Sickle cell disease (SCD), known in the homozygous form as sickle cell anemia, affects 1 in 50 African Americans with debilitating, chronic, crisis episodes and reduced life expectancy. SCD is an inherited blood disorder caused by a single point mutation in the beta-globin gene. Sickle hemoglobin (HbS) has the unique property of polymerizing when deoxygenated, triggering red blood cell (RBC) sickling and dehydration, leading to vaso-occlusion and impaired blood flow in capillaries and small vessels. The biochemistry of HbS polymerization in vitro is well understood. However, inside RBC, the mechanism of underlying changes in cell mechanics and adhesion properties resulting from HbS polymerization is poorly understood due to a lack of appropriate measurement methods and realistic models. Three research teams with complementary expertise in bio-photonics (lead by Peter So, MIT), in biomechanics and microfluidics (lead by Ming Dao, MIT), and in SCD treatment (lead by Gregory Kato, UPMC) will join force to develop technologies that can quantify RBC biomechanics during RBC sickling. While there are many factors contributing to vaso-occlusion, RBC biomechanics is known to play a key role. The development of a predictive vaso-occlusion model will deepen our understanding of SCD etiology on a system level allowing the development of more effective drugs and treatments. Toward these goals, our team will develop reflection mode quantitative phase microscopy and a 3-D dissipative particle dynamics (DPD) multi-scale model. These technologies together will allow us to quantify RBC rheological properties with unprecedented accuracy during sickling transition inside microfluidic devices with precisely controlled oxygenation level. We will further develop complementary phase microscopy based spectroscopic methods to quantify HbS oxygenation and polymerization states. Simultaneous measurement of changes in RBC shape and rheology with changes in HbS biochemical states should allow us to better understand how intracellular molecular level variations drive RBC biomechanics, a key factor in vaso-occlusion and SCD crisis. The power of this approach will be evaluated in pilot studies to elucidate the therapeutic mechanisms of hydroxyurea, the only FDA approved drug specifically for SCD, and Aes -103, a new drug under development. These studies will develop proof of principle that this platform could be utilized in screening new anti-sickling drugs. The UPMC sickle cell disease registry will provide a rich clinical database to annotate the patient specimens that will be analyzed by advanced RBC biomechanics assays. This will allow preliminary exploratory statistical correlation of clinical characteristics to the potential biomarkers derived from the biomechanics assays.

Public Health Relevance

Sickle cell disease (SCD) is an inherited blood disorder affecting 90,000 to 100,000 people in the United States alone. The sickle hemoglobin (HbS) causes the affected red blood cells to stiffen and twist, leading to occlusion of small blood vessels. Among other problems such as impaired vision and chest pains, patients with SCD are also at serious risk for strokes. Joining the strengths of three interdisciplinary research teams, with expertise in bio-photonics, biomechanics, and SCD treatment, this proposal advocates the development of novel imaging technologies and biomechanical models to quantify structural changes of red blood cell that is known to be an important parameter in understanding vaso-occlusion in SCD patients. The findings will help to improve diagnostics and to understand the mechanisms of leading drugs for SCD treatment.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL121386-03
Application #
9109004
Study Section
Enabling Bioanalytical and Imaging Technologies Study Section (EBIT)
Program Officer
Hanspal, Manjit
Project Start
2014-09-15
Project End
2017-06-30
Budget Start
2016-07-01
Budget End
2017-06-30
Support Year
3
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Massachusetts Institute of Technology
Department
Engineering (All Types)
Type
Biomed Engr/Col Engr/Engr Sta
DUNS #
001425594
City
Cambridge
State
MA
Country
United States
Zip Code
Ahmad, Azeem; Dubey, Vishesh; Singh, Vijay Raj et al. (2018) Quantitative phase microscopy of red blood cells during planar trapping and propulsion. Lab Chip 18:3025-3036
Wadduwage, Dushan N; Kay, Jennifer; Singh, Vijay Raj et al. (2018) Automated fluorescence intensity and gradient analysis enables detection of rare fluorescent mutant cells deep within the tissue of RaDR mice. Sci Rep 8:12108
Papageorgiou, Dimitrios P; Abidi, Sabia Z; Chang, Hung-Yu et al. (2018) Simultaneous polymerization and adhesion under hypoxia in sickle cell disease. Proc Natl Acad Sci U S A 115:9473-9478
Li, He; Yang, Jun; Chu, Trang T et al. (2018) Cytoskeleton Remodeling Induces Membrane Stiffness and Stability Changes of Maturing Reticulocytes. Biophys J 114:2014-2023
Jin, Di; Zhou, Renjie; Yaqoob, Zahid et al. (2018) Dynamic spatial filtering using a digital micromirror device for high-speed optical diffraction tomography. Opt Express 26:428-437
Hosseini, Poorya; Jin, Di; Yaqoob, Zahid et al. (2018) Single-shot dual-wavelength interferometric microscopy. Methods 136:35-39
Zhou, Renjie; Jin, Di; Hosseini, Poorya et al. (2017) Modeling the depth-sectioning effect in reflection-mode dynamic speckle-field interferometric microscopy. Opt Express 25:130-143
Kato, Gregory J; Steinberg, Martin H; Gladwin, Mark T (2017) Intravascular hemolysis and the pathophysiology of sickle cell disease. J Clin Invest 127:750-760
Wadduwage, Dushan N; Singh, Vijay Raj; Choi, Heejin et al. (2017) Near-common-path interferometer for imaging Fourier-transform spectroscopy in wide-field microscopy. Optica 4:546-556
Jacob, Seethal A; Novelli, Enrico M; Isenberg, Jeffrey S et al. (2017) Thrombospondin-1 gene polymorphism is associated with estimated pulmonary artery pressure in patients with sickle cell anemia. Am J Hematol 92:E31-E34

Showing the most recent 10 out of 31 publications