Your search keyword '"Ahmet Can Solak"' showing total 7 results

1. Democratising deep learning for microscopy with ZeroCostDL4Mic

Author

Lucas von Chamier, Romain F. Laine, Johanna Jukkala, Christoph Spahn, Daniel Krentzel, Elias Nehme, Martina Lerche, Sara Hernández-Pérez, Pieta K. Mattila, Eleni Karinou, Séamus Holden, Ahmet Can Solak, Alexander Krull, Tim-Oliver Buchholz, Martin L. Jones, Loïc A. Royer, Christophe Leterrier, Yoav Shechtman, Florian Jug, Mike Heilemann, Guillaume Jacquemet, and Ricardo Henriques

Subjects

Science

Abstract

Deep learning methods show great promise for the analysis of microscopy images but there is currently an accessibility barrier to many users. Here the authors report a convenient entry-level deep learning platform that can be used at no cost: ZeroCostDL4Mic.

Published

2021

2. Zebrahub – Multimodal Zebrafish Developmental Atlas Reveals the State Transition Dynamics of Late Vertebrate Pluripotent Axial Progenitors

Author

Merlin Lange, Alejandro Granados, Shruthi VijayKumar, Jordao Bragantini, Sarah Ancheta, Sreejith Santhosh, Michael Borja, Hirofumi Kobayashi, Erin McGeever, Ahmet Can Solak, Bin Yang, Xiang Zhao, Yang Liu, Angela Detweiler, Sheryl Paul, Honey Mekonen, Tiger Lao, Rachel Banks, Adrian Jacobo, Keir Balla, Kyle Awayan, Samuel D’Souza, Robert Haase, Alexandre Dizeux, Olivier Pourquie, Rafael Gómez-Sjöberg, Greg Huber, Mattia Serra, Norma Neff, Angela Oliveira Pisco, and Loïc A. Royer

Abstract

Elucidating the developmental process of an organism will require the complete cartography of cellular lineages in the spatial, temporal, and molecular domains. We present Zebrahub, a comprehensive dynamic atlas of zebrafish embryonic development that combines single-cell sequencing time course data with light-sheet microscopy-based lineage reconstructions. Zebrahub is a foundational resource to study developmental processes at both transcriptional and spatiotemporal levels. It is publicly accessible as a web-based resource, providing an open-access collection of datasets and tools. Using this resource we shed new light on the pluripotency of Neuro-Mesodermal Progenitors (NMPs). We find that NMPs are pluripotent only during early axis elongation before becoming exclusively mesodermal progenitors. We attribute this restriction in NMP cell fate to emerging morphodynamic features that compartmentalize tissue motion.

Published

2023

3. DaXi—high-resolution, large imaging volume and multi-view single-objective light-sheet microscopy

Author

Bin Yang, Merlin Lange, Alfred Millett-Sikking, Xiang Zhao, Jordão Bragantini, Shruthi VijayKumar, Mason Kamb, Rafael Gómez-Sjöberg, Ahmet Can Solak, Wanpeng Wang, Hirofumi Kobayashi, Matthew N. McCarroll, Lachlan W. Whitehead, Reto P. Fiolka, Thomas B. Kornberg, Andrew G. York, and Loic A. Royer

Subjects

Cell Biology, Molecular Biology, Biochemistry, Biotechnology

Abstract

The promise of single-objective light-sheet microscopy is to combine the convenience of standard single-objective microscopes with the speed, coverage, resolution and gentleness of light-sheet microscopes. We present DaXi, a single-objective light-sheet microscope design based on oblique plane illumination that achieves: (1) a wider field of view and high-resolution imaging via a custom remote focusing objective; (2) fast volumetric imaging over larger volumes without compromising image quality or necessitating tiled acquisition; (3) fuller image coverage for large samples via multi-view imaging and (4) higher throughput multi-well imaging via remote coverslip placement. Our instrument achieves a resolution of 450 nm laterally and 2 μm axially over an imaging volume of 3,000 × 800 × 300 μm. We demonstrate the speed, field of view, resolution and versatility of our instrument by imaging various systems, including Drosophila egg chamber development, zebrafish whole-brain activity and zebrafish embryonic development – up to nine embryos at a time.

Published

2022

4. ortho_seqs: A Python tool for sequence analysis and higher order sequence–phenotype mapping

Author

Saba Nafees, Venkata Naga Pranathi Vemuri, Miles Woollacott, Ahmet Can Solak, Phoenix Logan, Aaron McGeever, Olivia Yoo, and Sean H. Rice

Abstract

MotivationAn important goal in sequence analysis is to understand how parts of DNA, RNA, or protein sequences interact with each other and to predict how these interactions result in given phenotypes. Mapping phenotypes onto underlying sequence space at first- and higher order levels in order to independently quantify the impact of given nucleotides or residues along a sequence is critical to understanding sequence–phenotype relationships.ResultsWe developed a Python software tool, ortho_seqs, that quantifies higher order sequence-phenotype interactions based on our previously published method of applying multivariate tensor-based orthogonal polynomials to biological sequences. Using this method, nucleotide or amino acid sequence information is converted to vectors, which are then used to build and compute the first- and higher order tensor-based orthogonal polynomials. We derived a more complete version of the mathematical method that includes projections that not only quantify effects of given nucleotides at a particular site, but also identify the effects of nucleotide substitutions. We show proof of concept of this method, provide a use case example as applied to synthetic antibody sequences, and demonstrate the application of ortho_seqs to other other sequence–phenotype datasets.Availabilityhttps://github.com/snafees/ortho_seqs & documentation https://ortho-seqs.readthedocs.io/

Published

2022

5. Democratising deep learning for microscopy with ZeroCostDL4Mic

Author

Pieta K. Mattila, Lucas von Chamier, Yoav Shechtman, Elias Nehme, Guillaume Jacquemet, Johanna Jukkala, Alexander Krull, Daniel Krentzel, Loic Royer, Tim-Oliver Buchholz, Mike Heilemann, Christophe Leterrier, Martina Lerche, Romain F. Laine, Ricardo Henriques, Florian Jug, Sara Hernández-Pérez, Martin L. Jones, Eleni Karinou, Ahmet Can Solak, Christoph Spahn, Seamus Holden, University College of London [London] (UCL), University of Turku, Åbo Akademi University [Turku], Goethe-University Frankfurt am Main, Imperial College London, Technion - Israel Institute of Technology [Haifa], Newcastle University [Newcastle], Chan Zuckerberg BioHub [San Francisco, CA], Max Planck Institute for Molecular Biomedicine, Max-Planck-Gesellschaft, Max Planck Institute for Physics, Center for Systems Biology Dresden (CSBD), Technische Universität Dresden = Dresden University of Technology (TU Dresden)-Max Planck Society, The Francis Crick Institute [London], Institut de neurophysiopathologie (INP), and Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS)

Subjects

0301 basic medicine, Computer science, Science, [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Primary Cell Culture, Datasets as Topic, General Physics and Astronomy, Image processing, Cloud computing, Cellular imaging, Machine learning, computer.software_genre, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Deep Learning, 0302 clinical medicine, Software, Cell Line, Tumor, Image Processing, Computer-Assisted, Animals, Humans, FNET, Microscopy, Multidisciplinary, business.industry, Deep learning, General Chemistry, Cloud Computing, Object detection, Rats, 030104 developmental biology, Key (cryptography), Artificial intelligence, business, computer, 030217 neurology & neurosurgery, Coding (social sciences)

Abstract

Deep Learning (DL) methods are powerful analytical tools for microscopy and can outperform conventional image processing pipelines. Despite the enthusiasm and innovations fuelled by DL technology, the need to access powerful and compatible resources to train DL networks leads to an accessibility barrier that novice users often find difficult to overcome. Here, we present ZeroCostDL4Mic, an entry-level platform simplifying DL access by leveraging the free, cloud-based computational resources of Google Colab. ZeroCostDL4Mic allows researchers with no coding expertise to train and apply key DL networks to perform tasks including segmentation (using U-Net and StarDist), object detection (using YOLOv2), denoising (using CARE and Noise2Void), super-resolution microscopy (using Deep-STORM), and image-to-image translation (using Label-free prediction - fnet, pix2pix and CycleGAN). Importantly, we provide suitable quantitative tools for each network to evaluate model performance, allowing model optimisation. We demonstrate the application of the platform to study multiple biological processes., Deep learning methods show great promise for the analysis of microscopy images but there is currently an accessibility barrier to many users. Here the authors report a convenient entry-level deep learning platform that can be used at no cost: ZeroCostDL4Mic.

Published

2021

6. DaXi-high-resolution, large imaging volume and multi-view single-objective light-sheet microscopy

Author

Bin, Yang, Merlin, Lange, Alfred, Millett-Sikking, Xiang, Zhao, Jordão, Bragantini, Shruthi, VijayKumar, Mason, Kamb, Rafael, Gómez-Sjöberg, Ahmet Can, Solak, Wanpeng, Wang, Hirofumi, Kobayashi, Matthew N, McCarroll, Lachlan W, Whitehead, Reto P, Fiolka, Thomas B, Kornberg, Andrew G, York, and Loic A, Royer

Subjects

Microscopy, Fluorescence, Animals, Brain, Embryonic Development, Drosophila, Zebrafish

Abstract

The promise of single-objective light-sheet microscopy is to combine the convenience of standard single-objective microscopes with the speed, coverage, resolution and gentleness of light-sheet microscopes. We present DaXi, a single-objective light-sheet microscope design based on oblique plane illumination that achieves: (1) a wider field of view and high-resolution imaging via a custom remote focusing objective; (2) fast volumetric imaging over larger volumes without compromising image quality or necessitating tiled acquisition; (3) fuller image coverage for large samples via multi-view imaging and (4) higher throughput multi-well imaging via remote coverslip placement. Our instrument achieves a resolution of 450 nm laterally and 2 μm axially over an imaging volume of 3,000 × 800 × 300 μm. We demonstrate the speed, field of view, resolution and versatility of our instrument by imaging various systems, including Drosophila egg chamber development, zebrafish whole-brain activity and zebrafish embryonic development - up to nine embryos at a time.

Published

2021

7. ZeroCostDL4Mic: an open platform to use Deep-Learning in Microscopy

Author

Elias Nehme, Martina Lerche, Guillaume Jacquemet, Mike Heilemann, Martin L. Jones, Eleni Karinou, Sara Hernández-Pérez, Alexander Krull, Yoav Shechtman, Chamier Lv, Ricardo Henriques, Florian Jug, Tim-Oliver Buchholz, Daniel Krentzel, Loic Royer, Christophe Leterrier, Christoph Spahn, Pieta K. Mattila, Johanna Jukkala, Seamus Holden, Romain F. Laine, and Ahmet Can Solak

Subjects

0303 health sciences, Open platform, Multimedia, Computer science, business.industry, Deep learning, Cloud computing, computer.software_genre, 03 medical and health sciences, 0302 clinical medicine, Microscopy, Key (cryptography), Segmentation, Artificial intelligence, business, computer, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The resources and expertise needed to use Deep Learning (DL) in bioimaging remain significant barriers for most laboratories. We present https://github.com/HenriquesLab/ZeroCostDL4Mic/wiki, a platform simplifying access to DL by exploiting the free, cloud-based computational resources of Google Colab. https://github.com/HenriquesLab/ZeroCostDL4Mic/wiki allows researchers to train, evaluate, and apply key DL networks to perform tasks including segmentation, detection, denoising, restoration, resolution enhancement and image-to-image translation. We demonstrate the application of the platform to study multiple biological processes.

Published

2020