# Publications **Please include the following acknowledgement in any publications utilizing HCBI resources:** **"We thank the Harvard Center for Biological Imaging (RRID:SCR\_018673) for infrastructure and support."** *Have you published a paper that used the HCBI? Let us know by filling out our* [*publication form*](https://forms.office.com/Pages/ResponsePage.aspx?id=9CL6b2hFBUGtQy461HJpVxqZ_Z1hoxpGiSmD-uduvAVUOFpXRU8xMDZDRzMzRVEwT0hRNVkxSE5aMCQlQCN0PWcu) Search Within Results Search Within Results search ## 311 results Show filters filter\_alt Sort by Year of PublicationAlphabetical A-Z sort ## 311 results Download 311 citations download- [BibTeX](/node/1910786/export?format=bibtex) - [EndNote X3 XML](/node/1910786/export?format=endnote8) - [EndNote 7 XML](/node/1910786/export?format=endnote7) - [Endnote tagged](/node/1910786/export?format=tagged) - [Marc](/node/1910786/export?format=marc) - [PubMedId](/node/1910786/export?format=pubmed_id) - [RIS](/node/1910786/export?format=ris) ### 2026 Chao Y-K, Wu M, Gong Q, Chen F. [A genetically encoded device for transcriptome storage in mammalian cells](/publication/genetically-encoded-device-transcriptome-storage-mammalian-cells). American Association for the Advancement of Science; 2026. p. eadz9353. Chao Y-K, Wu M, Gong Q, Chen F. [A genetically encoded device for transcriptome storage in mammalian cells](/publication/genetically-encoded-device-transcriptome-storage-mammalian-cells). American Association for the Advancement of Science; 2026. p. eadz9353. - add\_circle\_outline do\_not\_disturb\_on Abstract Understanding how cells make decisions over time requires the ability to link past molecular states to future phenotypic outcomes. We present TimeVault, a genetically encoded system that records and stores transcriptomes within living mammalian cells for... Herrera KJ, Zarghani-Shiraz A, Ahrens MB, Engert F, Fishman MC. [Synchronization of behavioral and cardiac dynamics in larval zebrafish](/publication/synchronization-behavioral-and-cardiac-dynamics-larval-zebrafish). Elsevier; 2026. Herrera KJ, Zarghani-Shiraz A, Ahrens MB, Engert F, Fishman MC. [Synchronization of behavioral and cardiac dynamics in larval zebrafish](/publication/synchronization-behavioral-and-cardiac-dynamics-larval-zebrafish). Elsevier; 2026. Manandhar A, Rockwell FE, Watson N, Graham A, Holbrook NM. [Visualizing physical interactions between guard and epidermal cells during light-induced stomatal opening in 2 angiosperms](/publication/visualizing-physical-interactions-between-guard-and-epidermal-cells-during-light). 2026. p. kiaf644. Manandhar A, Rockwell FE, Watson N, Graham A, Holbrook NM. [Visualizing physical interactions between guard and epidermal cells during light-induced stomatal opening in 2 angiosperms](/publication/visualizing-physical-interactions-between-guard-and-epidermal-cells-during-light). 2026. p. kiaf644. - add\_circle\_outline do\_not\_disturb\_on Abstract Stomatal function results from structural movements of guard cells in which an increase in their volume opens the pore, while a decrease in volume closes the pore. In angiosperms, neighboring epidermal cells are described as having a mechanical advantage... Mapalo MA, Ghosh S, Gavrilov EA, Smith FW, Ortega-Hernandez J. [‘tail’ as old as time: insights into tardigrade posterior trunk development \\textbar Zoological Journal of the Linnean Society \\textbar Oxford Academic](/publication/tail-old-time-insights-tardigrade-posterior-trunk-development-textbar-zoological-0). 2026. Mapalo MA, Ghosh S, Gavrilov EA, Smith FW, Ortega-Hernandez J. [‘tail’ as old as time: insights into tardigrade posterior trunk development \\textbar Zoological Journal of the Linnean Society \\textbar Oxford Academic](/publication/tail-old-time-insights-tardigrade-posterior-trunk-development-textbar-zoological-0). 2026. Rizzo R, Sampon T, Wilt JK, Stankey PP, Lewis JA. [Embedding Perfusable Microchannel Networks in Photoclickable Bioresins via High-Resolution Digital Light Processing](/publication/embedding-perfusable-microchannel-networks-photoclickable-bioresins-high-resolution-1). 2026. p. e02466. Rizzo R, Sampon T, Wilt JK, Stankey PP, Lewis JA. [Embedding Perfusable Microchannel Networks in Photoclickable Bioresins via High-Resolution Digital Light Processing](/publication/embedding-perfusable-microchannel-networks-photoclickable-bioresins-high-resolution-1). 2026. p. e02466. - add\_circle\_outline do\_not\_disturb\_on Abstract Light-mediated 3D bioprinting methods hold great promise for the generation of biomimetic microvasculature networks for applications ranging from organ-on-chip models to vascularized tissue constructs. While printing microvascular channels (≤100 µm in... Scott-Solomon E, Brielle S, Mann AO, Khoury MJ, Peng J, Tellez L, Harrigan M, Ziogas M, Pasolli A, Cassandras M, et al. [Stress-induced sympathetic hyperactivation drives hair follicle necrosis to trigger autoimmunity](/publication/stress-induced-sympathetic-hyperactivation-drives-hair-follicle-necrosis-trigger). Elsevier; 2026. pp. 252–271.e19. Scott-Solomon E, Brielle S, Mann AO, Khoury MJ, Peng J, Tellez L, Harrigan M, Ziogas M, Pasolli A, Cassandras M, et al. [Stress-induced sympathetic hyperactivation drives hair follicle necrosis to trigger autoimmunity](/publication/stress-induced-sympathetic-hyperactivation-drives-hair-follicle-necrosis-trigger). Elsevier; 2026. pp. 252–271.e19. Tam HT, Peng J, Freeman R, Shwartz Y, Brielle S, Garg S, Rahmayanti S, Crocker SJ, Coon D, Hsu Y-C. [Hyperinnervation inhibits organ-level regeneration in mammalian skin](/publication/hyperinnervation-inhibits-organ-level-regeneration-mammalian-skin). Elsevier; 2026. Tam HT, Peng J, Freeman R, Shwartz Y, Brielle S, Garg S, Rahmayanti S, Crocker SJ, Coon D, Hsu Y-C. [Hyperinnervation inhibits organ-level regeneration in mammalian skin](/publication/hyperinnervation-inhibits-organ-level-regeneration-mammalian-skin). Elsevier; 2026. van den Berg ML, Munting LP, Hanlin L, Yi I, Bailey J, Richardson DS, Zwang TJ, van Veluw SJ, Kozberg MG. [Neuropathological correlates of MRI-observed hypointense lesions in the APP23 mouse model of cerebral amyloid angiopathy](/publication/neuropathological-correlates-mri-observed-hypointense-lesions-app23-mouse-model). SAGE Publications Ltd STM; 2026. p. 0271678X261424057. van den Berg ML, Munting LP, Hanlin L, Yi I, Bailey J, Richardson DS, Zwang TJ, van Veluw SJ, Kozberg MG. [Neuropathological correlates of MRI-observed hypointense lesions in the APP23 mouse model of cerebral amyloid angiopathy](/publication/neuropathological-correlates-mri-observed-hypointense-lesions-app23-mouse-model). SAGE Publications Ltd STM; 2026. p. 0271678X261424057. - add\_circle\_outline do\_not\_disturb\_on Abstract Cerebral amyloid angiopathy (CAA) is a small vessel disease associated with hemorrhagic lesions including microbleeds and intracerebral hemorrhage. Growing evidence suggests vascular remodeling may be a critical step leading to CAA-related vessel rupture... Veeraraghavan P, Engmann AK, Hatch JJ, Itoh Y, Nguyen D, Addison T, Macklis JD. [Dynamic subtype- and context-specific subcellular RNA regulation in growth cones of developing neurons of the cerebral cortex](/publication/dynamic-subtype-and-context-specific-subcellular-rna-regulation-growth-cones-developing). Nature Publishing Group; 2026. pp. 581–591. Veeraraghavan P, Engmann AK, Hatch JJ, Itoh Y, Nguyen D, Addison T, Macklis JD. [Dynamic subtype- and context-specific subcellular RNA regulation in growth cones of developing neurons of the cerebral cortex](/publication/dynamic-subtype-and-context-specific-subcellular-rna-regulation-growth-cones-developing). Nature Publishing Group; 2026. pp. 581–591. - add\_circle\_outline do\_not\_disturb\_on Abstract Neurons of distinct subtypes compartmentalize subtype-specific function in part by differentially localizing and translating specific RNAs, but underlying mechanisms are not understood. Here we investigate messenger RNA localization and stability within... Villar PS, Jiang H, Shugaeva T, Berdan EL, Kulkarni A, Hiroi M, Masucci G, Reiter S, Lindahl E, Howard RJ, et al. [A sensory system for mating in octopus](/publication/sensory-system-mating-octopus). American Association for the Advancement of Science; 2026. pp. 96–101. Villar PS, Jiang H, Shugaeva T, Berdan EL, Kulkarni A, Hiroi M, Masucci G, Reiter S, Lindahl E, Howard RJ, et al. [A sensory system for mating in octopus](/publication/sensory-system-mating-octopus). American Association for the Advancement of Science; 2026. pp. 96–101. - add\_circle\_outline do\_not\_disturb\_on Abstract Sensory systems for mate recognition maintain species boundaries and influence diversification. Thus, uncovering how molecules and receptors evolve to mediate this critical function is essential to understanding biodiversity. Male octopuses use a... Yokomizo S, Maci M, Stafford AM, Miller MR, Perle SJ, Inagaki S, Takahashi S, Brown‐Harding H, Liang L, Lovely A, et al. [Transplantation of GABAergic Interneuron Progenitors Restores Cortical Circuit Function in an Alzheimer’s Disease Mouse Model](/publication/transplantation-gabaergic-interneuron-progenitors-restores-cortical-circuit-function). 2026. p. e11472. Yokomizo S, Maci M, Stafford AM, Miller MR, Perle SJ, Inagaki S, Takahashi S, Brown‐Harding H, Liang L, Lovely A, et al. [Transplantation of GABAergic Interneuron Progenitors Restores Cortical Circuit Function in an Alzheimer’s Disease Mouse Model](/publication/transplantation-gabaergic-interneuron-progenitors-restores-cortical-circuit-function). 2026. p. e11472. - add\_circle\_outline do\_not\_disturb\_on Abstract In addition to dementia, Alzheimer's patients suffer from sleep impairments and aberrations in sleep‐dependent brain rhythms. Deficits in inhibitory GABAergic interneuron function disrupt one of those rhythms, slow oscillation in particular, and actively... ### 2025 Sanduja P, Schmieder SS, Baddal B, Tian S, Velarde JJ, Lencer WI, Dong M, Wessels MR. [SLO co-opts host cell glycosphingolipids to access cholesterol-rich lipid rafts for enhanced pore formation and cytotoxicity](/publication/slo-co-opts-host-cell-glycosphingolipids-access-cholesterol-rich-lipid-rafts-enhanced). 20250121st ed. 2025. p. e0377724. Sanduja P, Schmieder SS, Baddal B, Tian S, Velarde JJ, Lencer WI, Dong M, Wessels MR. [SLO co-opts host cell glycosphingolipids to access cholesterol-rich lipid rafts for enhanced pore formation and cytotoxicity](/publication/slo-co-opts-host-cell-glycosphingolipids-access-cholesterol-rich-lipid-rafts-enhanced). 20250121st ed. 2025. p. e0377724. - add\_circle\_outline do\_not\_disturb\_on Abstract Streptolysin O (SLO) is a virulence determinant of group A Streptococcus (S. pyogenes), the agent of streptococcal sore throat and severe invasive infections. SLO is a member of a family of bacterial pore-forming toxins known as cholesterol-dependent... - Previous page chevron\_left - [1](?page=0 "Current page") - [2](?page=1 "Go to page 2") - [3](?page=2 "Go to page 3") - [ Last page 26 ](?page=25 "Go to last page") - [ Next page chevron\_right ](?page=1 "Go to next page")