About

Dr. Steven Graham Adie is an Associate Professor at the Meinig School of Biomedical Engineering at Cornell University, where he is based in Weill Hall, Room 113. He joined Cornell in 2013 after completing a postdoctoral fellowship at the Beckman Institute for Advanced Science and Technology at the University of Illinois at Urbana-Champaign. His postdoctoral research focused on optical coherence tomography (OCT), including computational image formation, dynamic optical coherence elastography (OCE), and translational OCT research for image-guided surgery in breast cancer. Dr. Adie earned his Ph.D. in Electrical and Electronic Engineering from The University of Western Australia. Prior to his academic career, he worked in the R&D division of a startup developing solid-state laser systems for LASIK eye surgery. His research program centers on the development and application of OCT-based imaging for both basic science investigations and clinical applications. OCT is an imaging modality capable of 3D label-free imaging of tissue structure and function in vivo, functioning as the optical analogue of ultrasound with higher resolution. In his lab, Dr. Adie develops OCT instrumentation and imaging techniques to optimize resolution and contrast, including methods for optical coherence elastography to image tissue mechanical properties. His work explores new image formation paradigms for cellular-resolution volumetric OCT, leveraging computational approaches that combine the advantages of digital holography and confocal microscopy. His research aims to better understand disease development and progression, particularly the role of mechanical properties in carcinogenesis, through multidisciplinary collaborations. Additionally, Dr. Adie focuses on translating OCT's non-invasive, label-free imaging capabilities into clinical settings by designing portable systems and testing image-based biomarkers for disease diagnosis and treatment monitoring.

Research topics

• Optics
• Computer science
• Medicine
• Materials science
• Physics

Selected publications

• Ultradeep optical coherence tomography in scattering media

  2026-03-05

  articleSenior author
  PublisherDOI

• Valve endothelial monolayer fissuring and interstitial matrix fracture triggers calcific lesion formation via GTPase signaling

  Acta Biomaterialia · 2026-02-27

  articleOpen access
  PublisherOA PDFDOI

• Simple calibration procedure for spectrometer matching in balanced detection spectral domain optical coherence tomography

  2026-03-05

  articleSenior author
  PublisherDOI

• Enhanced deep tissue imaging using long wavelength conjugate spectral domain OCT with balanced detection

  2025-04-03

  articleSenior author

  Deep tissue imaging is achieved with a long-wavelength conjugate SD-OCT (Spectral-Domain Optical Coherence Tomography) combined with balanced detection. The use of long wavelength and conjugate configuration serves to reduce scattering and counteract spectrometer roll off, respectively, in SD-OCT, thereby enhancing imaging depth. A 1550nm OCT system is designed with the use of supercontinuum source (SuperK FIANIUM FIU-6 OCT) and Cobra 1600 spectrometer with bandwidth 1450-1690 nm. Balanced detection is employed to mitigate the excess noise associated with the supercontinuum source and to minimize the autocorrelation noise artefacts. This advanced technique leveraging long wavelength and BD in conjugate SD-OCT has allowed us to achieve optical imaging depths exceeding 4 mm in chicken breast tissue and scotch tape.

  PublisherDOI

• Study of ventricular morphogenesis and cardiac dynamics in a live chick embryonic heart slice

  2025-03-19

  articleSenior author

  Defects in trabecular development are associated with congenital heart disease and cardiomyopathies. However, a full understanding of trabecular development and their function in ventricular morphogenesis remains elusive. Cardiac dynamics and development were studied in a live, chick embryo, heart slice that preserves beats and contractility for >24 hours. High-resolution, longitudinal imaging of the trabeculated and compact myocardium was performed with a combined Optical Coherence Microscopy (OCM), and confocal microscopy platform. Three dimensional volumes over multiple cardiac phases of the beating heart slice were reconstructed from BM-mode OCM acquisitions of the beating heart slices. The feasibility of performing structural and functional cellular tracking of trabecular growth was also explored by combining OCM with confocal fluorescence imaging. Longitudinal imaging was performed every 2 hours over 24 hours to track growth. High-resolution examination of trabecular structure and growth could be performed by the use of this live-slice culture and combined imaging approach.

  PublisherDOI

• Valve endothelial monolayer fissuring via RhoA activity induces 3D calcific aortic valve lesion emergence as revealed by a longitudinal live-imaging platform

  bioRxiv (Cold Spring Harbor Laboratory) · 2025-06-27

  preprintOpen access

  Calcific aortic valve disease (CAVD) is a degenerative disease with wide prevalence in the aging population and a low survival rate after onset of symptoms, yet there are no effective pharmacological treatments. Many patients present to the clinic with symptoms at end-stages of CAVD, when the disease may be irreversible. The ability to identify and live-trace calcific lesion emergence in-vivo would allow for the identification of disease biomarkers and discovery of therapeutic targets at earlier, more treatable stages. In this work, we establish a new multimodal in-vitro CAVD platform consisting of lineage traced-VEC and VIC cells in a 3D model combined with live optical coherence and fluorescence microscopy to unravel VEC, VIC, and matrix transitional events during calcific lesion formation. We discover that fissuring of the endothelial monolayer combined with the formation of dense aggregates in adjacent regions is a key biomarker of the onset of lesion formation. This coincides with the formation of dense VIC and ECM conglomerates under endothelial aggregates, an additional biomarker of pathogenesis. Further, we discover that fibrotic tissue compaction is correlated with but not necessary for lesion formation. Additionally, we identify RhoA activation in disease-treated samples. We demonstrate that RhoA inhibition through ROCK, but not Rac1 inhibition, prevents delamination of the endothelial monolayer, fibrotic remodeling, and emergence of calcific lesions. Together, this work establishes a new longitudinal live-imaging platform that identifies emergent cell and matrix biological signatures of CAVD onset and enables the evaluation of therapeutic interventions.

  PublisherOA PDFDOI

• Dual spectrometer-based ultra-broadband spectral domain optical coherence tomography at 1450nm

  2025-03-19

  articleSenior author

  Imaging deep in scattering samples with high resolution is potentially useful in a wide range of biomedical applications. In order to accomplish this, we utilize two off-the-shelf spectrometers centered at ~1300 nm and ~1550 nm along with a simple fiber-based interferometer and a supercontinuum source to synthesize an effective bandwidth of ~400 nm centered at ~1450 nm. A portion of the spectrum was missing and was filled-in using the gapped-data amplitude and phase estimation method. The axial resolution when using only the 1300 nm or 1550 nm spectrometer was 10.3 μm or 14.8 μm respectively, while the combined spectra yielded a 5.4 μm resolution in air while still maintaining a ~3.5 mm imaging range.

  PublisherDOI

• Combined optical coherence microscopy and confocal microscopy of a 3D, co-culture model of aortic valve calcification

  2024-03-13

  articleSenior author

  Longitudinal imaging of a 3D model of calcific aortic valve disease, which consisted of co-cultured GFP+ Valve Endothelial Cells (VEC) and Valve Interstitial Cells (VIC), was performed with a combined Optical Coherence Microscopy (OCM), confocal reflectance and fluorescence microscopy system. The acquired confocal volumes depicted the VEC morphological changes and migration as well as collagen fiber alignment. With the aid of computational refocusing and multi-volume processing, the OCM datasets could visualize VIC cell bodies, matrix remodeling, nodule formation and calcific deposits. The complementary information derived using this combined approach could help unravel the cellular mechanisms leading to aortic valve calcification.

  PublisherDOI

• Imaging of tumor spheroids embedded in a collagen matrix with a combined optical coherence microscopy and confocal microscopy system

  2024-03-13

  articleSenior author

  A combined 1300 nm Optical Coherence Microscopy (OCM) and 488 nm confocal reflectance/ fluorescence microscopy system was designed to perform high-resolution, high-specificity imaging of collagen-embedded spheroids. Spheroids of Hyaluronic Acid (HA) synthase-overexpressing breast epithelial cells alone, or co-cultured with adipose stromal cells were imaged. The volumes, acquired either after fixing and staining or longitudinally with labeling, enabled the visualization of the spheroid morphology, luminal structures, cellular organization, and collagen matrix remodeling. The morphology and internal lumen structures of spheroids, as large as 500 μm in diameter, could be obtained from the OCM volumes, even in the presence of dense collagen matrix surrounding the spheroids. The confocal stacks provided superior specificity to discriminate cells from the compacted collagen along the spheroid’s periphery, up to a depth of ~120 μm. The combined use of OCM and confocal imaging on these spheroid models has added to our understanding of how HA may contribute to tumor initiation and invasion.

  PublisherDOI

• Extended Imaging Depth via Long-wavelength Conjugate Spectral-domain OCT

  2024-01-01

  articleSenior author

  This article presents ultra-deep imaging in spectral domain OCT based on a combination of long-wavelength super-continuum source and conjugate configuration. Using this technique, we demonstrate deep tissue imaging up to 5.1mm optical depth in chicken breast tissue.

  PublisherDOI

Recent grants

• Volumetric Traction Force Tomography of Collective Cell Migration Dynamics

  NIH · $434k · 2016–2019

• Volumetric time-lapse imaging of biophysical cell-extracellular matrix interactions for systems mechanobiology research

  NIH · $1.7M · 2019–2024

• THREE-DIMENSIONAL MECHANO-MICROSCOPY OF THE STEM CELL NICHE

  NIH · $611k · 2018–2021

• CAREER: Hybrid adaptive optics: a new paradigm for faster, deeper, volumetric microscopy in scattering media

  NSF · $500k · 2018–2023

• Development of Hybrid Adaptive Optics for Multimodal Microscopy Deep in the Mouse Brain

  NIH · $491k · 2017–2020

Frequent coauthors

• SA Boppart

  Diagnostic Photonics (United States)

  74 shared

• KA Cradock

  Carle Foundation Hospital

  74 shared

• Stephen A. Boppart

  University of Illinois System

  68 shared

• PS Carney

  Carle Foundation Hospital

  65 shared

• DT McCormick

  University of Illinois Urbana-Champaign

  65 shared

• LK Jacobs

  Diagnostic Photonics (United States)

  49 shared

• DA Darga

  University of Illinois System

  49 shared

• Partha Ray

  49 shared

Education

• PhD, School of Electrical, Electronic and Computer Engineering

  University of Western Australia

  2007

• Bachelor of Science (Hons), Chemical Physics

  University of Western Australia

  1997