Your search keyword '"Chandran Suja V"' showing total 24 results

1. Antifoams in non-aqueous diesel fuels: Thin liquid film dynamics and antifoam mechanisms

Author

Calhoun, S.G.K., Chandran Suja, V., Fowler, R., Agiral, A., Salem, K., and Fuller, G.G.

Published

2024

2. Physicochemical characteristics of droplet interface bilayers

Author

Huang, Y., Fuller, G.G., and Chandran Suja, V.

Published

2022

3. Dewetting characteristics of contact lenses coated with wetting agents

Author

Chandran Suja, V., Verma, A., Mossige, E.J.L., Cui, K.W., Xia, V., Zhang, Y., Sinha, D., Joslin, S., and Fuller, G.G.

Published

2022

4. Foaming and antifoaming in non-aqueous liquids

Author

Calhoun, S.G.K., Chandran Suja, V., and Fuller, G.G.

Published

2022

5. Single bubble and drop techniques for characterizing foams and emulsions

Author

Chandran Suja, V., Rodríguez-Hakim, M., Tajuelo, J., and Fuller, G.G.

Published

2020

6. Foam stability in filtered lubricants containing antifoams

Author

Chandran Suja, V., Kar, A., Cates, W., Remmert, S.M., and Fuller, G.G.

Published

2020

7. Hyperspectral imaging for dynamic thin film interferometry

Author

Chandran Suja, V., Sentmanat, J., Hofmann, G., Scales, C., and Fuller, G. G.

Published

2020

8. Axisymmetry breaking, chaos, and symmetry recovery in bubble film thickness profiles due to evaporation-induced Marangoni flows.

Author

Chandran Suja, V., Hadidi, A., Kannan, A., and Fuller, G. G.

Subjects

*MARANGONI effect, *LIQUID films, *SURFACE tension, *BUBBLES, *THIN films, *EVAPORATION (Chemistry), *DYNAMIC viscosity, *CHIRALITY of nuclear particles

Abstract

Understanding the dynamics of evaporating thin liquid films is of practical and fundamental interest. Practically, this understanding is crucial for tuning bubble stability, while fundamentally thin films are an excellent platform to study the characteristics of evaporation-driven two-dimensional (2D) flows. Here, we experimentally study, across a wide range of volatile species concentrations (c0), the spatial and temporal dynamics of film thickness profiles [h(r, θ, t)] over bubbles in binary liquid mixtures subjected to evaporation-induced Marangoni flows. Initially, we probe the spatial structure and show that the spatial symmetry of the film thickness profiles is non-monotonic functions of volatile species concentration with profiles being axisymmetric for both very low (∼1%) and very high (∼90%) concentrations. The temporal evolution of the film thickness fluctuations reveals a similar non-monotonic dependence between the species concentration and the spatial prevalence of fluctuation stochasticity. At a tested intermediate species concentration of 50%, we observe a complete breakdown in spatial symmetry and obtain film thickness fluctuations that are chaotic everywhere in space with spatially invariant fluctuation statistics and rapidly decaying spatial correlation. The observed non-monotonic behavior is a result of the system sensitivity to ambient perturbations scaling as Δγc0(1 − c0)/μ, where Δγ is the difference in equilibrium surface tension between the two species in the mixture and μ is the dynamic viscosity. These insights along with the reported experimental setup serve as an excellent platform to further investigate evaporation-driven 2D chaotic flows. [ABSTRACT FROM AUTHOR]

Published

2021

9. Bubble Coalescence at Wormlike Micellar Solution–Air Interfaces.

Author

Chandran Suja, V., Kannan, A., Kubicka, B., Hadidi, A., and Fuller, G. G.

Published

2020

10. Evaporation-induced Rayleigh–Taylor instabilities in polymer solutions.

Author

Mossige, E. J., Chandran Suja, V., Islamov, M., Wheeler, S. F., and Fuller, Gerald. G.

Subjects

*POLYMER solutions, *RAYLEIGH-Taylor instability, *MOLECULAR weights, *THERMAL instability, *GRAVITATIONAL instability, *INTERFACIAL tension, *EVAPORATION (Chemistry)

Abstract

Understanding the mechanics of detrimental convective instabilities in drying polymer solutions is crucial in many applications such as the production of film coatings. It is well known that solvent evaporation in polymer solutions can lead to Rayleigh-Bénard or Marangoni-type instabilities. Here, we reveal another mechanism, namely that evaporation can cause the interface to display Rayleigh–Taylor instabilities due to the build-up of a dense layer at the air–liquid interface. We study experimentally the onset time (tp) of the instability as a function of the macroscopic properties of aqueous polymer solutions, which we tune by varying the polymer concentration (c0), molecular weight and polymer type. In dilute solutions, tp shows two limiting behaviours depending on the polymer diffusivity. For high diffusivity polymers (low molecular weight), the pluming time scales as c0−2/3. This result agrees with previous studies on gravitational instabilities in miscible systems where diffusion stabilizes the system. On the other hand, in low diffusivity polymers the pluming time scales as c0−1. The stabilizing effect of an effective interfacial tension, similar to those in immiscible systems, explains this strong concentration dependence. Above a critical concentration, c^ , viscosity delays the growth of the instability, allowing time for diffusion to act as the dominant stabilizing mechanism. This results in tp scaling as (ν/c0)2/3. This article is part of the theme issue 'Stokes at 200 (Part 1)'. [ABSTRACT FROM AUTHOR]

Published

2020

11. From improving eyesight to disease theranostics: The impact of ocular fluid mechanics research.

Author

Chandran Suja, V. and Fuller, G. G.

Subjects

*VISION, *EYE drops, *NEWTONIAN fluids, *COMPANION diagnostics, *COMPUTATIONAL fluid dynamics, *RETINAL vein occlusion, *FLUID mechanics

Abstract

Results from the computational fluid dynamics model reveal that the sine wave phakic refractive lens outperforms the existing options in improving aqueous humor flows, consequently reducing the intraocular pressure, increasing vaulting distance, decreasing shear stress, and enhancing oxygen transport. The study contrasts a novel sine wave phakic refractive lens with two established PILs, namely, the implantable contact lens and the posterior chamber phakic refractive lens. The resulting artificial cornea system has a large focus range under a modest applied voltage of 5 V. This innovation not only holds promise for replacing diseased human corneas but also opens possibilities for tunable optical systems. [Extracted from the article]

Published

2023

12. Neutrophils bearing adhesive polymer micropatches as a drug-free cancer immunotherapy.

Author

Kumbhojkar N, Prakash S, Fukuta T, Adu-Berchie K, Kapate N, An R, Darko S, Chandran Suja V, Park KS, Gottlieb AP, Bibbey MG, Mukherji M, Wang LL, Mooney DJ, and Mitragotri S

Subjects

Animals, Mice, Cell Line, Tumor, Tumor Microenvironment drug effects, Female, Mice, Inbred BALB C, Melanoma, Experimental immunology, Melanoma, Experimental therapy, Melanoma, Experimental pathology, Neoplasms immunology, Neoplasms therapy, Killer Cells, Natural immunology, Humans, Neutrophils immunology, Immunotherapy methods, Polymers chemistry, Mice, Inbred C57BL

Abstract

Tumour-associated neutrophils can exert antitumour effects but can also assume a pro-tumoural phenotype in the immunosuppressive tumour microenvironment. Here we show that neutrophils can be polarized towards the antitumour phenotype by discoidal polymer micrometric 'patches' that adhere to the neutrophils' surfaces without being internalized. Intravenously administered micropatch-loaded neutrophils accumulated in the spleen and in tumour-draining lymph nodes, and activated splenic natural killer cells and T cells, increasing the accumulation of dendritic cells and natural killer cells. In mice bearing subcutaneous B16F10 tumours or orthotopic 4T1 tumours, intravenous injection of the micropatch-loaded neutrophils led to robust systemic immune responses, a reduction in tumour burden and improvements in survival rates. Micropatch-activated neutrophils combined with the checkpoint inhibitor anti-cytotoxic T-lymphocyte-associated protein 4 resulted in strong inhibition of the growth of B16F10 tumours, and in complete tumour regression in one-third of the treated mice. Micropatch-loaded neutrophils could provide a potent, scalable and drug-free approach for neutrophil-based cancer immunotherapy., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

13. Preclinical characterization of macrophage-adhering gadolinium micropatches for MRI contrast after traumatic brain injury in pigs.

Author

Wang LL, Gao Y, Chandran Suja V, Boucher ML, Shaha S, Kapate N, Liao R, Sun T, Kumbhojkar N, Prakash S, Clegg JR, Warren K, Janes M, Park KS, Dunne M, Ilelaboye B, Lu A, Darko S, Jaimes C, Mannix R, and Mitragotri S

Subjects

Animals, Mice, Swine, Gadolinium, Brain pathology, Magnetic Resonance Imaging methods, Macrophages pathology, Brain Injuries, Traumatic diagnostic imaging, Brain Concussion pathology

Abstract

The choroid plexus (ChP) of the brain plays a central role in orchestrating the recruitment of peripheral leukocytes into the central nervous system (CNS) through the blood-cerebrospinal fluid (BCSF) barrier in pathological conditions, thus offering a unique niche to diagnose CNS disorders. We explored whether magnetic resonance imaging of the ChP could be optimized for mild traumatic brain injury (mTBI). mTBI induces subtle, yet influential, changes in the brain and is currently severely underdiagnosed. We hypothesized that mTBI induces sufficient alterations in the ChP to cause infiltration of circulating leukocytes through the BCSF barrier and developed macrophage-adhering gadolinium [Gd(III)]-loaded anisotropic micropatches (GLAMs), specifically designed to image infiltrating immune cells. GLAMs are hydrogel-based discoidal microparticles that adhere to macrophages without phagocytosis. We present a fabrication process to prepare GLAMs at scale and demonstrate their loading with Gd(III) at high relaxivities, a key indicator of their effectiveness in enhancing image contrast and clarity in medical imaging. In vitro experiments with primary murine and porcine macrophages demonstrated that GLAMs adhere to macrophages also under shear stress and did not affect macrophage viability or functions. Studies in a porcine mTBI model confirmed that intravenously administered macrophage-adhering GLAMs provide a differential signal in the ChP and lateral ventricles at Gd(III) doses 500- to 1000-fold lower than those used in the current clinical standard Gadavist. Under the same mTBI conditions, Gadavist did not offer a differential signal at clinically used doses. Our results suggest that macrophage-adhering GLAMs could facilitate mTBI diagnosis.

Published

2024

14. Interfacial stresses on droplet interface bilayers using two photon fluorescence lifetime imaging microscopy.

Author

Huang Y, Chandran Suja V, Yang M, Malkovskiy AV, Tandon A, Colom A, Qin J, and Fuller GG

Subjects

Cell Membrane, Lipid Bilayers, Microscopy

Abstract

Hypothesis: Response of lipid bilayers to external mechanical stimuli is an active area of research with implications for fundamental and synthetic cell biology. Developing novel tools for systematically imposing mechanical strains and non-invasively mapping out interfacial (membrane) stress distributions on lipid bilayers can accelerate research in this field., Experiments: We report a miniature platform to manipulate model cell membranes in the form of droplet interface bilayers (DIBs), and non-invasively measure spatio-temporally resolved interfacial stresses using two photon fluorescence lifetime imaging of an interfacially active molecular flipper (Flipper-TR). We established the effectiveness of the developed framework by investigating interfacial stresses accompanying three key processes associated with DIBs: thin film drainage between lipid monolayer coated droplets, bilayer formation, and bilayer separation., Findings: The measurements revealed fundamental aspects of DIBs including the existence of a radially decaying interfacial stress distribution post bilayer formation, and the simultaneous build up and decay of stress respectively at the bilayer corner and center during bilayer separation. Finally, utilizing interfacial rheology measurements and MD simulations, we also reveal that the tested molecular flipper is sensitive to membrane fluidity that changes with interfacial stress - expanding the scientific understanding of how molecular flippers sense stress., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2024

15. A biomimetic chip to assess subcutaneous bioavailability of monoclonal antibodies in humans.

Author

Chandran Suja V, Qi QM, Halloran K, Zhang J, Shaha S, Prakash S, Kumbhojkar N, Deslandes A, Huille S, Gokarn YR, and Mitragotri S

Abstract

Subcutaneous (subQ) injection is a common route for delivering biotherapeutics, wherein pharmacokinetics is largely influenced by drug transport in a complex subQ tissue microenvironment. The selection of good drug candidates with beneficial pharmacokinetics for subQ injections is currently limited by a lack of reliable testing models. To address this limitation, we report here a Sub cutaneous Co- Cu lture T issue-on-a-chip for I njection S imulation (SubCuTIS). SubCuTIS possesses a 3D coculture tissue architecture, and it allows facile quantitative determination of relevant scale independent drug transport rate constants. SubCuTIS captures key in vivo physiological characteristics of the subQ tissues, and it differentiates the transport behavior of various chemically distinct molecules. We supplemented the transport measurements with theoretical modeling, which identified subtle differences in the local absorption rate constants of seven clinically available mAbs. Accounting for first-order proteolytic catabolism, we established a mathematical framework to assess clinical bioavailability using the local absorption rate constants obtained from SubCuTIS. Taken together, the technology described here broadens the applicability of organs-on-chips as a standardized and easy-to-use device for quantitative analysis of subQ drug transport., (© The Author(s) 2023. Published by Oxford University Press on behalf of National Academy of Sciences.)

Published

2023

16. A backpack-based myeloid cell therapy for multiple sclerosis.

Author

Kapate N, Dunne M, Kumbhojkar N, Prakash S, Wang LL, Graveline A, Park KS, Chandran Suja V, Goyal J, Clegg JR, and Mitragotri S

Subjects

Mice, Animals, Myeloid Cells, Central Nervous System, Monocytes, Mice, Inbred C57BL, Multiple Sclerosis therapy, Encephalomyelitis, Autoimmune, Experimental

Abstract

Multiple sclerosis (MS) is an incurable autoimmune disease and is currently treated by systemic immunosuppressants with off-target side effects. Although aberrant myeloid function is often observed in MS plaques in the central nervous system (CNS), the role of myeloid cells in therapeutic intervention is currently overlooked. Here, we developed a myeloid cell-based strategy to reduce the disease burden in experimental autoimmune encephalomyelitis (EAE), a mouse model of progressive MS. We developed monocyte-adhered microparticles ("backpacks") for activating myeloid cell phenotype to an anti-inflammatory state through localized interleukin-4 and dexamethasone signals. We demonstrate that backpack-laden monocytes infiltrated into the inflamed CNS and modulated both the local and systemic immune responses. Within the CNS, backpack-carrying monocytes regulated both the infiltrating and tissue-resident myeloid cell compartments in the spinal cord for functions related to antigen presentation and reactive species production. Treatment with backpack-monocytes also decreased the level of systemic pro-inflammatory cytokines. Additionally, backpack-laden monocytes induced modulatory effects on T H 1 and T H 17 populations in the spinal cord and blood, demonstrating cross talk between the myeloid and lymphoid arms of disease. Backpack-carrying monocytes conferred therapeutic benefit in EAE mice, as quantified by improved motor function. The use of backpack-laden monocytes offers an antigen-free, biomaterial-based approach to precisely tune cell phenotype in vivo, demonstrating the utility of myeloid cells as a therapeutic modality and target.

Published

2023

17. Alzheimer's and Parkinson's disease therapies in the clinic.

Author

Chopade P, Chopade N, Zhao Z, Mitragotri S, Liao R, and Chandran Suja V

Abstract

Alzheimer's disease (AD) and Parkinson's disease (PD) are the most prevalent neurodegenerative diseases, affecting millions and costing billions each year in the United States alone. Despite tremendous progress in developing therapeutics that manage the symptoms of these two diseases, the scientific community has yet to develop a treatment that effectively slows down, inhibits, or cures neurodegeneration. To gain a better understanding of the current therapeutic frontier for the treatment of AD and PD, we provide a review on past and present therapeutic strategies for these two major neurodegenerative disorders in the clinical trial process. We briefly recap currently US Food and Drug Administration-approved therapies, and then explore trends in clinical trials across the variables of therapy mechanism of disease intervention, administration route, use of delivery vehicle, and outcome measures, across the clinical phases over time for "Drug" and "Biologic" therapeutics. We then present the success rate of past clinical trials and analyze the intersections in therapeutic approaches for AD and PD, revealing the shift in clinical trials away from therapies targeting neurotransmitter systems that provide symptomatic relief, and towards anti-aggregation, anti-inflammatory, anti-oxidant, and regeneration strategies that aim to inhibit the root causes of disease progression. We also highlight the evolving distribution of the types of "Biologic" therapies investigated, and the slowly increasing yet still severe under-utilization of delivery vehicles for AD and PD therapeutics. We then briefly discuss novel preclinical strategies for treating AD and PD. Overall, this review aims to provide a succinct overview of the clinical landscape of AD and PD therapies to better understand the field's therapeutic strategy in the past and the field's evolution in approach to the present, to better inform how to effectively treat AD and PD in the future., Competing Interests: The authors declare that they have no competing interests., (© 2022 The Authors. Bioengineering & Translational Medicine published by Wiley Periodicals LLC on behalf of American Institute of Chemical Engineers.)

Published

2022

18. Flowering in bursting bubbles with viscoelastic interfaces.

Author

Tammaro D, Chandran Suja V, Kannan A, Gala LD, Di Maio E, Fuller GG, and Maffettone PL

Subjects

Humans, Surface Properties, Surface-Active Agents, Computer Simulation, Viscoelastic Substances chemistry

Abstract

The lifetime of bubbles, from formation to rupture, attracts attention because bubbles are often present in natural and industrial processes, and their geometry, drainage, coarsening, and rupture strongly affect those operations. Bubble rupture happens rapidly, and it may generate a cascade of small droplets or bubbles. Once a hole is nucleated within a bubble, it opens up with a variety of shapes and velocities depending on the liquid properties. A range of bubble rupture modes are reported in literature in which the reduction of a surface energy drives the rupture against inertial and viscous forces. The role of surface viscoelasticity of the liquid film in this colorful scenario is, however, still unknown. We found that the presence of interfacial viscoelasticity has a profound effect in the bubble bursting dynamics. Indeed, we observed different bubble bursting mechanisms upon the transition from viscous-controlled to surface viscoelasticity-controlled rupture. When this transition occurs, a bursting bubble resembling the blooming of a flower is observed. A simple modeling argument is proposed, leading to the prediction of the characteristic length scales and the number and shape of the bubble flower petals, thus paving the way for the control of liquid formulations with surface viscoelasticity as a key ingredient. These findings can have important implications in the study of bubble dynamics, with consequences for the numerous processes involving bubble rupture. Bubble flowering can indeed impact phenomena such as the spreading of nutrients in nature or the life of cells in bioreactors., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

19. Adsorption and Aggregation of Monoclonal Antibodies at Silicone Oil-Water Interfaces.

Author

Kannan A, Shieh IC, Negulescu PG, Chandran Suja V, and Fuller GG

Subjects

Adsorption, Drug Compounding methods, Drug Stability, Poloxamer chemistry, Polysorbates chemistry, Protein Aggregates, Rheology, Surface Tension, Antibodies, Monoclonal chemistry, Excipients chemistry, Silicone Oils chemistry, Water chemistry

Abstract

Monoclonal antibody (mAb) therapies are rapidly growing for the treatment of various diseases like cancer and autoimmune disorders. Many mAb drug products are sold as prefilled syringes and vials with liquid formulations. Typically, the walls of prefilled syringes are coated with silicone oil to lubricate the surfaces during use. MAbs are surface-active and adsorb to these silicone oil-solution interfaces, which is a potential source of aggregation. We studied formulations containing two different antibodies, mAb1 and mAb2, where mAb1 aggregated more when agitated in the presence of an oil-water interface. This directly correlated with differences in surface activity of the mAbs, studied with interfacial tension, surface mass adsorption, and interfacial rheology. The difference in interfacial properties between the mAbs was further reinforced in the coalescence behavior of oil droplets laden with mAbs. We also looked at the efficacy of surfactants, typically added to stabilize mAb formulations, in lowering adsorption and aggregation of mAbs at oil-water interfaces. We showed the differences between poloxamer-188 and polysorbate-20 in competing with mAbs for adsorption to interfaces and in lowering particulate and overall aggregation. Our results establish a direct correspondence between the adsorption of mAbs at oil-water interfaces and aggregation and the effect of surfactants in lowering aggregation by competitively adsorbing to these interfaces.

Published

2021

20. Surface energy and separation mechanics of droplet interface phospholipid bilayers.

Author

Huang Y, Chandran Suja V, Tajuelo J, and Fuller GG

Subjects

Cell Membrane, Models, Theoretical, Phosphatidylcholines, Lipid Bilayers, Phospholipids

Abstract

Droplet interface bilayers are a convenient model system to study the physio-chemical properties of phospholipid bilayers, the major component of the cell membrane. The mechanical response of these bilayers to various external mechanical stimuli is an active area of research because of its implications for cellular viability and the development of artificial cells. In this article, we characterize the separation mechanics of droplet interface bilayers under step strain using a combination of experiments and numerical modelling. Initially, we show that the bilayer surface energy can be obtained using principles of energy conservation. Subsequently, we subject the system to a step strain by separating the drops in a step-wise manner, and track the evolution of the bilayer contact angle and radius. The relaxation time of the bilayer contact angle and radius along with the decay magnitude of the bilayer radius were observed to increase with each separation step. By analysing the forces acting on the bilayer and the rate of separation, we show that the bilayer separates primarily through the peeling process with the dominant resistance to separation coming from viscous dissipation associated with corner flows. Finally, we explain the intrinsic features of the observed bilayer separation by means of a mathematical model comprising the Young-Laplace equation and an evolution equation. We believe that the reported experimental and numerical results extend the scientific understanding of lipid bilayer mechanics, and that the developed experimental and numerical tools offer a convenient platform to study the mechanics of other types of bilayers.

Published

2021

21. Shear stress rosettes capture the complex flow physics in diseased arteries.

Author

Vamsi Krishna C, Chandran Suja V, Watton PN, Arakeri JH, and Gundiah N

Subjects

Blood Flow Velocity, Hemodynamics, Humans, Models, Cardiovascular, Physics, Shear Strength, Stress, Mechanical, Atherosclerosis, Carotid Artery, Internal

Abstract

Wall shear stress (WSS) is an important parameter in arterial mechanobiology. Various flow metrics, such as time averaged WSS (TAWSS), oscillatory shear index (OSI), and transWSS, have been used to characterize and relate possible WSS variations in arterial diseases like aneurysms and atherosclerosis. We use a graphical representation of WSS using shear rosettes to map temporal changes in the flow dynamics during a cardiac cycle at any spatial location on the vessel surface. The presence of secondary flows and flow reversals can be interpreted directly from the shape of the shear rosette. The mean WSS is given by the rosette centroid, the OSI by the splay around the rosette origin, and the transWSS by its width. We define a new metric, anisotropy ratio (AR), based on the ratio of the length to width of the shear rosette, to capture flow bi-directionality. We characterized the flow physics in controls and patient specific geometries of the ascending aorta (AA) and internal carotid artery (ICA) that have fundamentally different flow dynamics due to differences in the Reynolds and Womersley numbers. The differences in the flow dynamics are well reflected in the shapes of the WSS rosettes and the corresponding flow metrics., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

22. Evaporation-induced foam stabilization in lubricating oils.

Author

Chandran Suja V, Kar A, Cates W, Remmert SM, Savage PD, and Fuller GG

Abstract

Foaming in liquids is ubiquitous in nature. Whereas the mechanism of foaming in aqueous systems has been thoroughly studied, nonaqueous systems have not enjoyed the same level of examination. Here we study the mechanism of foaming in a widely used class of nonaqueous liquids: lubricant base oils. Using a newly developed experimental technique, we show that the stability of lubricant foams can be evaluated at the level of single bubbles. The results obtained with this single-bubble technique indicate that solutocapillary flows are central to lubricant foam stabilization. These solutocapillary flows are shown to originate from the differential evaporation of multicomponent lubricants-an unexpected result given the low volatility of nonaqueous liquids. Further, we show that mixing of some combinations of different lubricant base oils, a common practice in the industry, exacerbates solutocapillary flows and hence leads to increased foaming., Competing Interests: The authors declare no conflict of interest.

Published

2018

23. A Mathematical Model for the Sounds Produced by Knuckle Cracking.

Author

Chandran Suja V and Barakat AI

Subjects

Acoustics, Humans, Hydrodynamics, Pressure, Viscosity, Metacarpophalangeal Joint physiology, Models, Theoretical, Sound, Synovial Fluid physiology

Abstract

The articular release of the metacarpophalangeal joint produces a typical cracking sound, resulting in what is commonly referred to as the cracking of knuckles. Despite over sixty years of research, the source of the knuckle cracking sound continues to be debated due to inconclusive experimental evidence as a result of limitations in the temporal resolution of non-invasive physiological imaging techniques. To support the available experimental data and shed light onto the source of the cracking sound, we have developed a mathematical model of the events leading to the generation of the sound. The model resolves the dynamics of a collapsing cavitation bubble in the synovial fluid inside a metacarpophalangeal joint during an articular release. The acoustic signature from the resulting bubble dynamics is shown to be consistent in both magnitude and dominant frequency with experimental measurements in the literature and with our own experiments, thus lending support for cavitation bubble collapse as the source of the cracking sound. Finally, the model also shows that only a partial collapse of the bubble is needed to replicate the experimentally observed acoustic spectra, thus allowing for bubbles to persist following the generation of sound as has been reported in recent experiments.

Published

2018

24. Impact of Compressibility on the Control of Bubble-Pressure Tensiometers.

Author

Chandran Suja V, Frostad JM, and Fuller GG

Abstract

An experimental and theoretical investigation is conducted to understand the role of compressibility on the quasi-static expansion and contraction of a bubble that is pinned at the opening of a small capillary. The results show that there are two regimes of expansion and contraction depending on the values of two dimensionless parameters which correspond to a dimensionless volume and maximum capillary pressure. In one regime, not all bubble sizes are accessible during expansion and contraction, and the bubbles exhibit a hysteretic behavior when cycling through expansion and contraction. We call this the bubble shape hysteresis. The magnitude of the bubble shape hysteresis is computed for a realistic range of the nondimensional parameters. In the other regime, the bubble size can be varied continuously, but compressibility can still make it difficult to smoothly control the size of the bubble. The theoretical analysis shows that compressibility affects the evolution of the bubbles, even when the bubble is smaller than a hemispherical cap. The analysis also provides the infusion and withdrawal rates that a syringe pump must supply to expand and contract the bubble at a desired rate, accounting for compressibility. The validity of the assumptions used in the model is verified by comparison against experimental data.

Published

2016