Integrated automated particle tracking microfluidic enables high‐throughput cell deformability cytometry for red cell disorders

Guruprasad, Puneeth; Mannino, Robert G.; Caruso, Christina M.; Zhang, Hanqing; Josephson, Cassandra D.; Roback, John D.; Lam, Wilbur A.

doi:10.1002/ajh.25345

Cited by 29 publications

(30 citation statements)

References 55 publications

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“…In the initial period of studying the effect of cold-storage on the deformability of PRBCs was carried out using the filtration method (Kucera et al, 1985;Wegner and Kucera, 1989) and ektacytometry (Cluitmans et al, 2012;Sosa et al, 2014;Marin et al, 2021;van Cromvoirt et al, 2021). In the last decade, measurements with a flow chamber (Relevy et al, 2008;Barshtein et al, 2014Barshtein et al, , 2020bOrbach et al, 2017) or microfluidic systems (Guruprasad et al, 2019;Islamzada et al, 2020;Man et al, 2020) have become more frequently used.…”

Section: Cold Storage Of Rbcs and Cell Deformabilitymentioning

confidence: 99%

“…Research directly targeting unit-to-unit variations in PRBCs deformability has only recently been initiated, with several authors have demonstrated the significance of this phenomenon (Frank et al, 2013;Matthews et al, 2015;Guruprasad et al, 2019;Jeon et al, 2019;Barshtein et al, 2020b;Islamzada et al, 2020;van Cromvoirt et al, 2021). It was found that two factors primarily cause variability among units: the difference in the initial properties of donated RBCs and the differing ability of the cells to retain their deformability during storage (Barshtein et al, 2020b;Islamzada et al, 2020).…”

Section: Unit-to-unit Variability Of Rbc Deformabilitymentioning

confidence: 99%

“…As mentioned above, research in this area began in the mid-1980s. At present, with the advent of new approaches (microfluidics) which enable us to determine the distribution of deformability in the cell population (Relevy et al, 2008;Guruprasad et al, 2019;Barshtein et al, 2020b;Islamzada et al, 2020;Man et al, 2020), the scientific interest in this field has increased. This led to an increase in the number of research groups working in this area.…”

Section: Futures Perspectivesmentioning

confidence: 99%

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Deformability of Stored Red Blood Cells

2021

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Red blood cells (RBCs) deformability refers to the cells’ ability to adapt their shape to the dynamically changing flow conditions so as to minimize their resistance to flow. The high red cell deformability enables it to pass through small blood vessels and significantly determines erythrocyte survival. Under normal physiological states, the RBCs are attuned to allow for adequate blood flow. However, rigid erythrocytes can disrupt the perfusion of peripheral tissues and directly block microvessels. Therefore, RBC deformability has been recognized as a sensitive indicator of RBC functionality. The loss of deformability, which a change in the cell shape can cause, modification of cell membrane or a shift in cytosol composition, can occur due to various pathological conditions or as a part of normal RBC aging (in vitro or in vivo). However, despite extensive research, we still do not fully understand the processes leading to increased cell rigidity under cold storage conditions in a blood bank (in vitro aging), In the present review, we discuss publications that examined the effect of RBCs’ cold storage on their deformability and the biological mechanisms governing this change. We first discuss the change in the deformability of cells during their cold storage. After that, we consider storage-related alterations in RBCs features, which can lead to impaired cell deformation. Finally, we attempt to trace a causal relationship between the observed phenomena and offer recommendations for improving the functionality of stored cells.

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Section: Cold Storage Of Rbcs and Cell Deformabilitymentioning

confidence: 99%

Section: Unit-to-unit Variability Of Rbc Deformabilitymentioning

confidence: 99%

Section: Futures Perspectivesmentioning

confidence: 99%

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Deformability of Stored Red Blood Cells

2021

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“…As such, blood cannot be treated as a simple continuum, and it is important to consider the stiffness and size of single blood cells. In the smallest capillaries, RBCs must deform to pass, so changes in microvasculature function and transport occur due to increases in RBC stiffness or adhesion, which is common in many cases, including sickle cell disease ( 16 , 17 ), malaria ( 18 , 19 ), or even various intravenous fluids ( 16 ). Adding to this complexity, the shear ( 20 ) and oxygen levels ( 21 ) in the local microenvironment also affect RBC adhesiveness.…”

Section: The Biology Biophysics and Pathology Of The Microvasculaturementioning

confidence: 99%

Vascularized Microfluidics and Their Untapped Potential for Discovery in Diseases of the Microvasculature

Myers

Lam

2021

Annu. Rev. Biomed. Eng.

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Microengineering advances have enabled the development of perfusable, endothelialized models of the microvasculature that recapitulate the unique biological and biophysical conditions of the microcirculation in vivo. Indeed, at that size scale (<100 μm)—where blood no longer behaves as a simple continuum fluid; blood cells approximate the size of the vessels themselves; and complex interactions among blood cells, plasma molecules, and the endothelium constantly ensue—vascularized microfluidics are ideal tools to investigate these microvascular phenomena. Moreover, perfusable, endothelialized microfluidics offer unique opportunities for investigating microvascular diseases by enabling systematic dissection of both the blood and vascular components of the pathophysiology at hand. We review ( a) the state of the art in microvascular devices and ( b) the myriad of microvascular diseases and pressing challenges. The engineering community has unique opportunities to innovate with new microvascular devices and to partner with biomedical researchers to usher in a new era of understanding and discovery of microvascular diseases. Expected final online publication date for the Annual Review of Biomedical Engineering, Volume 23 is June 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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“…3 RBC disorders such as sickle cell disease are also associated with increasing cell stiffness -an approximately threefold increase in membrane shear modulus 4 -and a broadening of the cell size distribution. 5 RBCs are examples of natural capsules consisting of a fluid core encapsulated by a semi-permeable membrane. 6 In fact, the transport and flow-induced deformation of RBCs and other biological cells are commonly modelled with idealised capsules and soft beads.…”

Section: Introductionmentioning

confidence: 99%