Your search keyword '"Irimia, Daniel"' showing total 42 results

1. Infiltrating CD8+T cells exacerbate Alzheimer’s disease pathology in a 3D human neuroimmune axis model

Author

Jorfi, Mehdi, Park, Joseph, Hall, Clare K., Lin, Chih-Chung Jerry, Chen, Meng, von Maydell, Djuna, Kruskop, Jane M., Kang, Byunghoon, Choi, Younjung, Prokopenko, Dmitry, Irimia, Daniel, Kim, Doo Yeon, and Tanzi, Rudolph E.

Abstract

Brain infiltration of peripheral immune cells and their interactions with brain-resident cells may contribute to Alzheimer’s disease (AD) pathology. To examine these interactions, in the present study we developed a three-dimensional human neuroimmune axis model comprising stem cell-derived neurons, astrocytes and microglia, together with peripheral immune cells. We observed an increase in the number of T cells (but not B cells) and monocytes selectively infiltrating into AD relative to control cultures. Infiltration of CD8+T cells into AD cultures led to increased microglial activation, neuroinflammation and neurodegeneration. Using single-cell RNA-sequencing, we identified that infiltration of T cells into AD cultures led to induction of interferon-γ and neuroinflammatory pathways in glial cells. We found key roles for the C-X-C motif chemokine ligand 10 (CXCL10) and its receptor, CXCR3, in regulating T cell infiltration and neuronal damage in AD cultures. This human neuroimmune axis model is a useful tool to study the effects of peripheral immune cells in brain disease.

Published

2023

2. Monocyte Anisocytosis is Associated with Sepsis in Children with Suspected Infection

Author

Yonker, Lael M., Badaki-Makun, Oluwakemi, Alvarez-Carcamo, Bryan, Cross, Cody, Okuducu, Yanki, Appleman, Lori, Greatorex, Jaime, Onu, Rosemary E., Santos, Christine, Petherbridge, Rachel, Foy, Brody H., Cereaga, Diana, Naiman, Melissa, Castro, Iris, Haller, Logan, Guthrie, Lauren B., Higgins, John M., Lewandrowski, Kent B., and Irimia, Daniel

Published

2025

3. Transfusable neutrophil progenitors as cellular therapy for the prevention of invasive fungal infections

Author

Sykes, David B., Martinelli, Michelle M., Negoro, Paige, Xu, Shuying, Maxcy, Katrina, Timmer, Kyle, Viens, Adam L., Alexander, Natalie J., Atallah, Johnny, Snarr, Brendan D., Baistrocchi, Shane R., Atallah, Natalie J., Hopke, Alex, Scherer, Allison, Rosales, Ivy, Irimia, Daniel, Sheppard, Donald C., and Mansour, Michael K.

Abstract

The use of mature neutrophil (granulocyte) transfusions for the treatment of neutropenic patients with invasive fungal infections (IFIs) has been the focus of multiple clinical trials. Despite these efforts, the transfusion of mature neutrophils has resulted in limited clinical benefit, likely owing to problems of insufficient numbers and the very short lifespan of these donor cells. In this report, we employed a system of conditionally immortalized murine neutrophil progenitors that are capable of continuous expansion, allowing for the generation of unlimited numbers of homogenous granulocyte‐macrophage progenitors (GMPs). These GMPs were assayed in vivo to demonstrate their effect on survival in 2 models of IFI: candidemia and pulmonary aspergillosis. Mature neutrophils derived from GMPs executed all cardinal functions of neutrophils. Transfused GMPs homed to the bone marrow and spleen, where they completed normal differentiation to mature neutrophils. These neutrophils were capable of homing and extravasation in response to inflammatory stimuli using a sterile peritoneal challenge model. Furthermore, conditionally immortalized GMP transfusions significantly improved survival in models of candidemia and pulmonary aspergillosis. These data confirm the therapeutic benefit of prophylactic GMP transfusions in the setting of neutropenia and encourage development of progenitor cellular therapies for the management of fungal disease in high‐risk patients. Engineered neutrophil progenitors protect against the invasive fungal pathogens, Candida and Aspergillus, in a neutropenic mouse model

Published

2022

4. Multifactorial assessment of neutrophil chemotaxis efficiency from a drop of blood

Author

Ellett, Felix, Marand, Anika L., and Irimia, Daniel

Abstract

Following injury and infection, neutrophils are guided to the affected site by chemoattractants released from injured tissues and invading microbes. During this process (chemotaxis), neutrophils must integrate multiple chemical signals, while also responding to physical constraints and prioritizing their directional decisions to generate an efficient immune response. In some clinical conditions, human neutrophils appear to lose the ability to chemotax efficiently, which may contribute both directly and indirectly to disease pathology. Here, a range of microfluidic designs is utilized to test the sensitivity of chemotaxing neutrophils to various perturbations, including binary decision‐making in the context of channels with different chemoattractant gradients, hydraulic resistance, and angle of approach. Neutrophil migration in long narrow channels and planar environments is measured. Conditions in which neutrophils are significantly more likely to choose paths with the steepest chemoattractant gradient and the most direct approach angle, and find that migration efficiency across planar chambers is inversely correlated with chamber diameter. By sequential measurement of neutrophil binary decision‐making to different chemoattractant gradients, or chemotactic index in sequential planar environments, data supporting a model of biased random walk for neutrophil chemotaxis are presented. Dynamic sensitivity range of neutrophils to mechanical and chemical cues is determined.

Published

2022

5. Resolvin T-series reduce neutrophil extracellular traps

Author

Chiang, Nan, Sakuma, Miyuki, Rodriguez, Ana R., Spur, Bernd W., Irimia, Daniel, and Serhan, Charles N.

Abstract

The newly identified 13-series (T-series) resolvins (RvTs) regulate phagocyte functions and accelerate resolution of infectious inflammation. Because severe acute respiratory syndrome coronavirus 2 elicits uncontrolled inflammation involving neutrophil extracellular traps (NETs), we tested whether stereochemically defined RvTs regulate NET formation. Using microfluidic devices capturing NETs in phorbol 12-myristate 13-acetate–stimulated human whole blood, the RvTs (RvT1-RvT4; 2.5 nM each) potently reduced NETs. With interleukin-1β–stimulated human neutrophils, each RvT dose and time dependently decreased NETosis, conveying ∼50% potencies at 10 nM, compared with a known NETosis inhibitor (10 μM). In a murine Staphylococcus aureus infection, RvTs (50 ng each) limited neutrophil infiltration, bacterial titers, and NETs. In addition, each RvT enhanced NET uptake by human macrophages; RvT2 was the most potent of the four RvTs, giving a >50% increase in NET-phagocytosis. As part of the intracellular signaling mechanism, RvT2 increased cyclic adenosine monophosphate and phospho–AMP-activated protein kinase (AMPK) within human macrophages, and RvT2-stimulated NET uptake was abolished by protein kinase A and AMPK inhibition. RvT2 also stimulated NET clearance by mouse macrophages in vivo. Together, these results provide evidence for novel pro-resolving functions of RvTs, namely reducing NETosis and enhancing macrophage NET clearance via a cyclic adenosine monophosphate–protein kinase A–AMPK axis. Thus, RvTs open opportunities for regulating NET-mediated collateral tissue damage during infection as well as monitoring NETs.

Published

2022

6. Resolvin T-series reduce neutrophil extracellular traps

Author

Chiang, Nan, Sakuma, Miyuki, Rodriguez, Ana R., Spur, Bernd W., Irimia, Daniel, and Serhan, Charles N.

Abstract

The newly identified 13-series (T-series) resolvins (RvTs) regulate phagocyte functions and accelerate resolution of infectious inflammation. Because severe acute respiratory syndrome coronavirus 2 elicits uncontrolled inflammation involving neutrophil extracellular traps (NETs), we tested whether stereochemically defined RvTs regulate NET formation. Using microfluidic devices capturing NETs in phorbol 12-myristate 13-acetate–stimulated human whole blood, the RvTs (RvT1-RvT4; 2.5 nM each) potently reduced NETs. With interleukin-1β–stimulated human neutrophils, each RvT dose and time dependently decreased NETosis, conveying ∼50% potencies at 10 nM, compared with a known NETosis inhibitor (10 μM). In a murine Staphylococcus aureusinfection, RvTs (50 ng each) limited neutrophil infiltration, bacterial titers, and NETs. In addition, each RvT enhanced NET uptake by human macrophages; RvT2 was the most potent of the four RvTs, giving a >50% increase in NET-phagocytosis. As part of the intracellular signaling mechanism, RvT2 increased cyclic adenosine monophosphate and phospho–AMP-activated protein kinase (AMPK) within human macrophages, and RvT2-stimulated NET uptake was abolished by protein kinase A and AMPK inhibition. RvT2 also stimulated NET clearance by mouse macrophages in vivo. Together, these results provide evidence for novel pro-resolving functions of RvTs, namely reducing NETosis and enhancing macrophage NET clearance via a cyclic adenosine monophosphate–protein kinase A–AMPK axis. Thus, RvTs open opportunities for regulating NET-mediated collateral tissue damage during infection as well as monitoring NETs.

Published

2022

7. Humoral signatures of protective and pathological SARS-CoV-2 infection in children

Author

Bartsch, Yannic C., Wang, Chuangqi, Zohar, Tomer, Fischinger, Stephanie, Atyeo, Caroline, Burke, John S., Kang, Jaewon, Edlow, Andrea G., Fasano, Alessio, Baden, Lindsey R., Nilles, Eric J., Woolley, Ann E., Karlson, Elizabeth W., Hopke, Alex R., Irimia, Daniel, Fischer, Eric S., Ryan, Edward T., Charles, Richelle C., Julg, Boris D., Lauffenburger, Douglas A., Yonker, Lael M., and Alter, Galit

Abstract

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic continues to spread relentlessly, associated with a high frequency of respiratory failure and mortality. Children experience largely asymptomatic disease, with rare reports of multisystem inflammatory syndrome in children (MIS-C). Identifying immune mechanisms that result in these disparate clinical phenotypes in children could provide critical insights into coronavirus disease 2019 (COVID-19) pathogenesis. Using systems serology, in this study we observed in 25 children with acute mild COVID-19 a functional phagocyte and complement-activating IgG response to SARS-CoV-2, similar to the acute responses generated in adults with mild disease. Conversely, IgA and neutrophil responses were significantly expanded in adults with severe disease. Moreover, weeks after the resolution of SARS-CoV-2 infection, children who develop MIS-C maintained highly inflammatory monocyte-activating SARS-CoV-2 IgG antibodies, distinguishable from acute disease in children but with antibody levels similar to those in convalescent adults. Collectively, these data provide unique insights into the potential mechanisms of IgG and IgA that might underlie differential disease severity as well as unexpected complications in children infected with SARS-CoV-2.

Published

2021

8. Influence of Laser Parameters and Experimental Conditions on Nonphotochemical Laser-Induced Nucleation of Glycine Polymorphs

Author

Irimia, Daniel, Jose Shirley, Jenkins, Garg, Anshul S., Nijland, Davey P.A., van der Heijden, Antoine E. D. M., Kramer, Herman J. M., and Eral, Huseyin Burak

Abstract

Nonphotochemical laser-induced nucleation (NPLIN) is a promising primary nucleation control method, yet its underlying mechanism remains elusive. To contribute to the discussion on whether the polarization of laser irradiation in NPLIN experiments influences the polymorphic outcome, we revisit NPLIN experiments with aqueous glycine solutions with supersaturations ranging between S= 1.5 and S= 1.7 irradiated by nanosecond pulses (∼7 ns) of near-infrared wavelength (1064 nm). Systematically altering laser light excitation properties, including the number of pulses and type of polarization, we quantified the nucleation kinetics and characterized the polymorphic form that crystallized upon laser irradiation. Due to the stochasticity of the nucleation process, a large number of samples (>100 per each experimental point) were studied under carefully controlled experimental conditions such as the ambient temperature, cooling rate, and aging period. We observed significant differences among laser-irradiated, spontaneously nucleated, and crash-cooled samples in terms of nucleation kinetics and polymorphic form. This result indicates that laser irradiation provides a different polymorph-forming pathway in comparison to crash-cooling and spontaneous nucleation. However, no clear dependence between the polymorphic form and the polarization of laser irradiation is observed. We discuss our results in the context of previous reports supported thorough quantification of sample heating in NPLIN experiments.

Published

2021

9. 12 Monitoring Monocyte Anisocytosis Changes as a Burn Injury Recovery Marker: Insights from a Clinical Study

Author

Nazemidashtarjandi, Saeed, Supple, Matthew D, Boribong, Brittany, Rosado, Nikki, Karabacak, Nezihi Murat, Yonker, Lael, Yarmush, Martin, Goverman, Jeremy, and Irimia, Daniel

Published

2024

10. Primary and Metastatic Pancreatic Cancer Cells Exhibit Differential Migratory Potentials

Author

Park, Joo Kyung, Hank, Thomas, Scherber, Cally M., Lillemoe, Keith D., Fernández-del Castillo, Carlos, Warshaw, Andrew L., Toner, Mehmet, Irimia, Daniel, Thayer, Sarah P., and Liss, Andrew S.

Abstract

Supplemental digital content is available in the text.

Published

2020

11. Multiparameter Investigation of Laser-Induced Nucleation of Supersaturated Aqueous KCl Solutions

Author

Kacker, Rohit, Dhingra, Sanjana, Irimia, Daniel, Ghatkesar, Murali Krishna, Stankiewicz, Andrzej, Kramer, Herman J. M., and Eral, Huseyin Burak

Abstract

Various mechanisms have been proposed to explain the nonphotochemical laser-induced nucleation (NPLIN). Identifying the dominant mechanism requires addressing a large set of experimental parameters with a statistically significant number of samples, forced by the stochastic nature of nucleation. In this study, with aqueous KCl system, we focus on the nucleation probability as a function of laser wavelength, laser intensity, and sample supersaturation, whereas the influence of filtration and the laser-induced radiation pressure on NPLIN activity is also studied. To account for the nucleation stochasticity, we used 80–100 samples. The NPLIN probability showed an increase with increasing laser intensity. The results are different from the previous report, as a supersaturation independent intensity threshold is not observed. No dependence of the NPLIN probability on the laser wavelength (355, 532, and 1064 nm) was observed. Filtration of samples reduced the nucleation probability suggesting a pronounced role of impurities on NPLIN. The magnitude and the propagation velocity of the laser-induced radiation pressure were quantified using a pressure sensor under laser intensities ranging from 0.5 to 80 MW/cm2. No correlation was found between the radiation pressure and NPLIN at our unfocused laser beam intensities ruling out the radiation pressure as a possible cause for nucleation.

Published

2024

12. Neutrophil functional profiling and cytokine augmentation for patients with multiple recurrent infections: A case study

Author

Alexander, Natalie J., Bozym, David J., Farmer, Joceyln R., Parris, Priscilla, Viens, Adam, Atallah, Natalie, Hopke, Alex, Scherer, Allison, Dagher, Zeina, Barros, Nicolas, Knooihuizen, Sally A.I., Saff, Rebecca R., Pasternack, Mark S., Thompson, Ryan W., Irimia, Daniel, and Mansour, Michael K.

Published

2021

13. Progressive mechanical confinement of chemotactic neutrophils induces arrest, oscillations, and retrotaxis

Author

Wang, Xiao, Jodoin, Emily, Jorgensen, Julianne, Lee, Jarone, Markmann, James J., Cataltepe, Sule, and Irimia, Daniel

Abstract

Neutrophils reach the sites of inflammation and infection in a timely manner by navigating efficiently through mechanically complex interstitial spaces, following the guidance of chemical gradients. However, our understanding of how neutrophils that follow chemical cues overcome mechanical obstacles in their path is restricted by the limitations of current experimental systems. Observations in vivo provide limited insights due to the complexity of the tissue environment. Here, we developed microfluidic devices to study the effect of progressive mechanical confinement on the migration patterns of human neutrophils toward chemical attractants. Using these devices, we identified four migration patterns: arrest, oscillation, retrotaxis, and persistent migration. The proportion of these migration patterns is different in patients receiving immunosuppressant treatments after kidney transplant, patients in critical care, and neonatal patients with infections and is distinct from that in healthy donors. The occurrence of these migration patterns is independent of the nuclear lobe number of the neutrophils and depends on the integrity of their cytoskeletal components. Our study highlights the important role of mechanical cues in moving neutrophils and suggests the mechanical constriction‐induced migration patterns as potential markers for infection and inflammation. Confined mechanical environment rivals chemical cues and alters the migratory behavior of neutrophils during chemotaxis.

Published

2018

14. Resolvin D2 Limits Secondary Tissue Necrosis After Burn Wounds in Rats

Author

Inoue, Yoshitaka, Liu, Yuk Ming, Otawara, Masayuki, Chico Calero, Isabel, Stephanie Nam, Ahhyun, Yu, Yong-Ming, Chang, Philip, Butler, Kathryn L, Nazarian, Rosalynn M, Goverman, Jeremy, Vakoc, Benjamin J, and Irimia, Daniel

Abstract

Secondary burn necrosis is the expansion and deepening of the original burn injury several days after injury. Limiting the extent of secondary burn necrosis may improve outcomes. In this study, we examined the ability of the lipid mediator of inflammation-resolution resolvin D2 (RvD2) and chromatin-lysing enzyme (DNase) to reduce secondary burn necrosis. Male Wistar rats were injured using a brass comb with 4 prongs heated in boiling water. This method created 2 parallel rows of 4 rectangular burned areas separated by 3 unburned interspaces. Starting at 2 hours after the burn injury, rats received either 25?ng/kg RvD2 intravenously daily for 7 days or 200 U/kg DNase every 12 hours for 3 days. We documented the necrosis around the initial wounds by digital photography. We used laser Doppler to assess the total blood flux in the burn area. We evaluated the functionality of the capillary network in the interspaces by optical coherence tomography angiography. We performed histological examination of wound skin tissue samples collected at 14 days postburn. We found that the interspace areas were preserved and had higher blood flow in the RvD2-treated group, while the burn areas expanded into the interspace areas, which were confluent by 7 days postburn, in the control-untreated group. We found a larger monocyte-to-neutrophil ratio in the RvD2-treated group compared with the DNase-treated and control groups (P< .05). Overall, RvD2 suppresses secondary necrosis and starts regeneration, highlighting the role of inflammation resolution as a potential therapeutic target in burn care.

Published

2018

15. Rapid antibiotic sensitivity testing in microwell arrays

Author

Jalali, Fatemeh, Ellett, Felix, and Irimia, Daniel

Abstract

The widespread bacterial resistance to a broad range of antibiotics necessitates rapid antibiotic susceptibility testing before effective treatment could start in the clinic. Among resistant bacteria, Staphylococcus aureusis one of the most important, and Methicillin-resistant (MRSA) strains are a common cause of life threatening infections. However, standard susceptibility testing for S. aureusis time consuming and thus the start of effective antibiotic treatment is often delayed. To circumvent the limitations of current susceptibility testing systems, we designed an assay that enables measurements of bacterial growth with higher spatial and temporal resolution than standard techniques. The assay consists of arrays of microwells that confine small number of bacteria in small spaces, where their growth is monitored with high precision. These devices enabled us to investigate the effect of different antibiotics on S. aureusgrowth. We measured the Minimal Inhibitory Concentration (MIC) in less than 3 hours. In addition to being significantly faster than the 48 hours needed for traditional microbiological methods, the assay is also capable of differentiating the specific effects of different antibiotic classes on S. aureusgrowth. Overall, this assay has the potential to become a rapid, sensitive, and robust tool for use in hospitals and laboratories to assess antibiotic sensitivity.

Published

2017

16. Microstructured Surface Arrays for Injection of Zebrafish Larvae

Author

Ellett, Felix and Irimia, Daniel

Abstract

AbstractMicroinjection of zebrafish larvae is an essential technique for delivery of treatments, dyes, microbes, and xenotransplantation into various tissues. Although a number of casts are available to orient embryos at the single-cell stage, no device has been specifically designed to position hatching-stage larvae for microinjection of different tissues. In this study, we present a reusable silicone device consisting of arrayed microstructures, designed to immobilize 2 days postfertilization larvae in lateral, ventral, and dorsal orientations, while providing maximal access to target sites for microinjection. Injection of rhodamine dextran was used to demonstrate the utility of this device for precise microinjection of multiple anatomical targets.

Published

2017

17. Technical Advance: Changes in neutrophil migration patterns upon contact with platelets in a microfluidic assay

Author

Frydman, Galit H., Le, Anna, Ellett, Felix, Jorgensen, Julianne, Fox, James G., Tompkins, Ronald G., and Irimia, Daniel

Abstract

Microfluidic techniques employed to measure neutrophil motility after interactions with platelets identify patterns of spontaneous and oscillatory neutrophil migration, mediated by CD62P-CD162 interactions. Neutrophils are traditionally regarded as the “first responders” of the immune system. However, recent observations revealed that platelets often respond earlier to recruit and activate neutrophils within sites of injury and inflammation. Currently, platelet–neutrophil interactions are studied by intravital microscopy. Although such studies provide exceptional, physiologic in vivo data, they are also laborious and have low throughput. To accelerate platelet–neutrophil interaction studies, we have developed and optimized an ex vivo microfluidic platform with which the interactions between platelets and moving neutrophils are measured at single-cell level in precise conditions and with high throughput. With the use of this new assay, we have evaluated changes in neutrophil motility upon direct contact with platelets. Motility changes include longer distances traveled, frequent changes in direction, and faster neutrophil velocities compared with a standard motility response to chemoattractant fMLP. We also found that the neutrophil–platelet direct interactions are transient and mediated by CD62P–CD162 interactions, localized predominantly at the uropod of moving neutrophils. This “crawling,” oscillatory neutrophil behavior upon platelet contact is consistent with previous in vivo studies and validates the use of this new test for the exploration of this interactive relationship.

Published

2017

18. Leading edge competition promotes context-dependent responses to receptor inputs to resolve directional dilemmas in neutrophil migration

Author

Hadjitheodorou, Amalia, Bell, George R.R., Ellett, Felix, Irimia, Daniel, Tibshirani, Robert, Collins, Sean R., and Theriot, Julie A.

Abstract

Maintaining persistent migration in complex environments is critical for neutrophils to reach infection sites. Neutrophils avoid getting trapped, even when obstacles split their front into multiple leading edges. How they re-establish polarity to move productively while incorporating receptor inputs under such conditions remains unclear. Here, we challenge chemotaxing HL60 neutrophil-like cells with symmetric bifurcating microfluidic channels to probe cell-intrinsic processes during the resolution of competing fronts. Using supervised statistical learning, we demonstrate that cells commit to one leading edge late in the process, rather than amplifying structural asymmetries or early fluctuations. Using optogenetic tools, we show that receptor inputs only bias the decision similarly late, once mechanical stretching begins to weaken each front. Finally, a retracting edge commits to retraction, with ROCK limiting sensitivity to receptor inputs until the retraction completes. Collectively, our results suggest that cell edges locally adopt highly stable protrusion/retraction programs that are modulated by mechanical feedback.

Published

2023

19. Porous microwells for geometry-selective, large-scale microparticle arrays

Author

Kim, Jae Jung, Bong, Ki Wan, Reátegui, Eduardo, Irimia, Daniel, and Doyle, Patrick S.

Abstract

Large-scale microparticle arrays (LSMAs) are key for material science and bioengineering applications. However, previous approaches suffer from trade-offs between scalability, precision, specificity and versatility. Here, we present a porous microwell-based approach to create large-scale microparticle arrays with complex motifs. Microparticles are guided to and pushed into microwells by fluid flow through small open pores at the bottom of the porous well arrays. A scaling theory allows for the rational design of LSMAs to sort and array particles on the basis of their size, shape, or modulus. Sequential particle assembly allows for proximal and nested particle arrangements, as well as particle recollection and pattern transfer. We demonstrate the capabilities of the approach by means of three applications: high-throughput single-cell arrays; microenvironment fabrication for neutrophil chemotaxis; and complex, covert tags by the transfer of an upconversion nanocrystal-laden LSMA.

Published

2016

20. Big insights from small volumes: deciphering complex leukocyte behaviors using microfluidics

Author

Irimia, Daniel and Ellett, Felix

Abstract

Review on microfluidic tools at the interface between clinical and basic research, of direct relevance to leukocyte biology. Inflammation is an indispensable component of the immune response, and leukocytes provide the first line of defense against infection. Although the major stereotypic leukocyte behaviors in response to infection are well known, the complexities and idiosyncrasies of these phenotypes in conditions of disease are still emerging. Novel tools are indispensable for gaining insights into leukocyte behavior, and in the past decade, microfluidic technologies have emerged as an exciting development in the field. Microfluidic devices are readily customizable, provide tight control of experimental conditions, enable high precision of ex vivo measurements of individual as well as integrated leukocyte functions, and have facilitated the discovery of novel leukocyte phenotypes. Here, we review some of the most interesting insights resulting from the application of microfluidic approaches to the study of the inflammatory response. The aim is to encourage leukocyte biologists to integrate these new tools into increasingly more sophisticated experimental designs for probing complex leukocyte functions.

Published

2016

21. Microfluidic assay for precise measurements of mouse, rat, and human neutrophil chemotaxis in whole‐blood droplets

Author

Jones, Caroline N., Hoang, Anh N., Martel, Joseph M., Dimisko, Laurie, Mikkola, Amy, Inoue, Yoshitaka, Kuriyama, Naohide, Yamada, Marina, Hamza, Bashar, Kaneki, Masao, Warren, H. Shaw, Brown, Diane E., and Irimia, Daniel

Abstract

A microfluidic assay enables precise characterization of neutrophil migration in the native blood environment, independent of the donor species, and at single cell resolution. Animal models of human disease differ in innate immune responses to stress, pathogens, or injury. Precise neutrophil phenotype measurements could facilitate interspecies comparisons. However, such phenotype comparisons could not be performed accurately with the use of current assays, as they require the separation of neutrophils from blood using species‐specific protocols, and they introduce distinct artifacts. Here, we report a microfluidic technology that enables robust characterization of neutrophil migratory phenotypes in a manner independent of the donor species and performed directly in a droplet of whole blood. The assay relies on the particular ability of neutrophils to deform actively during chemotaxis through microscale channels that block the advance of other blood cells. Neutrophil migration is measured directly in blood, in the presence of other blood cells and serum factors. Our measurements reveal important differences among migration counts, velocity, and directionality among neutrophils from 2 common mouse strains, rats, and humans.

Published

2016

22. Design and Validation of a Droplet-based Microfluidic System To Study Non-Photochemical Laser-Induced Nucleation of Potassium Chloride Solutions

Author

Korede, Vikram, Penha, Frederico Marques, de Munck, Vincent, Stam, Lotte, Dubbelman, Thomas, Nagalingam, Nagaraj, Gutta, Maheswari, Cui, PingPing, Irimia, Daniel, van der Heijden, Antoine E.D.M., Kramer, Herman J.M., and Eral, Hüseyin Burak

Abstract

Non-photochemical laser-induced nucleation (NPLIN) has emerged as a promising primary nucleation control technique offering spatiotemporal control over crystallization with potential for polymorph control. So far, NPLIN was mostly investigated in milliliter vials, through laborious manual counting of the crystallized vials by visual inspection. Microfluidics represents an alternative to acquiring automated and statistically reliable data. Thus we designed a droplet-based microfluidic platform capable of identifying the droplets with crystals emerging upon Nd:YAG laser irradiation using the deep learning method. In our experiments, we used supersaturated solutions of KCl in water, and the effect of laser intensity, wavelength (1064, 532, and 355 nm), solution supersaturation (S), solution filtration, and intentional doping with nanoparticles on the nucleation probability is quantified and compared to control cooling crystallization experiments. Ability of dielectric polarization and the nanoparticle heating mechanisms proposed for NPLIN to explain the acquired results is tested. Solutions with lower supersaturation (S= 1.05) exhibit significantly higher NPLIN probabilities than those in the control experiments for all laser wavelengths above a threshold intensity (50 MW/cm2). At higher supersaturation studied (S= 1.10), irradiation was already effective at lower laser intensities (10 MW/cm2). No significant wavelength effect was observed besides irradiation with 355 nm light at higher laser intensities (≥50 MW/cm2). Solution filtration and intentional doping experiments showed that nanoimpurities might play a significant role in explaining NPLIN phenomena.

Published

2023

23. A practical approach for clustering large data flows of malicious URLs

Author

Popescu, Adrian-Ştefan, Gavriluţ, Dragoş-Teodor, and Irimia, Daniel-Ionuţ

Abstract

Over the last couple of years there has been a substantial increase of malicious attacks that are using the Internet as an infection vector. One solution to counter this problem is to implement a filter at the network connection level. Due to the large amount of data that has to be filtered in real-time, any practical approach has to consider both memory usage and performance limitations in order to deliver a fast response time. This paper presents a cloud-based mechanism that can be used to filter large amounts of network traffic with respect to both memory and response time limitations. The algorithms have been tested on data flows of more than 750 million of URLs/day. We will address different practical problems, such as storage, computation time and large data flow clustering. In the end we will also present different statistical results that we obtained over a period of 2 months.

Published

2016

24. Fast sorting of CD4+ T cells from whole blood using glass microbubbles

Author

Hsu, Chia-Hsien, Chen, Chihchen, Irimia, Daniel, and Toner, Mehmet

Abstract

The isolation of CD4 positive T lymphocyte (CD4+) from peripheral blood is important for monitoring patients after HIV infection. Here, we demonstrate a fast isolation strategy for CD4+ cells that involves mixing blood and glass microbubbles. After the specific binding of target cells to the microbubbles carrying specific antibodies on their surface, target cells will spontaneously float to the top of the blood vial and can be quickly separated. Using this strategy, we demonstrate that the isolation of CD4+ cells in less than 5 minutes and with better than 90% efficiency. This strategy for cell isolation based on buoyancy and glass microbubbles is quick and inexpensive, minimizes blood handling, does not require magnetic fields, or centrifugation equipment, and could lead to new, efficient strategies for AIDS diagnosis in resource-limited areas.

Published

2015

25. "Universal" vitrification of cells by ultra-fast cooling

Author

Heo, Yun Seok, Nagrath, Sunitha, Moore, Alessandra L., Zeinali, Mahnaz, Irimia, Daniel, Stott, Shannon L., Toth, Thomas L., and Toner, Mehmet

Abstract

Long-term preservation of live cells is critical for a broad range of clinical and research applications. With the increasing diversity of cells that need to be preserved (e.g. oocytes, stem and other primary cells, genetically modified cells), careful optimization of preservation protocols becomes tedious and poses significant limitations for all but the most expert users. To address the challenge of long-term storage of critical, heterogeneous cell types, we propose a universal protocol for cell vitrification that is independent of cell phenotype and uses only low concentrations of cryoprotectant (1.5 M PROH and 0.5 M trehalose). We employed industrial grade microcapillaries made of highly conductive fused silica, which are commonly used for analytical chemistry applications. The minimal mass and thermal inertia of the microcapillaries enabled us to achieve ultrafast cooling rates up to 4,000 K/s. Using the same low, non-toxic concentration of cryoprotectant, we demonstrate high recovery and viability rates after vitrification for human mammary epithelial cells, rat hepatocytes, tumor cells from pleural effusions, and multiple cancer cell lines.

Published

2015

26. Mitochondrial Localization and the Persistent Migration of Epithelial Cancer cells

Author

Desai, Salil P., Bhatia, Sangeeta N., Toner, Mehmet, and Irimia, Daniel

Abstract

During cancer cell invasion, faster moving cancer cells play a dominant role by invading further and metastasizing earlier. Despite the importance of these outlier cells, the source of heterogeneity in their migratory behavior remains poorly understood. Here, we show that anterior localization of mitochondria, in between the nucleus and the leading edge of migrating epithelial cancer cells, correlates with faster migration velocities and increased directional persistence. The asymmetry of mitochondrial localization along the axis of migration is absent during spontaneous cell migration on two-dimensional surfaces and only occurs in the presence of chemical attractant cues or in conditions of mechanical confinement. Moreover, perturbing the asymmetric distribution of mitochondria within migrating cells by interfering with mitochondrial fusion (opa-1) or fission (drp-1) proteins, significantly reduces the number of cells with anterior localization of mitochondria and significantly decreases the velocity and directional persistence of the fastest moving cells. We also observed similar changes after perturbing the linkage between mitochondria and microtubules by the knockdown of mitochondrial rhoGTPase-1 (miro-1). Taken together, the changes in migration velocity and directional persistence in cells with anterior-localized mitochondria could account for an order of magnitude differences in invasive abilities between cells from otherwise homogenous cell populations.

Published

2013

27. Adaptive-Control Model for Neutrophil Orientation in the Direction of Chemical Gradients

Author

Irimia, Daniel, Balázsi, Gábor, Agrawal, Nitin, and Toner, Mehmet

Abstract

Neutrophils have a remarkable ability to detect the direction of chemoattractant gradients and move directionally in response to bacterial infections and tissue injuries. For their role in health and disease, neutrophils have been extensively studied, and many of the molecules involved in the signaling mechanisms of gradient detection and chemotaxis have been identified. However, the cellular-scale mechanisms of gradient sensing and directional neutrophil migration have been more elusive, and existent models provide only limited insight into these processes. Here, we propose a what we believe is a novel adaptive-control model for the initiation of cell polarization in response to gradients. In this model, the neutrophils first sample the environment by extending protrusions in random directions and subsequently adapt their sensitivity depending on localized, temporal changes in stimulation levels. Our results suggest that microtubules may play a critical role in integrating all the sensing events from the cellular periphery through their redistribution inside the neutrophils, and may also be involved in modulating local signaling. An unexpected finding was that model neutrophils exhibit significant randomness in timing and directionality of activation, comparable to our experimental observations in microfluidic devices. Moreover, their responses are robust against alterations of the rate and amplitude of the signaling reactions, and for a broad range in chemoattractant concentrations and spatial gradients.

Published

2009

28. A high-throughput microfluidic real-time gene expression living cell array

Author

KingAuthors contributed equally., Kevin R., Wang, Sihong, Irimia, Daniel, Jayaraman, Arul, Toner, Mehmet, and Yarmush, Martin L.

Abstract

The dynamics of gene expression are fundamental to the coordination of cellular responses. Measurement of temporal gene expression patterns is currently limited to destructive low-throughput techniques such as northern blotting, reverse transcription polymerase chain reaction (RT-PCR), and DNA microarrays. We report a scalable experimental platform that combines microfluidic addressability with quantitative live cell imaging of fluorescent protein transcriptional reporters to achieve real-time characterization of gene expression programs in living cells. Integrated microvalve arrays control row-seeding and column-stimulation of 256 nanoliter-scale bioreactors to create a high density matrix of stimulus–response experiments. We demonstrate the approach in the context of hepatic inflammation by acquiring ∼5000 single-time-point measurements in each automated and unattended experiment. Experiments can be assembled in hours and perform the equivalent of months of conventional experiments. By enabling efficient investigation of dynamic gene expression programs, this technology has the potential to make significant impacts in basic science, drug development, and clinical medicine.

Published

2006

29. Microfluidic system for measuring neutrophil migratory responses to fast switches of chemical gradientsElectronic supplementary information (ESI) available: Device characterization using fluorescent dyes (movies 01–05) and neutrophil migration in response to chemokine gradient switches (movies 06–10). See DOI: 10.1039/b511877h

Author

Irimia, Daniel, Liu, Su-Yang, Tharp, William G., Samadani, Azadeh, Toner, Mehmet, and Poznansky, Mark C.

Abstract

Experimental systems that provide temporal and spatial control of chemical gradients are required for probing into the complex mechanisms of eukaryotic cell chemotaxis. However, no current technique can simultaneously generate stable chemical gradients and allow fast gradient changes. We developed a microfluidic system with microstructured membranes for exposing neutrophils to fast and precise changes between stable, linear gradients of the known chemoattractant Interleukin-8 (IL-8). We observed that rapidly lowering the average concentration of IL-8 within a gradient, while preserving the direction of the gradient, resulted in temporary neutrophil depolarization. Fast reversal of the gradient direction while increasing or decreasing the average concentration also resulted in temporary depolarization. Neutrophils adapted and maintained their directional motility, only when the average gradient concentration was increased and the direction of the gradient preserved. Based on these observations we propose a two-component temporal sensing mechanism that uses variations of chemokine concentration averaged over the entire cell surface and localized at the leading edge, respectively, and directs neutrophil responses to changes in their chemical microenvironment.

Published

2006

30. Cell handling using microstructured membranes

Author

Irimia, Daniel and Toner, Mehmet

Abstract

Gentle and precise handling of cell suspensions is essential for scientific research and clinical diagnostic applications. Although different techniques for cell analysis at the micro-scale have been proposed, many still require that preliminary sample preparation steps be performed off the chip. Here we present a microstructured membrane as a new microfluidic design concept, enabling the implementation of common sample preparation procedures for suspensions of eukaryotic cells in lab-on-a-chip devices. We demonstrate the novel capabilities for sample preparation procedures by the implementation of metered sampling of nanoliter volumes of whole blood, concentration increase up to three orders of magnitude of sparse cell suspension, and circumferentially uniform, sequential exposure of cells to reagents. We implemented these functions by using microstructured membranes that are pneumatically actuated and allowed to reversibly decouple the flow of fluids and the displacement of eukaryotic cells in suspensions. Furthermore, by integrating multiple structures on the same membrane, complex sequential procedures are possible using a limited number of control steps.

Published

2006

31. Kinetics of Intracellular Ice Formation in One-Dimensional Arrays of Interacting Biological Cells

Author

Irimia, Daniel and Karlsson, Jens O.M.

Abstract

Although cell-cell interactions are known to significantly affect the kinetics of intracellular ice formation (IIF) during tissue freezing, this effect is not well understood. Progress in elucidating the mechanism and role of intercellular ice propagation in tissue freezing has been hampered in part by limitations in experimental design and data analysis. Thus, using rapid-cooling cryomicroscopy, IIF was measured in adherent cells cultured in micropatterned linear constructs (to control cell-cell interactions and minimize confounding factors). By fitting a Markov chain model to IIF data from micropatterned HepG2 cell pairs, the nondimensional rate of intercellular ice propagation was found to be α=10.4±0.1. Using this measurement, a new generator matrix was derived to predict the kinetics of IIF in linear four-cell constructs; cryomicroscopic measurements of IIF state probabilities in micropatterned four-cell arrays conformed with theoretical predictions (p<0.05), validating the modeling assumptions. Thus, the theoretical model was extended to allow prediction of IIF in larger tissues, using Monte Carlo techniques. Simulations were performed to investigate the effects of tissue size and ice propagation rate, for one-dimensional tissue constructs containing up to 100 cells and nondimensional propagation rates in the range 0.1≤α≤1000.

Published

2005

32. Parametric Analysis of Intercellular Ice Propagation during Cryosurgery, Simulated Using Monte Carlo Techniques

Author

Stott, Shannon L., Irimia, Daniel, and Karlsson, Jens O.M.

Abstract

A microscale theoretical model of intracellular ice formation (IIF) in a heterogeneous tissue volume comprising a tumor mass and surrounding normal tissue is presented. Intracellular ice was assumed to form either by intercellular ice propagation or by processes that are not affected by the presence of ice in neighboring cells (e.g., nucleation or mechanical rupture). The effects of cryosurgery on a 2D tissue consisting of 104cells were simulated using a lattice Monte Carlo technique. A parametric analysis was performed to assess the specificity of IIF-related cell damage and to identify criteria for minimization of collateral damage to the healthy tissue peripheral to the tumor. Among the parameters investigated were the rates of interaction-independent IIF and intercellular ice propagation in the tumor and in the normal tissue, as well as the characteristic length scale of thermal gradients in the vicinity of the cryosurgical probe. Model predictions suggest gap junctional intercellular communication as a potential new target for adjuvant therapies complementing the cryosurgical procedure.

Published

2004

33. Development of a Cell Patterning Technique Using Poly(Ethylene Glycol) Disilane

Author

Irimia, Daniel and Karlsson, Jens

Abstract

A simple technique for controlling cell adhesion on glass substrates by surface modification using a commercially available poly(ethylene glycol) (PEG) disilane, which can bind directly to glass in a single step, in combination with photolithographic micropatterning, was developed, characterized, and evaluated for patterning of HepG2 hepatoma cells and 3T3 fibroblasts. The optimal concentration of PEG-disilane for surface modification was 5 mM, and patterning of strongly adherent cells such as HepG2 required the chelation of divalent metal cations in order to inhibit nonspecific binding and cell aggregation. Whereas the average thickness of the PEG-disilane layer was 18±3.5 nm, the perimeters of patterned areas of exposed glass exhibited ridges of average height 857±50 nm, which may have aided in constraining cell spreading and migration. Although unpatterned PEG-treated substrates were hydrophilic (contact angle 46±1°), micropatterned surfaces behaved as if they were somewhat hydrophobic (contact angle ∼90°), necessitating special protocols for preventing deleterious dewetting of cells. For optimized protocols, the probability of adhesion of HepG2 cells to a patterned area of exposed glass was almost 15 times higher than the probability of adhesion to a PEG-treated background region of equal area. Our technique is useful for short- to intermediate-term patterning of cell or tissue morphology, e.g., for investigation of the effects of cell–cell interactions or cell geometry.

Published

2003

34. Kinetics and Mechanism of Intercellular Ice Propagation in a Micropatterned Tissue Construct

Author

Irimia, Daniel and Karlsson, Jens O.M.

Abstract

Understanding the effects of cell–cell interaction on intracellular ice formation (IIF) is required to design optimized protocols for cryopreservation of tissue. To determine the effects of cell–cell interactions during tissue freezing, without confounding effects from uncontrolled factors (such as time in culture, cell geometry, and cell–substrate interactions), HepG2 cells were cultured in pairs on glass coverslips micropatterned with polyethylene glycol disilane, such that each cell interacted with exactly one adjacent cell. Assuming the cell pair to be a finite state system, being either in an unfrozen state (no ice in either cell), a singlet state (IIF in one cell only), or a doublet state (IIF in both cells), the kinetics of state transitions were theoretically modeled and cryomicroscopically measured. The rate of intercellular ice propagation, estimated from the measured singlet state probability, increased in the first 24h of culture and remained steady thereafter. In cell pairs cultured for 24h and treated with the gap junction blocker 18β-glycyrrhetinic acid before freezing, the intercellular ice propagation rate was lower than in untreated controls (p<0.001), but significantly greater than zero (p<0.0001). These results suggest that gap junctions mediate some, but not all, mechanisms of ice propagation in tissue.

Published

2002

35. Neutrophil profiles of pediatric COVID-19 and multisystem inflammatory syndrome in children

Author

Boribong, Brittany P., LaSalle, Thomas J., Bartsch, Yannic C., Ellett, Felix, Loiselle, Maggie E., Davis, Jameson P., Gonye, Anna L.K., Sykes, David B., Hajizadeh, Soroush, Kreuzer, Johannes, Pillai, Shiv, Haas, Wilhelm, Edlow, Andrea G., Fasano, Alessio, Alter, Galit, Irimia, Daniel, Sade-Feldman, Moshe, and Yonker, Lael M.

Abstract

Multisystem inflammatory syndrome in children (MIS-C) is a delayed-onset, COVID-19-related hyperinflammatory illness characterized by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) antigenemia, cytokine storm, and immune dysregulation. In severe COVID-19, neutrophil activation is central to hyperinflammatory complications, yet the role of neutrophils in MIS-C is undefined. Here, we collect blood from 152 children: 31 cases of MIS-C, 43 cases of acute pediatric COVID-19, and 78 pediatric controls. We find that MIS-C neutrophils display a granulocytic myeloid-derived suppressor cell (G-MDSC) signature with highly altered metabolism that is distinct from the neutrophil interferon-stimulated gene (ISG) response we observe in pediatric COVID-19. Moreover, we observe extensive spontaneous neutrophil extracellular trap (NET) formation in MIS-C, and we identify neutrophil activation and degranulation signatures. Mechanistically, we determine that SARS-CoV-2 immune complexes are sufficient to trigger NETosis. Our findings suggest that hyperinflammatory presentation during MIS-C could be mechanistically linked to persistent SARS-CoV-2 antigenemia, driven by uncontrolled neutrophil activation and NET release in the vasculature.

Published

2022

36. Spleen Tyrosine Kinase Is a Critical Regulator of Neutrophil Responses to CandidaSpecies

Author

Negoro, Paige E., Xu, Shuying, Dagher, Zeina, Hopke, Alex, Reedy, Jennifer L., Feldman, Michael B., Khan, Nida S., Viens, Adam L., Alexander, Natalie J., Atallah, Natalie J., Scherer, Allison K., Dutko, Richard A., Jeffery, Jane, Kernien, John F., Fites, J. Scott, Nett, Jeniel E., Klein, Bruce S., Vyas, Jatin M., Irimia, Daniel, Sykes, David B., and Mansour, Michael K.

Abstract

Neutrophils are recognized to represent significant immune cell mediators for the clearance and elimination of the human-pathogenic fungal pathogen Candida. The sensing of fungi by innate cells is performed, in part, through lectin receptor recognition of cell wall components and downstream cellular activation by signaling components, including spleen tyrosine kinase (Syk). While the essential role of Syk in macrophages and dendritic cells is clear, there remains uncertainty with respect to its contribution in neutrophils. In this study, we demonstrated that Syk is critical for multiple cellular functions in neutrophils responding to major human-pathogenic Candidaspecies. These data not only demonstrate the vital nature of Syk with respect to the control of fungi by neutrophils but also warn of the potential infectious complications arising from the recent clinical development of novel Syk inhibitors for hematologic and autoimmune disorders.

Published

2020

37. Three‐Dimensional Models of the Human Brain Development and Diseases

Author

Jorfi, Mehdi, D'Avanzo, Carla, Kim, Doo Yeon, and Irimia, Daniel

Abstract

Deciphering the human brain pathophysiology remains one of the greatest challenges of the 21stcentury. Neurological disorders represent a significant proportion of diseases burden; however, the complexity of the brain physiology makes it challenging to model its diseases. Simple in vitro models have been very useful for precise measurements in controled conditions. However, existing models are limited in their ability to replicate complex interactions between various cells in the brain. Studying human brain requires sophisticated models to reconstitute the tangled architecture and functions of brain cells. Recently, advances in the development of three‐dimensional (3D) brain cell culture models have begun to recapitulate various aspects of the human brain physiology in vitro and replicate basic disease processes of Alzheimer's disease, amyotrophic lateral sclerosis, and microcephaly. In this review, we discuss the progress, advantages, limitations, and future directions of 3D cell culture systems for modeling the human brain development and diseases. Neurological disordersrepresent a significant proportion of human diseases; however, understanding brain pathology is challenging, in part because of the complexity of the brain structure and function. Sophisticated models are required to reconstitute the tangled architecture and complex functions of brain cells. Here we review the most recent advances, chalenges, and future directions of 3D cell culture systems for modeling the human brain.

Published

2018

38. Adaptive-Control Model for Neutrophil ORIENTATION in the Direction of Chemical Gradients

Author

Irimia, Daniel

Published

2009

39. A Zebrafish Compound Screen Reveals Modulation of Neutrophil Reverse Migration as an Anti-Inflammatory Mechanism

Author

Robertson, Anne L., Holmes, Geoffrey R., Bojarczuk, Aleksandra N., Burgon, Joseph, Loynes, Catherine A., Chimen, Myriam, Sawtell, Amy K., Hamza, Bashar, Willson, Joseph, Walmsley, Sarah R., Anderson, Sean R., Coles, Mark C., Farrow, Stuart N., Solari, Roberto, Jones, Simon, Prince, Lynne R., Irimia, Daniel, Rainger, G. Ed, Kadirkamanathan, Visakan, Whyte, Moira K. B., and Renshaw, Stephen A.

Abstract

The proresolution therapeutic tanshinone IIA drives inflammation resolution by reverse migration.

Published

2014

40. Barotaxis in a Confined Neutrophil

Author

Prentice-Mott, Harrison, Chang, Chi-Han, Mahadevan, L., Mitchison, Tim, Irimia, Daniel, and Shah, Jagesh

Published

2014

41. Murine Melanomas Expressing High Levels of SDF-1 Repel and Escape Control by Tumor Specific T-Cells.

Author

Vianello, Fabrizio, Papeta, Natalia, Kircher, Moritz F., Toner, Mehmet, Weissleder, Ralph, Irimia, Daniel, and Poznansky, Mark C.

Abstract

Most antigenic tumors are able to evade the immune system despite T cell recognition of tumor specific antigens. The chemokine, stromal derived factor- 1 (SDF-1 or CXCL12) is constitutively expressed by both normal and neoplastic tissues and is involved in tumor growth, metastasis and modulation of the anti-tumor immune response. We have previously shown that human T cells are repelled by the chemokine SDF-1, in a concentration-dependent and CXCR4 receptor-mediated manner. We proposed that the repulsion of tumor-specific T cells from a tumor expressing SDF-1 may represent a novel mechanism of immune evasion. B16 melanoma cells stably expressing OVA were genetically modified to constitutively express SDF-1 using a bicistronic MSCV2.2 retroviral transfer vector encoding murine SDF-1α and EGFP. SDF-1 generated by transduced cells was 58 ± 28.5 ng/ml/1x106cells/24 hours as measured by ELISA. Immunization of mice with irradiated B16/OVA cells lead to destruction of B16/OVA.MSCV control tumors but not tumors expressing high levels of SDF-1 (p=0.0001). Failure to reject B16/OVA.SDF-1 tumors was associated with a reduction of T cell infiltration compared to control B16/OVA.MSCV (p=0.001). Similarly, early recruitment of adoptively-transferred OVA-specific CD8+ T cells into B16/OVA.SDF-1 tumors was significantly reduced in comparison to B16/OVA.MSCV control tumors as demonstrated by immunohistochemistry and real-time magnetic resonance imaging of nanoparticle labeled CTLs (p=0.018). Transferred memory OVA-specific CD8+ T-cells demonstrated antitumor activity against B16/OVA.MSCV control tumors but not against B16/OVA-SDF-1 tumors (p=0.04). Isolation and FACS analysis of tumor-infiltrating lymphocytes showed a 4-fold reduction of T cells in B16/OVA.SDF-1 compared to B16/OVA.MSCV control tumors (p=0.005). The in-vitro killing activity of tumor specific CD8+ T cells against B16/OVA.SDF-1 tumors was significantly reduced compared to B16/OVA.MSCV control tumors when measured in 51Cr release assay performed in a flat-bottom well system where cytotoxicity was dependent on effector cell migration (p=0.0004). Preincubation of OT-I CD8+ T cells with the CXCR4 antagonist AMD3100 restored their cytolytic activity against B16/OVA.SDF-1 cells (p=0.045). These data support the thesis that the active movement of tumor-specific T cells away from SDF-1, termed fugetaxis, may provide a novel mechanism by which a tumor evades challenge by immune effector cells and raises the possibility of the development of a novel immunotherapeutic approach to cancer.

Published

2004

42. Murine Melanomas Expressing High Levels of SDF-1 Repel and Escape Control by Tumor Specific T-Cells.

Author

Vianello, Fabrizio, Papeta, Natalia, Kircher, Moritz F., Toner, Mehmet, Weissleder, Ralph, Irimia, Daniel, and Poznansky, Mark C.

Abstract

Most antigenic tumors are able to evade the immune system despite T cell recognition of tumor specific antigens. The chemokine, stromal derived factor- 1 (SDF-1 or CXCL12) is constitutively expressed by both normal and neoplastic tissues and is involved in tumor growth, metastasis and modulation of the anti-tumor immune response. We have previously shown that human T cells are repelled by the chemokine SDF-1, in a concentration-dependent and CXCR4 receptor-mediated manner. We proposed that the repulsion of tumor-specific T cells from a tumor expressing SDF-1 may represent a novel mechanism of immune evasion. B16 melanoma cells stably expressing OVA were genetically modified to constitutively express SDF-1 using a bicistronic MSCV2.2 retroviral transfer vector encoding murine SDF-1α and EGFP. SDF-1 generated by transduced cells was 58 ± 28.5 ng/ml/1x106 cells/24 hours as measured by ELISA. Immunization of mice with irradiated B16/OVA cells lead to destruction of B16/OVA.MSCV control tumors but not tumors expressing high levels of SDF-1 (p=0.0001). Failure to reject B16/OVA.SDF-1 tumors was associated with a reduction of T cell infiltration compared to control B16/OVA.MSCV (p=0.001). Similarly, early recruitment of adoptively-transferred OVA-specific CD8+ T cells into B16/OVA.SDF-1 tumors was significantly reduced in comparison to B16/OVA.MSCV control tumors as demonstrated by immunohistochemistry and real-time magnetic resonance imaging of nanoparticle labeled CTLs (p=0.018). Transferred memory OVA-specific CD8+ T-cells demonstrated antitumor activity against B16/OVA.MSCV control tumors but not against B16/OVA-SDF-1 tumors (p=0.04). Isolation and FACS analysis of tumor-infiltrating lymphocytes showed a 4-fold reduction of T cells in B16/OVA.SDF-1 compared to B16/OVA.MSCV control tumors (p=0.005). The in-vitro killing activity of tumor specific CD8+ T cells against B16/OVA.SDF-1 tumors was significantly reduced compared to B16/OVA.MSCV control tumors when measured in 51Cr release assay performed in a flat-bottom well system where cytotoxicity was dependent on effector cell migration (p=0.0004). Preincubation of OT-I CD8+ T cells with the CXCR4 antagonist AMD3100 restored their cytolytic activity against B16/OVA.SDF-1 cells (p=0.045). These data support the thesis that the active movement of tumor-specific T cells away from SDF-1, termed fugetaxis, may provide a novel mechanism by which a tumor evades challenge by immune effector cells and raises the possibility of the development of a novel immunotherapeutic approach to cancer.

Published

2004