Kilian J. Druggan’s research while affiliated with Lehigh University and other places

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Publications (2)


Measuring the Effects of Cytokines on the Modification of Pericellular Rheology by Human Mesenchymal Stem Cells
  • Article

November 2021

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17 Reads

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3 Citations

ACS Biomaterials Science & Engineering

Maryam Daviran

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John A. McGlynn

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Jenna A. Catalano

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[...]

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Human mesenchymal stem cell-engineered length scale dependent rheology of the pericellular region measured with bi-disperse multiple particle tracking microrheology

December 2020

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10 Reads

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11 Citations

Acta Biomaterialia

Biological materials have length scale dependent structure enabling complex cell-material interactions and driving cellular processes. Synthetic biomaterials are designed to mimic aspects of these biological materials for applications including enhancing cell delivery during wound healing. To mimic native microenvironments, we must understand how cells manipulate their surroundings over several length scales. Our work characterizes length scale dependent rheology in a well-established 3D cell culture platform for human mesenchymal stem cells (hMSCs). hMSCs re-engineer their microenvironment through matrix metalloproteinase (MMP) secretions and cytoskeletal tension. Remodeling occurs across length scales: MMPs degrade cross-links on nanometer scales resulting in micrometer-sized paths that hMSCs migrate through, eventually resulting in bulk scaffold degradation. We use multiple particle tracking microrheology (MPT) and bi-disperse MPT to characterize hMSC-mediated length scale dependent pericellular remodeling. MPT measures particle Brownian motion to calculate rheological properties. We use MPT to measure larger length scales with 4.5 µm particles. Bi-disperse MPT simultaneously measures two different length scales (0.5 and 2.0 µm). We measure that hMSCs preferentially remodel larger length scales measured as a higher mobility of larger particles. We inhibit cytoskeletal tension by inhibiting myosin-II and no longer measure this difference in particle mobility. This indicates that cytoskeletal tension is the source of cell-mediated length scale dependent rheological changes. Particle mobility correlates with cell speed across length scales, relating material rheology to cell behavior. These results quantify length scale dependent pericellular remodeling and provide insight into how these microenvironments can be designed into materials to direct cell behavior.

Citations (2)


... [85] Besides, to confer the confounding mechanical input and for precise quantification of the force applied, together with atomic force microscopy, [86] video particle tracking microrheology was developed as well. Intracellular viscoelasticity [87] and the mechanical responses to external cytokines were depicted using such platform [88] during cell differentiation. Employing the tension sensor of Förster resonance energy transfer to define the force gradient [89] and further to the assessment at the single-molecule level [90] are advanced illustrations reflecting the industrial evolvement of experimental apparatus to analyze mechanotransduction. ...

Reference:

Mechanotransduction of Mesenchymal Stem Cells and Hemodynamic Implications
Measuring the Effects of Cytokines on the Modification of Pericellular Rheology by Human Mesenchymal Stem Cells
  • Citing Article
  • November 2021

ACS Biomaterials Science & Engineering

... Most hydrogels are crosslinked by peptides that are cleaved by soluble proteases that induce bulk hydrogel degradation. [6][7][8] The mechanical properties of hydrogels are important for cell behavior 9 and these properties are dependent on the extent of crosslinking between polymer chains. 6,10 While synthetic matrices are often treated as relatively inert scaffolds that can be modified with specific ligands or properties, the extent to which the encapsulated cells degrade the hydrogel network will alter the local network structure. ...

Human mesenchymal stem cell-engineered length scale dependent rheology of the pericellular region measured with bi-disperse multiple particle tracking microrheology
  • Citing Article
  • December 2020

Acta Biomaterialia