The Pathway of Bone Fluid Flow as Defined by In Vivo Intramedullary Pressure and Streaming Potential Measurements

Yi-Xian Qin; Wei Lin; Clinton Rubin

doi:10.1114/1.1483863

Induced Intramedullary Pressure by Dynamic Hydraulic Stimulation and Its Potential in Attenuation of Bone Loss

ASME 2011 Summer Bioengineering Conference, Parts A and B ◽

10.1115/sbc2011-54015 ◽

2011 ◽

Author(s):

M. Hu ◽

J. Cheng ◽

S. Ferreri ◽

F. Serra-Hsu ◽

W. Lin ◽

...

Keyword(s):

Fluid Flow ◽

Bone Loss ◽

Bone Adaptation ◽

Dependent Manner ◽

Hydraulic Stimulation ◽

Flow Coupling ◽

Bone Fluid Flow ◽

Intramedullary Pressure ◽

New Treatments

Bone loss is a critical health problem of astronauts in long-term space missions. A growing number of evidence has pointed out bone fluid flow as a critical regulator in mechanotransductive signaling and bone adaptation. Intramedullary pressure (ImP) is a key mediator for bone fluid flow initiation and it influences the osteogenic signals within the skeleton. The potential ImP-induced bone fluid flow then triggers bone adaptation [1]. Previous in vivo study has demonstrated that ImP induced by oscillatory electrical stimulations can effectively mitigate disuse osteopenia in a frequency-dependent manner in a disuse rat model [2, 3]. In order to develop the translational potentials of ImP, a non-invasive intervention with direct fluid flow coupling is necessary to develop new treatments for microgravity-induced osteopenia/osteoporosis.

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In Vivo Mesenchymal Stem Cell Proliferation in Response to Dynamic Fluid Flow Stimulation

ASME 2012 Summer Bioengineering Conference, Parts A and B ◽

10.1115/sbc2012-80586 ◽

2012 ◽

Author(s):

M. Hu ◽

R. Yeh ◽

M. Lien ◽

Y. X. Qin

Keyword(s):

Fluid Flow ◽

Bone Tissue ◽

Bone Adaptation ◽

Hindlimb Suspension ◽

Osteoporotic Bone ◽

Hydraulic Stimulation ◽

Structural Deterioration ◽

Bone Fluid Flow ◽

Cord Injury

Osteoporosis is a debilitating disease characterized as decreased bone mass and structural deterioration of bone tissue. Osteoporotic bone tissue turns itself into altered structure, which leads to weaker bones that are more susceptible for fractures. While often happening in elderly, long-term bed-rest patients, e.g. spinal cord injury, and astronauts who participate in long-duration spaceflights, osteoporosis has been considered as a major public health thread and causes great medical cost impacts to the society. Mechanobiology and novel stimulation on regulating bone health have long been recognized. Loading induced bone fluid flow, as a critical mechanotransductive promoter, has been demonstrated to regulate cellular signaling, osteogenesis, and bone adaptation [4]. As one of the factors that mediate bone fluid flow, intromedullary pressure (ImP) creates a pressure gradient that further influence the magnitude of mechanotransductory signals [5]. As for a potential translational development of ImP, our group has recently introduced a novel, non-invasive dynamic hydraulic stimulation (DHS) on bone structural enhancement. Its promising effects on inhibition of disuse bone loss has been shown with 2 Hz loading through a 4-week hindlimb suspension rat study followed by microCT analysis. At the cellular level, mesenchymal stem cells (MSCs) are defined by their self-renewal ability and that to potentially differentiate into the cells that form tissues such as bone [1]. To further elucidate the cellular effects of DHS and its potential mechanism on bone quality enhancement, the objective of this study was to measure MSC quantification in response to the in vivo mechanical signals driven by DHS.

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Oscillatory Bone Fluid Flow and its Role in Initiating Remodeling in the Absence of Matrix Strain

10.1115/imece2001/bed-23025 ◽

2001 ◽

Author(s):

Yixian Qin ◽

Anita Saldanha ◽

Tamara Kaplan

Keyword(s):

Fluid Flow ◽

Cellular Response ◽

Fluid Shear Stress ◽

Bone Matrix ◽

Fluid Pressure ◽

Streaming Potential ◽

Bone Adaptation ◽

Interstitial Fluid Flow ◽

Bone Fluid Flow ◽

Matrix Deformation

Abstract Load-generated intracortical fluid flow is proposed to be an important mediator for regulating bone mass and morphology [1]. Although the mechanism of cellular response to induced flow parameters, i.e., fluid pressure, pressure gradient, velocity, and fluid shear stress, are not yet clear, interstitial fluid flow driven by loading may be necessary to explain the adaptive response of bone, which is either coupled with load-induced strain magnitude or independent with matrix strain per se [2]. It has been demonstrated that load-induced intracortical fluid flow is contributed by both bone matrix deformation and induced intramedullary (IM) pressure [3]. To examine the hypothesis of fluid flow generated adaptation, it is necessary to test the mechanism under the circumstances of solely fluid induced bone adaptation in the absence of matrix deformation. While our previous data has demonstrated that bone fluid flow and its associated streaming potential product can be influenced by the dynamic IM pressure quantitatively [4], the objective of this study was to evaluate fluid induced bone adaptation in an avian ulna model using oscillatory IM fluid pressure loading in the absence of bone matrix strain. The potential fluid pathway was measured in the model.

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Local and Distant Intramedullary Pressure and Bone Strain by Dynamic Hydraulic Stimulation

ASME 2011 Summer Bioengineering Conference, Parts A and B ◽

10.1115/sbc2011-54017 ◽

2011 ◽

Author(s):

Y. X. Qin ◽

M. Hu ◽

F. Serra-Hsu ◽

J. Cheng ◽

S. Ferreri ◽

...

Keyword(s):

Fluid Flow ◽

Bone Adaptation ◽

External Loading ◽

Bone Strain ◽

Dependent Manner ◽

Frequency Dependent ◽

Hydraulic Stimulation ◽

Bone Fluid Flow ◽

Intramedullary Pressure ◽

Osteogenic Response

Osteoporosis gives rise to fragile bones that have higher fracture risks due to diminished bone mass and altered bone microarchitecture [1]. Mechanical loading mediated bone adaptation has demonstrated promising potentials as a non-pharmacological alteration for both osteogenic response and attenuation of osteopenia [2]. Intramedullary pressure (ImP) has been proposed as a key factor for fluid flow initiation and mechanotransductive signal inductions in bone. It is also suggested that integration of strain signals over time allows low-level mechanical strain in the skeleton to trigger osteogenic activities. The potential bone fluid flow induced by strain and ImP mediates adaptive responses in the skeleton [3]. Previous in vivo studies using oscillatory electrical stimulations showed that dynamic muscle contractions can generate ImP and bone strain to mitigate disuse osteopenia in a frequency-dependent manner. To apply ImP alteration as a means for bone fluid flow regulation, it may be necessary to develop a new method that could couple external loading with internal bone fluid flow. In order to further study the direct effect of ImP on bone adaptation, it was hypothesized that external dynamic hydraulic stimulation (DHS) can generate ImP with minimal strain in a frequency-dependent manner. The aim of this study was to evaluate the immediate effects on local and distant ImP and bone strain induced by a novel, non-invasive dynamic external pressure stimulus in response to a range of loading frequencies.

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O23: CHARACTERISING PATIENT-DERIVED COLORECTAL CANCER TISSUE-ORIGINATED ORGANOIDAL SPHEROIDS FOR HIGH-THROUGHPUT MICROFLUIDIC APPLICATIONS

British Journal of Surgery ◽

10.1093/bjs/znab117.023 ◽

2021 ◽

Vol 108 (Supplement_1) ◽

Author(s):

MI Khot ◽

M Levenstein ◽

R Coppo ◽

J Kondo ◽

M Inoue ◽

...

Keyword(s):

Colorectal Cancer ◽

Fluid Flow ◽

High Throughput ◽

Microfluidic Devices ◽

In Vitro Models ◽

Fluorescent Imaging ◽

Cancer Tissue ◽

Cell Models

Abstract Introduction Three-dimensional (3D) cell models have gained reputation as better representations of in vivo cancers as compared to monolayered cultures. Recently, patient tumour tissue-derived organoids have advanced the scope of complex in vitro models, by allowing patient-specific tumour cultures to be generated for developing new medicines and patient-tailored treatments. Integrating 3D cell and organoid culturing into microfluidics, can streamline traditional protocols and allow complex and precise high-throughput experiments to be performed with ease. Method Patient-derived colorectal cancer tissue-originated organoidal spheroids (CTOS) cultures were acquired from Kyoto University, Japan. CTOS were cultured in Matrigel and stem-cell media. CTOS were treated with 5-fluorouracil and cytotoxicity evaluated via fluorescent imaging and ATP assay. CTOS were embedded, sectioned and subjected to H&E staining and immunofluorescence for ABCG2 and Ki67 proteins. HT29 colorectal cancer spheroids were produced on microfluidic devices using cell suspensions and subjected to 5-fluorouracil treatment via fluid flow. Cytotoxicity was evaluated through fluorescent imaging and LDH assay. Result 5-fluorouracil dose-dependent reduction in cell viability was observed in CTOS cultures (p<0.01). Colorectal CTOS cultures retained the histology, tissue architecture and protein expression of the colonic epithelial structure. Uniform 3D HT29 spheroids were generated in the microfluidic devices. 5-fluorouracil treatment of spheroids and cytotoxic analysis was achieved conveniently through fluid flow. Conclusion Patient-derived CTOS are better complex models of in vivo cancers than 3D cell models and can improve the clinical translation of novel treatments. Microfluidics can streamline high-throughput screening and reduce the practical difficulties of conventional organoid and 3D cell culturing. Take-home message Organoids are the most advanced in vitro models of clinical cancers. Microfluidics can streamline and improve traditional laboratory experiments.

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Myogenic Autoregulation in Bone Marrow Arterioles and In Vivo Intramedullary Pressure in Femora of Conscious, Female Long Evans Rats

Microcirculation ◽

10.1111/micc.12720 ◽

2021 ◽

Author(s):

S. Noh ◽

S. Lee ◽

S. Green ◽

R. Prisby

Keyword(s):

Bone Marrow ◽

Intramedullary Pressure ◽

Long Evans

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In Vivo Femoral Intramedullary Pressure During Uncemented Hip Arthroplasty

Clinical Orthopaedics and Related Research ◽

10.1097/00003086-199903000-00017 ◽

1999 ◽

Vol 360 ◽

pp. 136-146 ◽

Cited By ~ 25

Author(s):

Siegfried Hofmann ◽

Reinhard Hopf ◽

Gerald Mayr ◽

Gerhard Schlag ◽

Martin Salzer

Keyword(s):

Hip Arthroplasty ◽

Intramedullary Pressure ◽

Uncemented Hip Arthroplasty

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Oscillatory Compressional Behavior of Articular Cartilage and Its Associated Electromechanical Properties

Journal of Biomechanical Engineering ◽

10.1115/1.3138294 ◽

1981 ◽

Vol 103 (4) ◽

pp. 280-292 ◽

Cited By ~ 113

Author(s):

R. C. Lee ◽

E. H. Frank ◽

A. J. Grodzinsky ◽

D. K. Roylance

Keyword(s):

Fluid Flow ◽

Articular Cartilage ◽

Molecular Mechanisms ◽

Fluid Velocity ◽

Streaming Potential ◽

Usual Sense ◽

Frequency Range ◽

Confined Compression ◽

Streaming Potentials ◽

Compressive Stiffness

The compressive stiffness of articular cartilage was examined in oscillatory confined compression over a wide frequency range including high frequencies relevant to impact loading. Nonlinear behavior was found when the imposed sinusoidal compression amplitude exceeded a threshold value that depended on frequency. Linear behavior was attained only by suitable control of the compression amplitude. This was enabled by real time Fourier analysis of data which provided an accurate assessment of the extent of nonlinearity. For linear viscoelastic behavior, a stiffness could be defined in the usual sense. The dependence of the stiffness on ionic strength and proteoglycan content showed that electrostatic forces between matrix charge groups contribute significantly to cartilage’s compressive stiffness over the 0.001 to 20 Hz frequency range. Sinusoidal streaming potentials were also generated by oscillatory compression. A theory relating the streaming potential field to the fluid velocity field is derived and used to interpret the data. The observed magnitude of the streaming potential suggests that interstitial fluid flow is significant to cartilage behavior over the entire frequency range. The use of simultaneous streaming potential and stiffness data with an appropriate theory appears to be an important tool for assessing the relative contribution of fluid flow, intrinsic matrix viscoelasticity, or other molecular mechanisms to energy dissipation in cartilage. This method is applicable in general to hydrated, charged polymers.

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In Vitro Experimental Investigation of the Integrity of the Stem–Cement Interface

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.647.53 ◽

2013 ◽

Vol 647 ◽

pp. 53-56

Author(s):

Hong Yu Zhang ◽

Leigh Fleming ◽

Liam Blunt

Keyword(s):

Experimental Investigation ◽

Fluid Flow ◽

Hip Replacement ◽

Hip Prosthesis ◽

Vitro Experiment ◽

Cement Interface ◽

In Vitro Experiment ◽

Mechanical Bonding

The rationale behind failure of cemented total hip replacement is still far from being well understood in a mechanical and molecular perspective. In the present study, the integrity of the stem–cement interface was investigated through an in vitro experiment monitoring fluid flow along this interface. The results indicated that a good mechanical bonding formed at the stem–cement interface before debonding of this interface was induced by physiological loadings during the in vivo service of the hip prosthesis.

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