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1. Folate metabolism and risk of childhood acute lymphoblastic leukemia: a genetic pathway analysis from the Childhood Cancer and Leukemia International Consortium

Author

Metayer, Catherine, Spector, Logan G, Scheurer, Michael E, Jeon, Soyoung, Scott, Rodney J, Takagi, Masatoshi, Clavel, Jacqueline, Manabe, Atsushi, Ma, Xiaomei, Hailu, Elleni M, Lupo, Philip J, Urayama, Kevin Y, Bonaventure, Audrey, Kato, Motohiro, Meirhaeghe, Aline, Chiang, Charleston WK, Morimoto, Libby M, and Wiemels, Joseph L

Subjects
Epidemiology, Health Sciences, Hematology, Cancer, Human Genome, Genetics, Childhood Leukemia, Health Disparities, Minority Health, Rare Diseases, Pediatric, Pediatric Cancer, Clinical Research, 2.1 Biological and endogenous factors, Humans, Precursor Cell Lymphoblastic Leukemia-Lymphoma, Folic Acid, Polymorphism, Single Nucleotide, Child, Case-Control Studies, Female, Male, Genome-Wide Association Study, Risk Factors, Genetic Predisposition to Disease, Child, Preschool, Medical and Health Sciences, Biomedical and clinical sciences, Health sciences
Abstract

BackgroundPrenatal folate supplementation has been consistently associated with a reduced risk of childhood acute lymphoblastic leukemia (ALL). Previous germline genetic studies examining the one carbon (folate) metabolism pathway were limited in sample size, scope, and population diversity and led to inconclusive results.MethodsWe evaluated whether ∼2,900 single-nucleotide polymorphisms (SNP) within 46 candidate genes involved in the folate metabolism pathway influence the risk of childhood ALL, using genome-wide data from nine case-control studies in the Childhood Cancer and Leukemia International Consortium (n = 9,058 cases including 4,510 children of European ancestry, 3,018 Latinx, and 1,406 Asians, and 92,364 controls). Each study followed a standardized protocol for quality control and imputation of genome-wide data and summary statistics were meta-analyzed for all children combined and by major ancestry group using METAL software.ResultsNone of the selected SNPs reached statistical significance, overall and for major ancestry groups (using adjusted Bonferroni P-value of 5 × 10-6 and less-stringent P-value of 3.5 × 10-5 accounting for the number of "independent" SNPs). None of the 10 top (nonsignificant) SNPs and corresponding genes overlapped across ancestry groups.ConclusionsThis large meta-analysis of original data does not reveal associations between many common genetic variants in the folate metabolism pathway and childhood ALL in various ancestry groups.ImpactGenetic variants in the folate pathway alone do not appear to substantially influence childhood acute lymphoblastic leukemia risk. Other mechanisms such as gene-folate interaction, DNA methylation, or maternal genetic effects may explain the observed associations with self-reported prenatal folate intake.

Published
2024

2. Training of Physical Neural Networks

Author

Momeni, Ali, Rahmani, Babak, Scellier, Benjamin, Wright, Logan G., McMahon, Peter L., Wanjura, Clara C., Li, Yuhang, Skalli, Anas, Berloff, Natalia G., Onodera, Tatsuhiro, Oguz, Ilker, Morichetti, Francesco, del Hougne, Philipp, Gallo, Manuel Le, Sebastian, Abu, Mirhoseini, Azalia, Zhang, Cheng, Marković, Danijela, Brunner, Daniel, Moser, Christophe, Gigan, Sylvain, Marquardt, Florian, Ozcan, Aydogan, Grollier, Julie, Liu, Andrea J., Psaltis, Demetri, Alù, Andrea, and Fleury, Romain

Subjects
Physics - Applied Physics, Computer Science - Machine Learning
Abstract

Physical neural networks (PNNs) are a class of neural-like networks that leverage the properties of physical systems to perform computation. While PNNs are so far a niche research area with small-scale laboratory demonstrations, they are arguably one of the most underappreciated important opportunities in modern AI. Could we train AI models 1000x larger than current ones? Could we do this and also have them perform inference locally and privately on edge devices, such as smartphones or sensors? Research over the past few years has shown that the answer to all these questions is likely "yes, with enough research": PNNs could one day radically change what is possible and practical for AI systems. To do this will however require rethinking both how AI models work, and how they are trained - primarily by considering the problems through the constraints of the underlying hardware physics. To train PNNs at large scale, many methods including backpropagation-based and backpropagation-free approaches are now being explored. These methods have various trade-offs, and so far no method has been shown to scale to the same scale and performance as the backpropagation algorithm widely used in deep learning today. However, this is rapidly changing, and a diverse ecosystem of training techniques provides clues for how PNNs may one day be utilized to create both more efficient realizations of current-scale AI models, and to enable unprecedented-scale models., Comment: 29 pages, 4 figures

Published
2024

3. Scaling on-chip photonic neural processors using arbitrarily programmable wave propagation

Author

Onodera, Tatsuhiro, Stein, Martin M., Ash, Benjamin A., Sohoni, Mandar M., Bosch, Melissa, Yanagimoto, Ryotatsu, Jankowski, Marc, McKenna, Timothy P., Wang, Tianyu, Shvets, Gennady, Shcherbakov, Maxim R., Wright, Logan G., and McMahon, Peter L.

Subjects
Physics - Optics, Computer Science - Emerging Technologies, Computer Science - Machine Learning
Abstract

On-chip photonic processors for neural networks have potential benefits in both speed and energy efficiency but have not yet reached the scale at which they can outperform electronic processors. The dominant paradigm for designing on-chip photonics is to make networks of relatively bulky discrete components connected by one-dimensional waveguides. A far more compact alternative is to avoid explicitly defining any components and instead sculpt the continuous substrate of the photonic processor to directly perform the computation using waves freely propagating in two dimensions. We propose and demonstrate a device whose refractive index as a function of space, $n(x,z)$, can be rapidly reprogrammed, allowing arbitrary control over the wave propagation in the device. Our device, a 2D-programmable waveguide, combines photoconductive gain with the electro-optic effect to achieve massively parallel modulation of the refractive index of a slab waveguide, with an index modulation depth of $10^{-3}$ and approximately $10^4$ programmable degrees of freedom. We used a prototype device with a functional area of $12\,\text{mm}^2$ to perform neural-network inference with up to 49-dimensional input vectors in a single pass, achieving 96% accuracy on vowel classification and 86% accuracy on $7 \times 7$-pixel MNIST handwritten-digit classification. This is a scale beyond that of previous photonic chips relying on discrete components, illustrating the benefit of the continuous-waves paradigm. In principle, with large enough chip area, the reprogrammability of the device's refractive index distribution enables the reconfigurable realization of any passive, linear photonic circuit or device. This promises the development of more compact and versatile photonic systems for a wide range of applications, including optical processing, smart sensing, spectroscopy, and optical communications.

Published
2024

4. Highly multimode visible squeezed light with programmable spectral correlations through broadband up-conversion

Author

Presutti, Federico, Wright, Logan G., Ma, Shi-Yuan, Wang, Tianyu, Malia, Benjamin K., Onodera, Tatsuhiro, and McMahon, Peter L.

Subjects
Quantum Physics, Physics - Optics
Abstract

Multimode squeezed states of light have been proposed as a resource for achieving quantum advantage in computing and sensing. Recent experiments that demonstrate multimode Gaussian states to this end have most commonly opted for spatial or temporal modes, whereas a complete system based on frequency modes has yet to be realized. Instead, we show how to use the frequency modes simultaneously squeezed in a conventional, single-spatial-mode, optical parametric amplifier when pumped by ultrashort pulses. Specifically, we show how adiabatic frequency conversion can be used not only to convert the quantum state from infrared to visible wavelengths, but to concurrently manipulate the joint spectrum. This near unity-efficiency quantum frequency conversion, over a bandwidth >45 THz and, to our knowledge, the broadest to date, allows us to measure the state with an electron-multiplying CCD (EMCCD) camera-based spectrometer, at non-cryogenic temperatures. We demonstrate the squeezing of >400 frequency modes, with a mean of approximately 700 visible photons per shot. Our work shows how many-mode quantum states of light can be generated, manipulated, and measured with efficient use of hardware resources -- in our case, using one pulsed laser, two nonlinear crystals, and one camera. This ability to produce, with modest hardware resources, large multimode squeezed states with partial programmability motivates the use of frequency encoding for photonics-based quantum information processing.

Published
2024

5. Microwave signal processing using an analog quantum reservoir computer

Author

Senanian, Alen, Prabhu, Sridhar, Kremenetski, Vladimir, Roy, Saswata, Cao, Yingkang, Kline, Jeremy, Onodera, Tatsuhiro, Wright, Logan G., Wu, Xiaodi, Fatemi, Valla, and McMahon, Peter L.

Subjects
Quantum Physics
Abstract

Quantum reservoir computing (QRC) has been proposed as a paradigm for performing machine learning with quantum processors where the training is efficient in the number of required runs of the quantum processor and takes place in the classical domain, avoiding the issue of barren plateaus in parameterized-circuit quantum neural networks. It is natural to consider using a quantum processor based on superconducting circuits to classify microwave signals that are analog -- continuous in time. However, while theoretical proposals of analog QRC exist, to date QRC has been implemented using circuit-model quantum systems -- imposing a discretization of the incoming signal in time, with each time point input by executing a gate operation. In this paper we show how a quantum superconducting circuit comprising an oscillator coupled to a qubit can be used as an analog quantum reservoir for a variety of classification tasks, achieving high accuracy on all of them. Our quantum system was operated without artificially discretizing the input data, directly taking in microwave signals. Our work does not attempt to address the question of whether QRCs could provide a quantum computational advantage in classifying pre-recorded classical signals. However, beyond illustrating that sophisticated tasks can be performed with a modest-size quantum system and inexpensive training, our work opens up the possibility of achieving a different kind of advantage than a purely computational advantage: superconducting circuits can act as extremely sensitive detectors of microwave photons; our work demonstrates processing of ultra-low-power microwave signals in our superconducting circuit, and by combining sensitive detection with QRC processing within the same system, one could achieve a quantum sensing-computational advantage, i.e., an advantage in the overall analysis of microwave signals comprising just a few photons.

Published
2023
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6. Mesoscopic ultrafast nonlinear optics -- The emergence of multimode quantum non-Gaussian physics

Author

Yanagimoto, Ryotatsu, Ng, Edwin, Jankowski, Marc, Nehra, Rajveer, McKenna, Timothy P., Onodera, Tatsuhiro, Wright, Logan G., Hamerly, Ryan, Marandi, Alireza, Fejer, M. M., and Mabuchi, Hideo

Subjects
Quantum Physics, Physics - Optics
Abstract

Over the last few decades, nonlinear optics has become significantly more nonlinear, traversing nearly a billionfold improvement in energy efficiency, with ultrafast nonlinear nanophotonics in particular emerging as a frontier for combining both spatial and temporal engineering. At present, cutting-edge experiments in nonlinear nanophotonics place us just above the mesoscopic regime, where a few hundred photons suffice to trigger nonlinear saturation. In contrast to classical or deep-quantum optics, the mesoscale is characterized by dynamical interactions between mean-field, Gaussian, and non-Gaussian quantum features, all within a close hierarchy of scales. When combined with the inherent multimode complexity of optical fields, such hybrid quantum-classical dynamics present theoretical, experimental, and engineering challenges to the contemporary framework of quantum optics. In this review, we highlight the unique physics that emerges in multimode nonlinear optics at the mesoscale and outline key principles for exploiting both classical and quantum features to engineer novel functionalities. We briefly survey the experimental landscape and draw attention to outstanding technical challenges in materials, dispersion engineering, and device design for accessing mesoscopic operation. Finally, we speculate on how these capabilities might usher in some new paradigms in quantum photonics, from quantum-augmented information processing to nonclassical-light-driven dynamics and phenomena to all-optical non-Gaussian measurement and sensing. The physics unlocked at the mesoscale present significant challenges and opportunities in theory and experiment alike, and this review is intended to serve as a guidepost as we begin to navigate this new frontier in ultrafast quantum nonlinear optics., Comment: The first two authors contributed equally to this work; 26 pages, 7 figures

Published
2023
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7. The hardware is the software

Author

Laydevant, Jeremie, Wright, Logan G., Wang, Tianyu, and McMahon, Peter L.

Subjects
Computer Science - Emerging Technologies, Computer Science - Neural and Evolutionary Computing, Quantitative Biology - Neurons and Cognition
Abstract

Human brains and bodies are not hardware running software: the hardware is the software. We reason that because the microscopic physics of artificial-intelligence hardware and of human biological "hardware" is distinct, neuromorphic engineers need to be cautious (and yet also creative) in how we take inspiration from biological intelligence. We should focus primarily on principles and design ideas that respect -- and embrace -- the underlying hardware physics of non-biological intelligent systems, rather than abstracting it away. We see a major role for neuroscience in neuromorphic computing as identifying the physics-agnostic principles of biological intelligence -- that is the principles of biological intelligence that can be gainfully adapted and applied to any physical hardware.

Published
2023

8. Nonchromosomal birth defects and risk of childhood acute leukemia: An assessment in 15 000 leukemia cases and 46 000 controls from the Childhood Cancer and Leukemia International Consortium

Author

Lupo, Philip J, Chambers, Tiffany M, Mueller, Beth A, Clavel, Jacqueline, Dockerty, John D, Doody, David R, Erdmann, Friederike, Ezzat, Sameera, Filippini, Tommaso, Hansen, Johnni, Heck, Julia E, Infante‐Rivard, Claire, Kang, Alice Y, Magnani, Corrado, Malagoli, Carlotta, Marcotte, Erin L, Metayer, Catherine, Bailey, Helen D, Mora, Ana M, Ntzani, Evangelia, Petridou, Eleni Th, Pombo‐de‐Oliveira, Maria S, Rashed, Wafaa M, Roman, Eve, Schüz, Joachim, Wesseling, Catharina, Spector, Logan G, and Scheurer, Michael E

Subjects
Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Rare Diseases, Clinical Research, Cancer, Pediatric, Hematology, Pediatric Cancer, Childhood Leukemia, Pediatric Research Initiative, 2.1 Biological and endogenous factors, Aetiology, Child, Humans, Infant, Risk Factors, Leukemia, Myeloid, Acute, Birth Weight, Logistic Models, Case-Control Studies, Surveys and Questionnaires, acute lymphoblastic leukemia, acute myeloid leukemia, birth defects, childhood leukemia, epidemiology, Oncology & Carcinogenesis, Oncology and carcinogenesis
Abstract

Although recent studies have demonstrated associations between nonchromosomal birth defects and several pediatric cancers, less is known about their role on childhood leukemia susceptibility. Using data from the Childhood Cancer and Leukemia International Consortium, we evaluated associations between nonchromosomal birth defects and childhood leukemia. Pooling consortium data from 18 questionnaire-based and three registry-based case-control studies across 13 countries, we used multivariable logistic regression models to estimate odds ratios (ORs) and 95% confidence intervals (CIs) for the association between a spectrum of birth defects and leukemia. Our analyses included acute lymphoblastic leukemia (ALL, n = 13 115) and acute myeloid leukemia (AML, n = 2120) cases, along with 46 172 controls. We used the false discovery rate to account for multiple comparisons. In the questionnaire-based studies, the prevalence of birth defects was 5% among cases vs 4% in controls, whereas, in the registry-based studies, the prevalence was 11% among cases vs 7% in controls. In pooled adjusted analyses, there were several notable associations, including (1) digestive system defects and ALL (OR = 2.70, 95% CI: 1.46-4.98); (2) congenital anomalies of the heart and circulatory system and AML (OR = 2.86, 95% CI: 1.81-4.52) and (3) nervous system defects and AML (OR = 4.23, 95% CI: 1.50-11.89). Effect sizes were generally larger in registry-based studies. Overall, our results could point to novel genetic and environmental factors associated with birth defects that could also increase leukemia susceptibility. Additionally, differences between questionnaire- and registry-based studies point to the importance of complementary sources of birth defect phenotype data when exploring these associations.

Published
2024

9. Quantum-noise-limited optical neural networks operating at a few quanta per activation

Author

Ma, Shi-Yuan, Wang, Tianyu, Laydevant, Jérémie, Wright, Logan G., and McMahon, Peter L.

Subjects
Physics - Optics, Computer Science - Emerging Technologies, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Quantum Physics
Abstract

Analog physical neural networks, which hold promise for improved energy efficiency and speed compared to digital electronic neural networks, are nevertheless typically operated in a relatively high-power regime so that the signal-to-noise ratio (SNR) is large (>10). What happens if an analog system is instead operated in an ultra-low-power regime, in which the behavior of the system becomes highly stochastic and the noise is no longer a small perturbation on the signal? In this paper, we study this question in the setting of optical neural networks operated in the limit where some layers use only a single photon to cause a neuron activation. Neuron activations in this limit are dominated by quantum noise from the fundamentally probabilistic nature of single-photon detection of weak optical signals. We show that it is possible to train stochastic optical neural networks to perform deterministic image-classification tasks with high accuracy in spite of the extremely high noise (SNR ~ 1) by using a training procedure that directly models the stochastic behavior of photodetection. We experimentally demonstrated MNIST classification with a test accuracy of 98% using an optical neural network with a hidden layer operating in the single-photon regime; the optical energy used to perform the classification corresponds to 0.008 photons per multiply-accumulate (MAC) operation, which is equivalent to 0.003 attojoules of optical energy per MAC. Our experiment used >40x fewer photons per inference than previous state-of-the-art low-optical-energy demonstrations, to achieve the same accuracy of >90%. Our work shows that some extremely stochastic analog systems, including those operating in the limit where quantum noise dominates, can nevertheless be used as layers in neural networks that deterministically perform classification tasks with high accuracy if they are appropriately trained., Comment: 55 pages, 27 figures

Published
2023

11. Microwave signal processing using an analog quantum reservoir computer

Author

Alen Senanian, Sridhar Prabhu, Vladimir Kremenetski, Saswata Roy, Yingkang Cao, Jeremy Kline, Tatsuhiro Onodera, Logan G. Wright, Xiaodi Wu, Valla Fatemi, and Peter L. McMahon

Subjects
Science
Abstract

Abstract Quantum reservoir computing (QRC) has been proposed as a paradigm for performing machine learning with quantum processors where the training takes place in the classical domain, avoiding the issue of barren plateaus in parameterized-circuit quantum neural networks. It is natural to consider using a quantum processor based on microwave superconducting circuits to classify microwave signals that are analog—continuous in time. However, while there have been theoretical proposals of analog QRC, to date QRC has been implemented using the circuit model—imposing a discretization of the incoming signal in time. In this paper we show how a quantum superconducting circuit comprising an oscillator coupled to a qubit can be used as an analog quantum reservoir for a variety of classification tasks, achieving high accuracy on all of them. Our work demonstrates processing of ultra-low-power microwave signals within our superconducting circuit, a step towards achieving a quantum sensing-computational advantage on impinging microwave signals.

Published
2024
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12. Optical Transformers

Author

Anderson, Maxwell G., Ma, Shi-Yuan, Wang, Tianyu, Wright, Logan G., and McMahon, Peter L.

Subjects
Computer Science - Emerging Technologies, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Physics - Applied Physics, Physics - Optics
Abstract

The rapidly increasing size of deep-learning models has caused renewed and growing interest in alternatives to digital computers to dramatically reduce the energy cost of running state-of-the-art neural networks. Optical matrix-vector multipliers are best suited to performing computations with very large operands, which suggests that large Transformer models could be a good target for optical computing. To test this idea, we performed small-scale optical experiments with a prototype accelerator to demonstrate that Transformer operations can run on optical hardware despite noise and errors. Using simulations, validated by our experiments, we then explored the energy efficiency of optical implementations of Transformers and identified scaling laws for model performance with respect to optical energy usage. We found that the optical energy per multiply-accumulate (MAC) scales as $\frac{1}{d}$ where $d$ is the Transformer width, an asymptotic advantage over digital systems. We conclude that with well-engineered, large-scale optical hardware, it may be possible to achieve a $100 \times$ energy-efficiency advantage for running some of the largest current Transformer models, and that if both the models and the optical hardware are scaled to the quadrillion-parameter regime, optical computers could have a $>8,000\times$ energy-efficiency advantage over state-of-the-art digital-electronic processors that achieve 300 fJ/MAC. We analyzed how these results motivate and inform the construction of future optical accelerators along with optics-amenable deep-learning approaches. With assumptions about future improvements to electronics and Transformer quantization techniques (5$\times$ cheaper memory access, double the digital--analog conversion efficiency, and 4-bit precision), we estimated that optical computers' advantage against current 300-fJ/MAC digital processors could grow to $>100,000\times$., Comment: 27 pages, 13 figures

Published
2023

13. Class in Session: Analysis of GPT-4-created Plastic Surgery In-service Examination Questions

Author

Daniel Najafali, BS, Logan G. Galbraith, BA, Justin M. Camacho, MBA, Victoria Stoffel, MS, Isabel Herzog, BA, Civanni Moss, BSN, RN, Stephanie L. Taiberg, BS, and Leonard Knoedler, MD

Subjects
Surgery, RD1-811
Abstract

Background:. The Plastic Surgery In-Service Training Examination (PSITE) remains a critical milestone in residency training. Successful preparation requires extensive studying during an individual’s residency. This study focuses on the capacity of Generative Pre-trained Transformer 4 (GPT-4) to generate PSITE practice questions. Methods:. GPT-4 was prompted to generate multiple choice questions for each PSITE section and provide answer choices with detailed rationale. Question composition via readability metrics were analyzed, along with quality. Descriptive statistics compared GPT-4 and the 2022 PSITE. Results:. The overall median Flesch–Kincaid reading ease for GPT-4-generated questions was 43.90 (versus 50.35 PSITE, P = 0.036). GPT-4 provided questions that contained significantly fewer mean sentences (1 versus 4), words (16 versus 56), and percentage of complex words (3 versus 13) than 2022 PSITE questions (P < 0.001). When evaluating GPT-4 generated questions for each examination section, the highest median Flesch–Kincaid reading ease was on the core surgical principles section (median: 63.30, interquartile range [54.45–68.28]) and the lowest was on the craniomaxillofacial section (median: 36.25, interquartile range [12.57–58.40]). Most readability metrics were higher for the 2022 PSITE compared with GPT-4 generated questions. Overall question quality was poor for the chatbot. Conclusions:. Our study found that GPT-4 can be adapted to generate practice questions for the 2022 PSITE, but its questions are of poor quality. The program can offer general explanations for both the correct and incorrect answer options but was observed to generate false information and poor-quality explanations. Although trainees should navigate with caution as the technology develops, GPT-4 has the potential to serve as an effective educational adjunct under the supervision of trained plastic surgeons.

Published
2024
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14. Roadmap on spatiotemporal light fields

Author

Shen, Yijie, Zhan, Qiwen, Wright, Logan G., Christodoulides, Demetrios N., Wise, Frank W., Willner, Alan E., Zhao, Zhe, Zou, Kai-heng, Liao, Chen-Ting, Hernández-García, Carlos, Murnane, Margaret, Porras, Miguel A., Chong, Andy, Wan, Chenhao, Bliokh, Konstantin Y., Yessenov, Murat, Abouraddy, Ayman F., Wong, Liang Jie, Go, Michael, Kumar, Suraj, Guo, Cheng, Fan, Shanhui, Papasimakis, Nikitas, Zheludev, Nikolay I., Chen, Lu, Zhu, Wenqi, Agrawal, Amit, Jolly, Spencer W., Dorrer, Christophe, Alonso, Benjamín, Lopez-Quintas, Ignacio, López-Ripa, Miguel, Sola, Íñigo J., Fang, Yiqi, Gong, Qihuang, Liu, Yunquan, Huang, Junyi, Zhang, Hongliang, Ruan, Zhichao, Mounaix, Mickael, Fontaine, Nicolas K., Carpenter, Joel, Dorrah, Ahmed H., Capasso, Federico, and Forbes, Andrew

Subjects
Physics - Optics
Abstract

Spatiotemporal sculpturing of light pulse with ultimately sophisticated structures represents the holy grail of the human everlasting pursue of ultrafast information transmission and processing as well as ultra-intense energy concentration and extraction. It also holds the key to unlock new extraordinary fundamental physical effects. Traditionally, spatiotemporal light pulses are always treated as spatiotemporally separable wave packet as solution of the Maxwell's equations. In the past decade, however, more generalized forms of spatiotemporally nonseparable solution started to emerge with growing importance for their striking physical effects. This roadmap intends to highlight the recent advances in the creation and control of increasingly complex spatiotemporally sculptured pulses, from spatiotemporally separable to complex nonseparable states, with diverse geometric and topological structures, presenting a bird's eye viewpoint on the zoology of spatiotemporal light fields and the outlook of future trends and open challenges., Comment: This is the version of the article before peer review or editing, as submitted by an author to Journal of Optics. IOP Publishing Ltd is not responsible for any errors or omissions in this version of the manuscript or any version derived from it

Published
2022
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15. A phenome-wide association study of polygenic scores for selected childhood cancer: Results from the UK Biobank

Author

Eun Mi Jung, Andrew R. Raduski, Lauren J. Mills, and Logan G. Spector

Subjects
childhood cancer, etiology, polygenic risk score, phenome-wide association study, pleiotropy, UK Biobank, Genetics, QH426-470
Abstract

Summary: The aim of this study was to scan phenotypes in adulthood associated with polygenic risk scores (PRS) for childhood cancers with well-articulated genetic architectures—acute lymphoblastic leukemia (ALL), Ewing sarcoma, and neuroblastoma—to examine genetic pleiotropy. Furthermore, we aimed to determine which SNPs could drive associations. Per-SNP summary statistics were extracted for PRS calculation. Participants with white British ancestry were exclusively included for analyses. SNPs were queried from the UK Biobank genotype imputation data. Records from the cancer registry, death registry, and inpatient diagnoses were abstracted for phenome-wide scans. Firth logistic regression was used to estimate odds ratios (ORs) and 95% confidence intervals (CIs) alongside corresponding p values, adjusting for age at recruitment and sex. A total of 244,332 unrelated white British participants were included. We observed a significant association between ALL-PRS and ALL (OR: 1.20e+24, 95% CI: 9.08e+14–1.60e+33). In addition, we observed a significant association between high-risk neuroblastoma PRS and nonrheumatic aortic valve disorders (OR: 43.9, 95% CI: 7.42–260). There were no significant phenotype associations with Ewing sarcoma and neuroblastoma PRS. Regarding individual SNPs, rs17607816 increased the risk of ALL (OR: 6.40, 95% CI: 3.26–12.57). For high-risk neuroblastoma, rs80059929 elevated the risk of atrioventricular block (OR: 3.04, 95% CI: 1.85–4.99). Our findings suggest that individuals with genetic susceptibility to ALL may face a lifelong risk for developing ALL, along with a genetic pleiotropic association between high-risk neuroblastoma and circulatory diseases.

Published
2025
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16. Programmable large-scale simulation of bosonic transport in optical synthetic frequency lattices

Author

Senanian, Alen, Wright, Logan G., Wade, Peter F., Doyle, Hannah K., and McMahon, Peter L.

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

Photonic simulators using synthetic frequency dimensions have enabled flexible experimental analogues of condensed-matter systems, realizing phenomena that are impractical to observe in real-space systems. However, to date such photonic simulators have been limited to small systems suffering from finite-size effects. Here, we present an analog simulator capable of simulating large 2D and 3D lattices, as well as lattices with non-planar connectivity, including a tree lattice that serves as a toy model in quantum gravity. Our demonstration is enabled by the broad bandwidth achievable in photonics, allowing our simulator to realize lattices with over 100,000 lattice sites. We explore these large lattices in a wide range of previously inaccessible regimes by using a novel method to excite arbitrary states. Our work establishes the scalability and flexibility of programmable simulators based on synthetic frequency dimensions in the optical domain. We anticipate that future extensions of this platform will leverage advances in high-bandwidth optoelectronics to support simulations of dynamic, non-equilibrium phases at the scale of millions of lattice sites, and Kerr-frequency-comb technology to simulate models with higher-order interactions, ultimately in regimes and at scales inaccessible to both digital computers and realizable materials.

Published
2022
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17. Image sensing with multilayer, nonlinear optical neural networks

Author

Wang, Tianyu, Sohoni, Mandar M., Wright, Logan G., Stein, Martin M., Ma, Shi-Yuan, Onodera, Tatsuhiro, Anderson, Maxwell G., and McMahon, Peter L.

Subjects
Physics - Optics, Computer Science - Emerging Technologies, Computer Science - Machine Learning
Abstract

Optical imaging is commonly used for both scientific and technological applications across industry and academia. In image sensing, a measurement, such as of an object's position, is performed by computational analysis of a digitized image. An emerging image-sensing paradigm breaks this delineation between data collection and analysis by designing optical components to perform not imaging, but encoding. By optically encoding images into a compressed, low-dimensional latent space suitable for efficient post-analysis, these image sensors can operate with fewer pixels and fewer photons, allowing higher-throughput, lower-latency operation. Optical neural networks (ONNs) offer a platform for processing data in the analog, optical domain. ONN-based sensors have however been limited to linear processing, but nonlinearity is a prerequisite for depth, and multilayer NNs significantly outperform shallow NNs on many tasks. Here, we realize a multilayer ONN pre-processor for image sensing, using a commercial image intensifier as a parallel optoelectronic, optical-to-optical nonlinear activation function. We demonstrate that the nonlinear ONN pre-processor can achieve compression ratios of up to 800:1 while still enabling high accuracy across several representative computer-vision tasks, including machine-vision benchmarks, flow-cytometry image classification, and identification of objects in real scenes. In all cases we find that the ONN's nonlinearity and depth allowed it to outperform a purely linear ONN encoder. Although our experiments are specialized to ONN sensors for incoherent-light images, alternative ONN platforms should facilitate a range of ONN sensors. These ONN sensors may surpass conventional sensors by pre-processing optical information in spatial, temporal, and/or spectral dimensions, potentially with coherent and quantum qualities, all natively in the optical domain.

Published
2022
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19. Combined TMR and RPNI in a vasculopathy patient: A case report

Author

Logan G. Galbraith, Daniel Najafali, and James R. Gatherwright

Subjects
Amputation, Peripheral nerve, Regenerative peripheral nerve interface, Targeted muscle reinnervation, Surgery, RD1-811
Abstract

TMR (targeted muscle reinnervation) or RPNI (regenerative peripheral nerve interface) have been the standard after nerve injuries. In this case report, we explain our approach in combining these two techniques (TMRpni) for a patient undergoing left above-the-knee amputation. Using this method, both phantom and nerve pain were reduced in our patient's case. As this technique becomes more well understood and widely adopted, amputee patients may achieve a greater quality of life post operation.

Published
2023
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20. Developing Bottom-Up Induced Pluripotent Stem Cell Derived Solid Tumor Models Using Precision Genome Editing Technologies

Author

Becklin, Kelsie L, Draper, Garrett M, Madden, Rebecca A, Kluesner, Mitchell G, Koga, Tomoyuki, Huang, Miller, Weiss, William A, Spector, Logan G, Largaespada, David A, Moriarity, Branden S, and Webber, Beau R

Subjects
Biological Sciences, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Bioengineering, Regenerative Medicine, Biotechnology, Human Genome, Stem Cell Research, Rare Diseases, Stem Cell Research - Induced Pluripotent Stem Cell - Human, Genetics, Stem Cell Research - Induced Pluripotent Stem Cell, Cancer, CRISPR-Cas Systems, Gene Editing, Humans, Induced Pluripotent Stem Cells, Neoplasms
Abstract

Advances in genome and tissue engineering have spurred significant progress and opportunity for innovation in cancer modeling. Human induced pluripotent stem cells (iPSCs) are an established and powerful tool to study cellular processes in the context of disease-specific genetic backgrounds; however, their application to cancer has been limited by the resistance of many transformed cells to undergo successful reprogramming. Here, we review the status of human iPSC modeling of solid tumors in the context of genetic engineering, including how base and prime editing can be incorporated into "bottom-up" cancer modeling, a term we coined for iPSC-based cancer models using genetic engineering to induce transformation. This approach circumvents the need to reprogram cancer cells while allowing for dissection of the genetic mechanisms underlying transformation, progression, and metastasis with a high degree of precision and control. We also discuss the strengths and limitations of respective engineering approaches and outline experimental considerations for establishing future models.

Published
2022

21. Onset of non-Gaussian quantum physics in pulsed squeezing with mesoscopic fields

Author

Yanagimoto, Ryotatsu, Ng, Edwin, Yamamura, Atsushi, Onodera, Tatsuhiro, Wright, Logan G., Jankowski, Marc, Fejer, M. M., McMahon, Peter L., and Mabuchi, Hideo

Subjects
Quantum Physics, Physics - Optics
Abstract

We study the emergence of non-Gaussian quantum features in pulsed squeezed light generation with a mesoscopic number (i.e., dozens to hundreds) of pump photons. Due to the strong optical nonlinearities necessarily involved in this regime, squeezing occurs alongside significant pump depletion, compromising the predictions made by conventional semiclassical models for squeezing. Furthermore, nonlinear interactions among multiple frequency modes render the system dynamics exponentially intractable in na\"ive quantum models, requiring a more sophisticated modeling framework. To this end, we construct a nonlinear Gaussian approximation to the squeezing dynamics, defining a "Gaussian interaction frame" (GIF) in which non-Gaussian quantum dynamics can be isolated and concisely described using a few dominant (i.e., principal) supermodes. Numerical simulations of our model reveal non-Gaussian distortions of squeezing in the mesoscopic regime, largely associated with signal-pump entanglement. We argue that the state of the art in nonlinear nanophotonics is quickly approaching this regime, providing an all-optical platform for experimental studies of the semiclassical-to-quantum transition in a rich paradigm of coherent, multimode nonlinear dynamics. Mesoscopic pulsed squeezing thus provides an intriguing case study of the rapid rise in dynamic complexity associated with semiclassical-to-quantum crossover, which we view as a correlate of the emergence of new information-processing capacities in the quantum regime., Comment: The first two authors contributed equally to this work; 16 pages, 7 figures

Published
2021
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23. An investigation of the clinical impact and therapeutic relevance of a DNA damage immune response (DDIR) signature in patients with advanced gastroesophageal adenocarcinoma

Author

Baxter, M.A., Spender, L.C., Cairns, D., Walsh, S., Oparka, R., Porter, R.J., Bray, S., Skinner, G., King, S., Turbitt, J., Collinson, D., Miedzybrodzka, Z.H., Jellema, G., Logan, G., Kennedy, R.D., Turkington, R.C., McLean, M.H., Swinson, D., Grabsch, H.I., Lord, S., Seymour, M.J., Hall, P.S., and Petty, R.D.

Published
2024
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24. An optical neural network using less than 1 photon per multiplication

Author

Wang, Tianyu, Ma, Shi-Yuan, Wright, Logan G., Onodera, Tatsuhiro, Richard, Brian, and McMahon, Peter L.

Subjects
Physics - Optics, Computer Science - Emerging Technologies, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing
Abstract

Deep learning has rapidly become a widespread tool in both scientific and commercial endeavors. Milestones of deep learning exceeding human performance have been achieved for a growing number of tasks over the past several years, across areas as diverse as game-playing, natural-language translation, and medical-image analysis. However, continued progress is increasingly hampered by the high energy costs associated with training and running deep neural networks on electronic processors. Optical neural networks have attracted attention as an alternative physical platform for deep learning, as it has been theoretically predicted that they can fundamentally achieve higher energy efficiency than neural networks deployed on conventional digital computers. Here, we experimentally demonstrate an optical neural network achieving 99% accuracy on handwritten-digit classification using ~3.2 detected photons per weight multiplication and ~90% accuracy using ~0.64 photons (~$2.4 \times 10^{-19}$ J of optical energy) per weight multiplication. This performance was achieved using a custom free-space optical processor that executes matrix-vector multiplications in a massively parallel fashion, with up to ~0.5 million scalar (weight) multiplications performed at the same time. Using commercially available optical components and standard neural-network training methods, we demonstrated that optical neural networks can operate near the standard quantum limit with extremely low optical powers and still achieve high accuracy. Our results provide a proof-of-principle for low-optical-power operation, and with careful system design including the surrounding electronics used for data storage and control, open up a path to realizing optical processors that require only $10^{-16}$ J total energy per scalar multiplication -- which is orders of magnitude more efficient than current digital processors., Comment: 42 pages, 21 figures

Published
2021
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25. Deep physical neural networks enabled by a backpropagation algorithm for arbitrary physical systems

Author

Wright, Logan G., Onodera, Tatsuhiro, Stein, Martin M., Wang, Tianyu, Schachter, Darren T., Hu, Zoey, and McMahon, Peter L.

Subjects
Computer Science - Machine Learning, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Emerging Technologies, Physics - Optics
Abstract

Deep neural networks have become a pervasive tool in science and engineering. However, modern deep neural networks' growing energy requirements now increasingly limit their scaling and broader use. We propose a radical alternative for implementing deep neural network models: Physical Neural Networks. We introduce a hybrid physical-digital algorithm called Physics-Aware Training to efficiently train sequences of controllable physical systems to act as deep neural networks. This method automatically trains the functionality of any sequence of real physical systems, directly, using backpropagation, the same technique used for modern deep neural networks. To illustrate their generality, we demonstrate physical neural networks with three diverse physical systems-optical, mechanical, and electrical. Physical neural networks may facilitate unconventional machine learning hardware that is orders of magnitude faster and more energy efficient than conventional electronic processors.

Published
2021
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26. Efficient simulation of ultrafast quantum nonlinear optics with matrix product states

Author

Yanagimoto, Ryotatsu, Ng, Edwin, Wright, Logan G., Onodera, Tatsuhiro, and Mabuchi, Hideo

Subjects
Quantum Physics, Physics - Optics
Abstract

Ultra-short pulses propagating in nonlinear nanophotonic waveguides can simultaneously leverage both temporal and spatial field confinement, promising a route towards single-photon nonlinearities in an all-photonic platform. In this multimode quantum regime, however, faithful numerical simulations of pulse dynamics na\"ively require a representation of the state in an exponentially large Hilbert space. Here, we employ a time-domain, matrix product state (MPS) representation to enable efficient simulations by exploiting the entanglement structure of the system. In order to extract physical insight from these simulations, we develop an algorithm to unravel the MPS quantum state into constituent temporal supermodes, enabling, e.g., access to the phase-space portraits of arbitrary pulse waveforms. As a demonstration, we perform exact numerical simulations of a Kerr soliton in the quantum regime. We observe the development of non-classical Wigner-function negativity in the solitonic mode as well as quantum corrections to the semiclassical dynamics of the pulse. A similar analysis of $\chi^{(2)}$ simultons reveals a unique entanglement structure between the fundamental and second harmonic. Our approach is also readily compatible with quantum trajectory theory, allowing full quantum treatment of propagation loss and decoherence. We expect this work to establish the MPS technique as part of a unified engineering framework for the emerging field of broadband quantum photonics., Comment: 12 pages, 7 figures

Published
2021
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28. TMR Using a Free Rectus Flap after Transhumeral Amputation

Author

Logan G. Galbraith, BA, Daniel Najafali, BS, and James R. Gatherwright, MD

Subjects
Surgery, RD1-811
Abstract

Summary:. Targeted muscle reinnervation offers an approach to regain use of the affected extremity through electronic prosthesis while limiting phantom pain and neuroma limb production or pain. In this case report, we present the first reported case of leveraging the rectus flap for targeted muscle reinnervation. The case herein is of a 28-year-old woman who sustained a severe right upper extremity crush injury while being involved in a vehicular roll-over collision requiring right transhumeral amputation. Plastic surgery, orthopedic surgery, and vascular surgery were consulted to manage the right upper extremity injury.

Published
2024
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29. Genetic analyses identify evidence for a causal relationship between Ewing sarcoma and hernias

Author

Tianzhong Yang, Lauren J. Mills, Aubrey K. Hubbard, Rui Cao, Andrew Raduski, Mitchell J. Machiela, and Logan G. Spector

Subjects
diaphragmatic hernia, inguinal hernia, Ewing sarcoma, Mendelian randomization, genome-wide association study, GWAS, Genetics, QH426-470
Abstract

Summary: Knowledge of Ewing sarcoma (EWS) risk factors is exceedingly limited; however, multiple small, independent studies have suggested a possible connection between hernia and EWS. By leveraging hernia summary statistics from the UK Biobank and a recently published genome-wide association study of EWS (733 EWS cases and 1,346 controls), we conducted a genetic investigation of the relationship of 5 hernia types (diaphragmatic, inguinal, umbilical, femoral, and ventral) and EWS. We discovered a positive causal relationship between inguinal hernia and EWS (OR 1.27, 95% confidence interval [CI] 1.01–1.59, and p = 0.041) through Mendelian randomization analysis. Further analyses suggested shared pathways through three genes: HMGA2, LOX, and FBXW7. Diaphragmatic hernia showed a stronger causal relationship with EWS among all of the hernia types (OR 2.26, 95% CI 1.30–3.95, p = 0.004), but no statistically significant local correlation pattern was observed. No evidence of a causal or genetic relationship was observed between EWS and the other three hernia types, including umbilical hernia, despite a previous report indicating an OR as high as 3.3. The finding of our genetic analysis provided additional support to the hypothesis that EWS and hernias may share a common origin.

Published
2024
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30. Engineering a Kerr-based Deterministic Cubic Phase Gate via Gaussian Operations

Author

Yanagimoto, Ryotatsu, Onodera, Tatsuhiro, Ng, Edwin, Wright, Logan G., McMahon, Peter L., and Mabuchi, Hideo

Subjects
Quantum Physics, Physics - Optics
Abstract

We propose a deterministic, measurement-free implementation of a cubic phase gate for continuous-variable quantum information processing. In our scheme, the applications of displacement and squeezing operations allow us to engineer the effective evolution of the quantum state propagating through an optical Kerr nonlinearity. Under appropriate conditions, we show that the input state evolves according to a cubic phase Hamiltonian, and we find that the cubic phase gate error decreases inverse-quartically with the amount of quadrature squeezing, even in the presence of linear loss. We also show how our scheme can be adapted to deterministically generate a nonclassical approximate cubic phase state with high fidelity using a ratio of native nonlinearity to linear loss of only $10^{-4}$, indicating that our approach may be experimentally viable in the near term even on all-optical platforms, e.g., using quantum solitons in pulsed nonlinear nanophotonics., Comment: 10 pages, 7 figures. The first two authors contributed equally to this work

Published
2019
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32. Mechanisms of Spatiotemporal Mode-Locking

Author

Wright, Logan G., Sidorenko, Pavel, Pourbeyram, Hamed, Ziegler, Zachary M., Isichenko, Andrei, Malomed, Boris A., Menyuk, Curtis R., Christodoulides, Demetrios N., and Wise, Frank W.

Subjects
Physics - Optics, Nonlinear Sciences - Pattern Formation and Solitons
Abstract

Mode-locking is a process in which different modes of an optical resonator establish, through nonlinear interactions, stable synchronization. This self-organization underlies light sources that enable many modern scientific applications, such as ultrafast and high-field optics and frequency combs. Despite this, mode-locking has almost exclusively referred to self-organization of light in a single dimension - time. Here we present a theoretical approach, attractor dissection, for understanding three-dimensional (3D) spatiotemporal mode-locking (STML). The key idea is to find, for each distinct type of 3D pulse, a specific, minimal reduced model, and thus to identify the important intracavity effects responsible for its formation and stability. An intuition for the results follows from the 'minimum loss principle,' the idea that a laser strives to find the configuration of intracavity light that minimizes loss (maximizes gain extraction). Through this approach, we identify and explain several distinct forms of STML. These novel phases of coherent laser light have no analogues in 1D and are supported by experimental measurements of the three-dimensional field, revealing STML states comprising more than $10^7$ cavity modes. Our results should facilitate the discovery and understanding of new higher-dimensional forms of coherent light which, in turn, may enable new applications.

Published
2019
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33. The Capacity of Quantum Neural Networks

Author

Wright, Logan G. and McMahon, Peter L.

Subjects
Quantum Physics, Physics - Optics
Abstract

A key open question in quantum computation is what advantages quantum neural networks (QNNs) may have over classical neural networks (NNs), and in what situations these advantages may transpire. Here we address this question by studying the memory capacity $C$ of QNNs, which is a metric of the expressive power of a QNN that we have adapted from classical NN theory. We present a capacity inequality showing that the capacity of a QNN is bounded by the information $W$ that can be trained into its parameters: $C \leq W$. One consequence of this bound is that QNNs that are parameterized classically do not show an advantage in capacity over classical NNs having an equal number of parameters. However, QNNs that are parametrized with quantum states could have exponentially larger capacities. We illustrate our theoretical results with numerical experiments by simulating a particular QNN based on a Gaussian Boson Sampler. We also study the influence of sampling due to wavefunction collapse during operation of the QNN, and provide an analytical expression connecting the capacity to the number of times the quantum system is measured.

Published
2019

34. Genetic ancestry, differential gene expression, and survival in pediatric B‐cell acute lymphoblastic leukemia

Author

Freddy A. Barragan, Lauren J. Mills, Andrew R. Raduski, Erin L. Marcotte, Kelsey E. Grinde, Logan G. Spector, and Lindsay A. Williams

Subjects
acute lymphoblastic leukemia, genetic ancestry, survival disparities, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract Background Black children have lower incidence yet worse survival than White and Latinx children with B‐cell acute lymphoblastic leukemia (B‐ALL). It is unclear how reported race/ethnicity (RRE) is associated with death in B‐ALL after accounting for differentially expressed genes associated with genetic ancestry. Methods Using Phase 1 and 2 NCI TARGET B‐ALL cases (N = 273; RRE‐Black = 21, RRE‐White = 162, RRE‐Latinx = 69, RRE‐Other = 9, RRE‐Unknown = 12), we estimated proportions of African (AFR), European (EUR), and Amerindian (AMR) genetic ancestry. We estimated hazard ratios (HR) and 95% confidence intervals (95% CI) between ancestry and death while adjusting for RRE and clinical measures. We identified genes associated with genetic ancestry and adjusted for them in RRE and death associations. Results Genetic ancestry varied within RRE (RRE‐Black, AFR proportion: Mean: 78.5%, Range: 38.2%–93.6%; RRE‐White, EUR proportion: Mean: 94%, Range: 1.6%–99.9%; RRE‐Latinx, AMR proportion: Mean: 52.0%, Range: 1.2%–98.7%). We identified 10, 1, and 6 differentially expressed genes (padjusted

Published
2023
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35. Sympathetic innervation of human and porcine spleens: implications for between species variation in function

Author

Logan G. Kirkland, Chloe G. Garbe, Joseph Hadaya, Paul V. Benson, Brant M. Wagener, Sanjin Tankovic, and Donald B. Hoover

Subjects
Spleen, Noradrenergic innervation, Immunohistochemistry, Tyrosine hydroxylase, Neuropeptide Y, Leukocytes, Medical technology, R855-855.5
Abstract

Abstract Background The vagus nerve affects innate immune responses by activating spleen-projecting sympathetic neurons, which modulate leukocyte function. Recent basic and clinical research investigating vagus nerve stimulation to engage the cholinergic anti-inflammatory pathway (CAP) has shown promising therapeutic results for a variety of inflammatory diseases. Abundant sympathetic innervation occurs in rodent spleens, and use of these species has dominated mechanistic research investigating the CAP. However, previous neuroanatomical studies of human spleen found a more restricted pattern of innervation compared to rodents. Therefore, our primary goal was to establish the full extent of sympathetic innervation of human spleens using donor tissue with the shortest procurement to fixation time. Parallel studies of porcine spleen, a large animal model, were performed as a positive control and for comparison. Methods Human and porcine spleen tissue were fixed immediately after harvest and prepared for immunohistochemistry. Human heart and porcine spleen were stained in conjunction as positive controls. Several immunohistochemical protocols were compared for best results. Tissue was stained for tyrosine hydroxylase (TH), a noradrenergic marker, using VIP purple chromogen. Consecutive tissue slices were stained for neuropeptide Y (NPY), which often co-localizes with TH, or double-labelled for TH and CD3, a T cell marker. High-magnification images and full scans of the tissue were obtained and analyzed for qualitative differences between species. Results TH had dominant perivascular localization in human spleen, with negligible innervation of parenchyma, but such nerves were abundant throughout ventricular myocardium. In marked contrast, noradrenergic innervation was abundant in all regions of porcine spleen, with red pulp having more nerves than white pulp. NPY stain results were consistent with this pattern. In human spleen, noradrenergic nerves only ran close to T cells at the boundary of the periarterial lymphatic sheath and arteries. In porcine spleen, noradrenergic nerves were closely associated with T cells in both white and red pulp as well as other leukocytes in red pulp. Conclusion Sympathetic innervation of the spleen varies between species in both distribution and abundance, with humans and pigs being at opposite extremes. This has important implications for sympathetic regulation of neuroimmune interactions in the spleen of different species and focused targeting of the CAP in humans.

Published
2022
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38. Identifying childhood leukemia with an excess of hematological malignancies in first-degree relatives in Brazil

Author

Daniela P. Mendes-de-Almeida, Francianne G. Andrade, Maria do Perpétuo Socorro Sampaio Carvalho, José Carlos Córdoba, Marcelo dos Santos Souza, Paulo Chagas Neto, Logan G. Spector, and Maria S. Pombo-de-Oliveira

Subjects
familial history of hematological disorders, childhood leukemia, myeloid leukemia, lymphoblastic acute leukemia, Brazil, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

BackgroundFamilial aggregation in childhood leukemia is associated with epidemiological and genomic factors. Albeit epidemiological studies on the familial history of hematological malignancies (FHHMs) are scarce, genome-wide studies have identified inherited gene variants associated with leukemia risk. We revisited a dataset of acute lymphoblastic leukemia (ALL) and acute myeloid leukemia (AML) patients to explore the familial aggregation of malignancies among their relatives.MethodsA series of 5,878 childhood leukemia (≤21 years of age) from the EMiLI study (2000–2019) were assessed. Lack of well-documented familial history of cancer (FHC) and 670 cases associated with genetic phenotypic syndromes were excluded. Leukemia subtypes were established according to World Health Organization recommendations. Logistic regression-derived odds ratios (ORs) and 95% confidence intervals (CIs) were performed and adjusted by age as a continuous variable, where ALL was the reference group for AML and conversely. The pedigree of 18 families with excess hematological malignancy was constructed.ResultsFHC was identified in 472 of 3,618 eligible cases (13%). Ninety-six of the 472 patients (20.3%) had an occurrence of FHHMs among relatives. Overall, FHC was significantly associated with AML (OR, 1.36; 95% CI, 1.01–1.82; p = 0.040). Regarding the first-degree relatives, the OR, 2.92 95% CI,1.57-5.42 and the adjOR, 1.16 (1.03-1.30; p0.001) were found for FHC and FHHM, respectively.ConclusionOur findings confirmed that AML subtypes presented a significant association with hematological malignancies in first-degree relatives. Genomic studies are needed to identify germline mutations that significantly increase the risk of developing myeloid malignancies in Brazil.

Published
2023
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39. In Utero Origins of Acute Leukemia in Children

Author

Adam J. de Smith and Logan G. Spector

Subjects
leukemia, prenatal risk factors, epidemiology, newborn screening, twins, Biology (General), QH301-705.5
Abstract

Acute leukemias, mainly consisting of acute lymphoblastic leukemia (ALL) and acute myeloid leukemia (AML), comprise a major diagnostic group among hematologic cancers. Due to the early age at onset of ALL, particularly, it has long been suspected that acute leukemias of childhood may have an in utero origin. This supposition has motivated many investigations seeking direct proof of prenatal leukemogenesis, in particular, twin and “backtracking studies”. The suspected in utero origin has also focused on gestation as a critical window of risk, resulting in a rich literature on prenatal risk factors for pediatric acute leukemias. In this narrative review, we recount the circumstantial and direct evidence for an in utero origin of childhood acute leukemias.

Published
2024
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40. Multi-megawatt, self-seeded Mamyshev oscillator

Author

Sidorenko, Pavel, Fu, Walter, Wright, Logan G, and Wise, Frank W

Subjects
Physics - Optics
Abstract

We demonstrate a fiber oscillator that achieves 3 MW peak power, is easily started and is environmentally stable. The Mamyshev oscillator delivers 190-nJ pulses that can be compressed externally to 35 fs duration. Accurate numerical modeling of the gain medium provides insight into the behavior and performance of the device.

Published
2018
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41. Parental age and the risk of childhood acute myeloid leukemia: results from the Childhood Leukemia International Consortium

Author

Panagopoulou, Paraskevi, Skalkidou, Alkistis, Marcotte, Erin, Erdmann, Friederike, Ma, Xiaomei, Heck, Julia E, Auvinen, Anssi, Mueller, Beth A, Spector, Logan G, Roman, Eve, Metayer, Catherine, Magnani, Corrado, Pombo-de-Oliveira, Maria S, Scheurer, Michael E, Mora, Ana-Maria, Dockerty, John D, Hansen, Johnni, Kang, Alice Y, Wang, Rong, Doody, David R, Kane, Eleanor, Schüz, Joachim, Christodoulakis, Christos, Ntzani, Evangelia, Petridou, Eleni Th, group, FRECCLE, and group, NARECHEM-ST

Subjects
Epidemiology, Biomedical and Clinical Sciences, Public Health, Health Sciences, Hematology, Pediatric, Childhood Leukemia, Clinical Research, Pediatric Cancer, Cancer, Rare Diseases, 2.1 Biological and endogenous factors, Adolescent, Adult, Birth Weight, Case-Control Studies, Child, Child, Preschool, Female, Humans, Infant, Infant, Newborn, Leukemia, Myeloid, Acute, Logistic Models, Male, Parents, Registries, Risk, Surveys and Questionnaires, Young Adult, Infant acute myeloid leukemia, Childhood cancer, Maternal age, Paternal age, Risk factors, FRECCLE group, NARECHEM-ST group, Oncology and Carcinogenesis, Public Health and Health Services, Oncology & Carcinogenesis, Oncology and carcinogenesis
Abstract

BackgroundParental age has been associated with several childhood cancers, albeit the evidence is still inconsistent.AimTo examine the associations of parental age at birth with acute myeloid leukemia (AML) among children aged 0-14 years using individual-level data from the Childhood Leukemia International Consortium (CLIC) and non-CLIC studies.Material/methodsWe analyzed data of 3182 incident AML cases and 8377 controls from 17 studies [seven registry-based case-control (RCC) studies and ten questionnaire-based case-control (QCC) studies]. AML risk in association with parental age was calculated using multiple logistic regression, meta-analyses, and pooled-effect estimates. Models were stratified by age at diagnosis (infants

Published
2019

44. Sex differences in methylation profiles are apparent in medulloblastoma, particularly among SHH tumors

Author

Rachel M. Moss, Natali Sorajja, Lauren J. Mills, Christopher L. Moertel, Thanh T. Hoang, Logan G. Spector, David A. Largaespada, and Lindsay A. Williams

Subjects
medulloblastoma, sex differences, methylation, survival, pediatric and young adult cancer, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

BackgroundMedulloblastoma, the most common malignant pediatric brain tumor, displays marked sex differences in prevalence of the four main molecular subgroups: SHH, WNT, Group 3 and Group 4. Males are more frequently diagnosed with SHH, Group 3 and 4 tumors, which have worse prognoses than WNT tumors. Little is known about sex differences in methylation profiles within subgroups.MethodsUsing publicly available methylation data (Illumina HumanMethylation450K array), we compared beta values for males versus females. Differentially methylated positions (DMP) by sex within medulloblastoma subgroups were identified on the autosomes. DMPs were mapped to genes and Reactome pathway analysis was run by subgroup. Kaplan-Meier survival curves (Log-Rank p-values) were assessed for each sex within subgroup. MethylCIBERSORT was used to investigate the tumor microenvironment using deconvolution to estimate the abundances of immune cell types using DNA methylation data.ResultsThere were statistically significant differences in sex by medulloblastoma subgroups (chi-squared p-value=0.00004): Group 3 (n=144; 65% male), Group 4 (n=326; 67% male), SHH (n=223; 57% male) and WNT (n=70; 41% male). Females had worse survival than males for SHH (p-value=0.02). DMPs by sex were identified within subgroups: SHH (n=131), Group 4 (n=29), Group 3 (n=19), and WNT (n=16) and validated in an independent dataset. Unsupervised hierarchical clustering showed that sex-DMPs in SHH did not correlate with other tumor attributes. Ten genes with sex DMPs (RFTN1, C1orf103, FKBP1B, COL25A1, NPDC1, B3GNT1, FOXN3, RNASEH2C, TLE1, and PHF17) were shared across subgroups. Significant pathways (p

Published
2023
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48. Multimode Nonlinear Fiber Optics: Massively Parallel Numerical Solver, Tutorial and Outlook

Author

Wright, Logan G., Ziegler, Zachary M., Lushnikov, Pavel M., Zhu, Zimu, Eftekhar, M. Amin, Christodoulides, Demetrios N., and Wise, Frank W.

Subjects
Physics - Optics
Abstract

Building on the scientific understanding and technological infrastructure of single-mode fibers, multimode fibers are being explored as a means of adding new degrees of freedom to optical technologies such as telecommunications, fiber lasers, imaging, and measurement. Here, starting from a baseline of single-mode nonlinear fiber optics, we introduce the growing topic of multimode nonlinear fiber optics. We demonstrate a new numerical solution method for the system of equations that describes nonlinear multimode propagation, the generalized multimode nonlinear Schrodinger equation. This numerical solver is freely available, and includes a number of multimode fiber analysis tools. It features a significant parallel computing speed-up on modern graphical processing units, translating to orders-of-magnitude speed-up over the split-step Fourier method. We demonstrate its use with several examples in graded- and step-index multimode fibers. Finally, we discuss several key open directions and questions, whose answers could have significant scientific and technological impact., Comment: https://github.com/WiseLabAEP/GMMNLSE-Solver-FINAL

Published
2017
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49. Spatiotemporal mode-locking in multimode fiber lasers

Author

Wright, Logan G., Christodoulides, Demetrios N., and Wise, Frank W.

Subjects
Physics - Optics, Nonlinear Sciences - Pattern Formation and Solitons, Physics - Applied Physics
Abstract

A laser is based on the electromagnetic modes of its resonator, which provides the feedback required for oscillation. Enormous progress has been made in controlling the interactions of longitudinal modes in lasers with a single transverse mode. For example, the field of ultrafast science has been built on lasers that lock many longitudinal modes together to form ultrashort light pulses. However, coherent superposition of many longitudinal and transverse modes in a laser has received little attention. The multitude of disparate frequency spacings, strong dispersions, and complex nonlinear interactions among modes greatly favor decoherence over the emergence of order. Here we report the locking of multiple transverse and longitudinal modes in fiber lasers to generate ultrafast spatiotemporal pulses. We construct multimode fiber cavities using graded-index multimode fiber (GRIN MMF). This causes spatial and longitudinal mode dispersions to be comparable. These dispersions are counteracted by strong intracavity spatial and spectral filtering. Under these conditions, we achieve spatiotemporal, or multimode (MM), mode-locking. A variety of other multimode nonlinear dynamical processes can also be observed. Multimode fiber lasers thus open new directions in studies of three-dimensional nonlinear wave propagation. Lasers that generate controllable spatiotemporal fields, with orders-of-magnitude increases in peak power over existing designs, should be possible. These should increase laser utility in many established applications and facilitate new ones.

Published
2017
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50. High-power femtosecond pulses without a modelocked laser

Author

Fu, Walter, Wright, Logan G., and Wise, Frank W.

Subjects
Physics - Optics
Abstract

We demonstrate a fiber system which amplifies and compresses pulses from a gain-switched diode. A Mamyshev regenerator shortens the pulses and improves their coherence, enabling subsequent amplification by parabolic pre-shaping. As a result, we are able to control nonlinear effects and generate nearly transform-limited, 140-fs pulses with 13-MW peak power---an order-of-magnitude improvement over previous gain-switched diode sources. Seeding with a gain-switched diode results in random fluctuations of 2% in the pulse energy, which future work using known techniques may ameliorate. Further development may allow such systems to compete directly with sources based on modelocked oscillators in some applications while enjoying unparalleled robustness and repetition rate control., Comment: 10 pages, 8 figures

Published
2017
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