Your search keyword '"Tibia radiation effects"' showing total 11 results

1. Spaceflight-Relevant Challenges of Radiation and/or Reduced Weight Bearing Cause Arthritic Responses in Knee Articular Cartilage.

Author

Willey JS, Kwok AT, Moore JE, Payne V, Lindburg CA, Balk SA, Olson J, Black PJ, Walb MC, Yammani RR, and Munley MT

Subjects

Animals, Arthritis metabolism, Arthritis pathology, Biomarkers metabolism, Body Weight radiation effects, Cartilage, Articular metabolism, Cartilage, Articular pathology, Collagen metabolism, Femur metabolism, Femur physiopathology, Femur radiation effects, Glycosaminoglycans metabolism, Hindlimb Suspension adverse effects, Knee Joint physiopathology, Male, Rats, Rats, Sprague-Dawley, Tibia metabolism, Tibia physiopathology, Tibia radiation effects, Arthritis etiology, Arthritis physiopathology, Cartilage, Articular physiopathology, Cartilage, Articular radiation effects, Knee Joint radiation effects, Space Flight, Weight-Bearing

Abstract

There is little known about the effect of both reduced weight bearing and exposure to radiation during spaceflight on the mechanically-sensitive cartilage lining the knee joint. In this study, we characterized cartilage damage in rat knees after periods of reduced weight bearing with/without exposure to solar-flare-relevant radiation, then cartilage recovery after return to weight bearing. Male Sprague Dawley rats (n = 120) were either hindlimb unloaded (HLU) via tail suspension or remained weight bearing in cages (GROUND). On day 5, half of the HLU and GROUND rats were 1 Gy total-body X-ray irradiated during HLU, and half were sham irradiated (SHAM), yielding 4 groups: GROUND-SHAM; GROUND-IR; HLU-SHAM; and HLU-IR. Hindlimbs were collected from half of each group of rats on day 13. The remaining rats were then removed from HLU or remained weight bearing, and hindlimbs from these rats were collected on day 62. On day 13, glycosaminoglycan (GAG) content in cartilage lining the tibial plateau and femoral condyles of HLU rats was lower than that of the GROUND animals. Likewise, on day 13, immunoreactivity of the collagen type II-degrading matrix metalloproteinase-13 (MMP-13) and of a resultant metalloproteinase-generated neoepitope VDIPEN was increased in all groups versus GROUND-SHAM. Clustering of chondrocytes indicating cartilage damage was present in all HLU and IR groups versus GROUND-SHAM on day 13. On day 62, after 49 days of reloading, the loss of GAG content was attenuated in the HLU-SHAM and HLU-IR groups, and the increased VDIPEN staining in all treatment groups was attenuated. However, the increased chondrocyte clustering remained in all treatment groups on day 62. MMP-13 activity also remained elevated in the GROUND-IR and HLU-IR groups. Increased T2 relaxation times, measured on day 62 using 7T MRI, were greater in GROUND-IR and HLU-IR knees, indicating persistent cartilage damage in the irradiated groups. Both HLU and total-body irradiation resulted in acute degenerative and pre-arthritic changes in the knee articular cartilage of rats. A return to normal weight bearing resulted in some recovery from cartilage degradation. However, radiation delivered as both a single challenge and when combined with HLU resulted in chronic cartilage damage. These findings suggest that radiation exposure during spaceflight leads to and/or impairs recovery of cartilage upon return to reloading, generating long-term joint problems for astronauts.

Published

2016

2. Short-term effects of whole-body exposure to (56)fe ions in combination with musculoskeletal disuse on bone cells.

Author

Yumoto K, Globus RK, Mojarrab R, Arakaki J, Wang A, Searby ND, Almeida EA, and Limoli CL

Subjects

Animals, Cell Differentiation radiation effects, Cells, Cultured, Dose-Response Relationship, Radiation, Heavy Ions, Iron Isotopes, Male, Mice, Mice, Inbred C57BL, Radiation Dosage, Hindlimb Suspension, Osteoblasts cytology, Osteoblasts radiation effects, Osteoclasts cytology, Osteoclasts radiation effects, Tibia cytology, Tibia radiation effects, Whole-Body Irradiation

Abstract

Space travel and prolonged bed rest cause bone loss due to musculoskeletal disuse. In space, radiation fields may also have detrimental consequences because charged particles traversing the tissues of the body can elicit a wide range of cytotoxic and genotoxic lesions. The effects of heavy-ion radiation exposure in combination with musculoskeletal disuse on bone cells and tissue are not known. To explore this, normally loaded 16-week-old male C57BL/6 mice were exposed to (56)Fe ions (1 GeV/nucleon) at doses of 0 cGy (sham), 10 cGy, 50 cGy or 2 Gy 3 days before tissue harvest. Additional mice were hindlimb unloaded by tail traction continuously for 1 week to simulate weightlessness and exposed to (56)Fe-ion radiation (0 cGy, 50 cGy, 2 Gy) 3 days before tissue harvest. Despite the short duration of this study, low-dose (10, 50 cGy) irradiation of normally loaded mice reduced trabecular volume fraction (BV/TV) in the proximal tibiae by 18% relative to sham-irradiated controls. Hindlimb unloading together with 50 cGy radiation caused a 126% increase in the number of TRAP(+) osteoclasts on cancellous bone surfaces relative to normally loaded, sham-irradiated controls. Together, radiation and hindlimb unloading had a greater effect on suppressing osteoblastogenesis ex vivo than either treatment alone. In sum, low-dose exposure to heavy ions (50 cGy) caused rapid cancellous bone loss in normally loaded mice and increased osteoclast numbers in hindlimb unloaded mice. In vitro irradiation also was more detrimental to osteoblastogenesis in bone marrow cells that were recovered from hindlimb unloaded mice compared to cells from normally loaded mice. Furthermore, irradiation in vitro stimulated osteoclast formation in a macrophage cell line (RAW264.7) in the presence of RANKL (25 ng/ml), showing that heavy-ion radiation can stimulate osteoclast differentiation even in the absence of osteoblasts. Thus heavy-ion radiation can acutely increase osteoclast numbers in cancellous tissue and, under conditions of musculoskeletal disuse, can enhance the sensitivity of bone cells, in particular osteoprogenitors, to the effects of radiation.

Published

2010

3. Musculoskeletal changes in mice from 20-50 cGy of simulated galactic cosmic rays.

Author

Bandstra ER, Thompson RW, Nelson GA, Willey JS, Judex S, Cairns MA, Benton ER, Vazquez ME, Carson JA, and Bateman TA

Subjects

Animals, Body Weight radiation effects, Humerus diagnostic imaging, Humerus pathology, Male, Mice, Mice, Inbred C57BL, Organ Size, Radiation Dosage, Tibia diagnostic imaging, Tibia pathology, X-Ray Microtomography, Bone Density radiation effects, Cosmic Radiation adverse effects, Humerus radiation effects, Muscle Fibers, Skeletal radiation effects, Tibia radiation effects

Abstract

On a mission to Mars, astronauts will be exposed to a complex mix of radiation from galactic cosmic rays. We have demonstrated a loss of bone mass from exposure to types of radiation relevant to space flight at doses of 1 and 2 Gy. The effects of space radiation on skeletal muscle, however, have not been investigated. To evaluate the effect of simulated galactic cosmic radiation on muscle fiber area and bone volume, we examined mice from a study in which brains were exposed to collimated iron-ion radiation. The collimator transmitted a complex mix of charged secondary particles to bone and muscle tissue that represented a low-fidelity simulation of the space radiation environment. Measured radiation doses of uncollimated secondary particles were 0.47 Gy at the proximal humerus, 0.24-0.31 Gy at the midbelly of the triceps brachii, and 0.18 Gy at the proximal tibia. Compared to nonirradiated controls, the proximal humerus of irradiated mice had a lower trabecular bone volume fraction, lower trabecular thickness, greater cortical porosity, and lower polar moment of inertia. The tibia showed no differences in any bone parameter. The triceps brachii of irradiated mice had fewer small-diameter fibers and more fibers containing central nuclei. These results demonstrate a negative effect on the skeletal muscle and bone systems of simulated galactic cosmic rays at a dose and LET range relevant to a Mars exploration mission. The presence of evidence of muscle remodeling highlights the need for further study.

Published

2009

4. Inter- and intramouse heterogeneity of radiation response for a growing paired organ.

Author

Kozin SV, Niemierko A, Huang P, Silva J, Doppke KP, and Suit HD

Subjects

Animals, Dose-Response Relationship, Radiation, Mice, Mice, Inbred C3H, Radiation Dosage, Sensitivity and Specificity, Tibia growth & development, Tibia radiation effects

Abstract

An intensive search for predictive markers of individual radiation response of apparently normal tissues in cancer patients is in progress at the genetic and epigenetic levels. However, the relative impact of variability at these levels is not clear. Experimental results obtained in inbred rodents, which have significantly reduced genetic heterogeneity relative to a population of human patients, may help to clarify this issue. We investigated a paired-organ mouse system in a strain of inbred mice to evaluate the intermouse variability of normal tissue radiation response, singled out from measurement errors and stochastic effects. The legs of 5-day-old C3H mice were homogeneously gamma-irradiated with a range of single doses. The lengths of the right and left tibiae were measured in 30 kVp X-ray images taken at the time of irradiation and at 84 days postirradiation. The dose-effect curves were smooth and well defined, with bone growth retardation evident at approximately 14 Gy and higher, and were marginally gender-dependent. The intramouse (left compared to right) variability of the tibia length on day 89, which characterized stochastic effects, was not distinguishable from the measurement error for doses less than 16-18 Gy and slightly exceeded measurement errors only at the largest doses of 20-22 Gy. The corresponding intermouse variability was greater than the measurement error and stochastic effects at all doses used. Interestingly, the total variability, judged by the gamma(50) values of approximately 7 we obtained, was similar to that reported for severe late reactions in human normal tissue. If the variations of response determined by epigenetic events in human patients free of known factors associated with altered radiation sensitivity are comparable to those observed in this mouse model, our results imply a relatively low power of genetic approaches alone to predict individual side effects in radiotherapy.

Published

2008

5. Bone architectural and structural properties after 56Fe26+ radiation-induced changes in body mass.

Author

Willey JS, Grilly LG, Howard SH, Pecaut MJ, Obenaus A, Gridley DS, Nelson GA, and Bateman TA

Subjects

Animals, Dose-Response Relationship, Radiation, Heavy Ions, Male, Radiation Dosage, Radiography, Rats, Rats, Sprague-Dawley, Tibia diagnostic imaging, Body Weight physiology, Body Weight radiation effects, Iron Radioisotopes, Tibia physiology, Tibia radiation effects, Whole-Body Irradiation

Abstract

High-energy, high-charge (HZE) radiation, including iron ions ((56)Fe(26+)), is a component of the space environment. We recently observed a profound loss of trabecular bone in mice after whole-body HZE irradiation. The goal of this study was to examine morphology in bones that were excluded from a (56)Fe(26+) beam used to irradiate the body. Using 10-week-old male Sprague-Dawley rats and excluding the hind limbs and pelvis, we irradiated animals with 0, 1, 2 and 4 Gy (56)Fe(26+) ions and killed them humanely after 9 months. Animals grew throughout the experiment. Trabecular bone volume, connectivity and thickness within the proximal tibiae were significantly lower than control in a dose-dependent manner. Irradiated animals generally had less body mass than controls, which largely accounted for the variability in bone parameters as determined by ANCOVA. Likewise, lower cortical parameters were associated with reduced mass. However, lesser trabecular thickness in the 4-Gy group could not be attributed to body mass alone. Indicators of bone metabolism were generally unchanged, suggesting stabilized turnover. Exposure to (56)Fe(26+) ions can alter trabecular microarchitecture in shielded bones. Reduced body mass seems to be correlated with these deficits of trabecular and cortical bone.

Published

2008

6. Long-term dose response of trabecular bone in mice to proton radiation.

Author

Bandstra ER, Pecaut MJ, Anderson ER, Willey JS, De Carlo F, Stock SR, Gridley DS, Nelson GA, Levine HG, and Bateman TA

Subjects

Animals, Dose-Response Relationship, Radiation, Female, Mice, Mice, Inbred C57BL, Radiation, Ionizing, Stress, Mechanical, Sunlight, Synchrotrons, Tomography, X-Ray Computed methods, Ultraviolet Rays, Bone and Bones radiation effects, Femur radiation effects, Protons, Tibia radiation effects

Abstract

Astronauts on exploratory missions will experience a complex environment, including microgravity and radiation. While the deleterious effects of unloading on bone are well established, fewer studies have focused on the effects of radiation. We previously demonstrated that 2 Gy of ionizing radiation has deleterious effects on trabecular bone in mice 4 months after exposure. The present study investigated the skeletal response after total doses of proton radiation that astronauts may be exposed to during a solar particle event. We exposed mice to 0.5, 1 or 2 Gy of whole-body proton radiation and killed them humanely 117 days later. Tibiae and femora were analyzed using microcomputed tomography, mechanical testing, mineral composition and quantitative histomorphometry. Relative to control mice, mice exposed to 2 Gy had significant differences in trabecular bone volume fraction (-20%), trabecular separation (+11%), and trabecular volumetric bone mineral density (-19%). Exposure to 1 Gy radiation induced a nonsignificant trend in trabecular bone volume fraction (-13%), while exposure to 0.5 Gy resulted in no differences. No response was detected in cortical bone. Further analysis of the 1-Gy mice using synchrotron microCT revealed a significantly lower trabecular bone volume fraction (-13%) than in control mice. Trabecular bone loss 4 months after exposure to 1 Gy highlights the importance of further examination of how space radiation affects bone.

Published

2008

7. Early ultrastructural changes in osteocytes from the proximal tibial metaphysis of mice after the incorporation of 224 Ra1,2.

Author

Marquart KH

Subjects

Animals, Cell Nucleus radiation effects, Cell Nucleus ultrastructure, Endoplasmic Reticulum radiation effects, Endoplasmic Reticulum ultrastructure, Female, Golgi Apparatus radiation effects, Golgi Apparatus ultrastructure, Mice, Mitochondria radiation effects, Mitochondria ultrastructure, Osteocytes ultrastructure, Tibia ultrastructure, Osteocytes radiation effects, Radium, Tibia radiation effects

Published

1977

8. Effects of radiation on bone formation: a functional assessment.

Author

Morse BS, Giuliani D, and Giuliani ER

Subjects

Animals, Estrone pharmacology, Female, Mice, Osteogenesis drug effects, Radiation Tolerance, Stimulation, Chemical, Strontium Radioisotopes pharmacokinetics, Tibia drug effects, Osteogenesis radiation effects, Tibia radiation effects

Published

1974

9. Age and dose dependence of bone growth retardation induced by x-irradiation.

Author

Phillips RD and Kimeldorf DJ

Subjects

Animals, Femur radiation effects, Male, Radiometry, Rats, Tibia radiation effects, Aging, Bone Development radiation effects, Radiation Effects

Published

1966

10. Radiobiological investigations on embryonic rat bone grown in vitro.

Author

Mawhinney BS and Kember NF

Subjects

Animals, Culture Media, Culture Techniques, Embryo, Mammalian, Embryo, Nonmammalian, Epiphyses radiation effects, Nitrogen, Oxygen, Bone Development radiation effects, Radiation Effects, Tibia radiation effects

Published

1969

11. The effect of x-irradiation on the marrow blood volume in rat tibia.

Author

Gong JK, Vertalino JE, and Kane MJ

Subjects

Animals, Erythrocytes, Injections, Intravenous, Iron Isotopes, Rats, Serum Albumin, Radio-Iodinated, Time Factors, Blood Volume radiation effects, Bone Marrow radiation effects, Radiation Effects, Tibia radiation effects

Published

1969