystallinity disappears. The dispersions of sphingomyelin at high cholesterol content form large vesicular type of structures with smooth bilayers. The repeat distance of the lamellar phase depends on temperature, salt solution composition, and slightly with cholesterol content. The brain lipid extracts form large multilamellar vesicles often attached to assemblies of higher electron density. We think that this is probably an example of supra self-assembly with a multiple-layered vesicle surrounding an interior cubic microphase. This is challenging to resolve. DSC shows the presence of different kinds of water bound to the lipid aggregates as a function of the lipid content. Comparison with the effect of lithium, sodium, and calcium salts on the structural parameters of the sphingomyelin and the morphologies of brain lipid extract morphologies demonstrate that lithium has remarkable effects also at low content.


  • Centre for Analysis and Synthesis
  • Physical Chemistry
  • NanoLund: Center for Nanoscience

Publishing year





Frontiers in cell and developmental biology



Document type

Journal article


Frontiers Media S. A.


  • Physical Chemistry


  • brain lipid
  • cholesterol
  • cryo-TEM
  • specific ion effects
  • sphingomyelin
  • structure and morphology
  • X-ray diffraction




  • ISSN: 2296-634X