Tarlykov 2005: Aires Resonator Improves Erythrocyte Deformability in Multiple Myeloma Blood
Laser diffractometry study measuring how an Aires resonator affects the rheological properties of red blood cells from patients with multiple myeloma — demonstrating measurable improvement across two exposure time windows.
Study Context
This study investigated whether an Aires resonator affects the biophysical properties of blood from patients with multiple myeloma (a plasma cell cancer affecting blood composition and erythrocyte rheology). Researcher: V.A. Tarlykov, St. Petersburg State University of Information Technologies, Mechanics and Optics (SPbSUITMO), 2005.
Multiple myeloma produces abnormal proteins (paraproteins) that coat red blood cells, reducing their deformability and increasing aggregation — worsening microcirculatory function. Testing the resonator on this clinically relevant pathological blood sample provides a meaningful signal in a model where deformability changes are measurable and clinically significant.
Measurement Method
Laser diffractometry (ektacytometry) was used — a gold-standard method for measuring erythrocyte deformability. A helium-neon (He-Ne) laser at wavelength λ=0.63μm was passed through a blood sample under controlled osmotic stress. The diffraction pattern produced by red blood cells reflects their shape and deformability:
- Normal, deformable erythrocytes produce an elongated (elliptical) diffraction pattern
- Rigid or damaged cells produce a more circular pattern
- The ratio of pattern dimensions (elongation index) quantifies deformability
Osmotic fragility was also measured: a cell’s resistance to lysis (rupture) as surrounding solution becomes hypotonic — reflecting membrane integrity and flexibility.
Experimental Design
Blood Source
Blood drawn from multiple myeloma patients (pathological samples with compromised erythrocyte rheology at baseline).
Resonator Placement
Aires resonator placed in proximity to blood samples. Two exposure time windows assessed independently.
Phase 1: Short Exposure (<15 minutes)
Measurable improvement in both osmotic fragility and elongation index (deformability).
Phase 2: Extended Exposure (up to 40 minutes)
Further improvement in rheological parameters, with the effect continuing to develop through the longer exposure window.
Results
Significance
Erythrocyte deformability is critical for oxygen delivery through narrow capillaries — red blood cells must deform to pass through vessels smaller than their diameter. In multiple myeloma, paraproteins stiffen cell membranes, reducing this capacity and impairing microcirculation. The finding that an Aires resonator measurably improves deformability in this pathological model suggests a biophysical mechanism by which the resonator may influence the colloidal and membranous properties of cells in proximity.
This study connects with the water conductivity research (Zenin 2002, 2013) in suggesting that the resonator’s fractal diffraction mechanism may coherently influence structured biological media, including both extracellular water and cell membranes.
Researcher: V.A. Tarlykov | Institution: St. Petersburg State University of Information Technologies, Mechanics and Optics (SPbSUITMO) | Year: 2005