| review article | Q7318358 |
| scholarly article | Q13442814 |
| P2093 | author name string | Richard A Brand | |
| Clark M Stanford | |||
| Colby C Swan | |||
| P2860 | cites work | The mechanostat: a proposed pathogenic mechanism of osteoporoses and the bone mass effects of mechanical and nonmechanical agents | Q34174691 |
| Evaluation (not validation) of quantitative models | Q34942453 | ||
| Mechanical loading history and skeletal biology | Q39690685 | ||
| A survey of finite element analysis in orthopedic biomechanics: the first decade | Q40158239 | ||
| Implant stability, histology, RSA and wear--more critical questions are needed. A view point | Q40581489 | ||
| Differential effect of steady versus oscillating flow on bone cells | Q40982818 | ||
| The role of loading memory in bone adaptation simulations. | Q41041154 | ||
| Autonomous informational stability in connective tissues | Q41118309 | ||
| Pulsating fluid flow increases nitric oxide (NO) synthesis by osteocytes but not periosteal fibroblasts--correlation with prostaglandin upregulation | Q41659996 | ||
| Effect of cell growth rate and dose fractionation on chemically-induced ouabain-resistant mutations in Chinese hamster V79 cells | Q41699987 | ||
| Mechanotransduction in bone: osteoblasts are more responsive to fluid forces than mechanical strain | Q42835344 | ||
| Adaptive bone-remodeling theory applied to prosthetic-design analysis | Q43470451 | ||
| A new method to analyse the mechanical behaviour of skeletal parts | Q43646408 | ||
| Long-term clinical consequences of stress-shielding after total hip arthroplasty without cement | Q45105881 | ||
| Correlation of computed finite element stresses to bone density after remodeling around cementless femoral implants. | Q46020663 | ||
| Bone strength in small mammals and bipedal birds: do safety factors change with body size? | Q47267638 | ||
| Why do marathon runners have less bone than weight lifters? A vital-biomechanical view and explanation | Q47313366 | ||
| A homogenization sampling procedure for calculating trabecular bone effective stiffness and tissue level stress | Q48556188 | ||
| How connective tissues temporally process mechanical stimuli. | Q52059026 | ||
| Three rules for bone adaptation to mechanical stimuli. | Q52231198 | ||
| The adaptation of bone apparent density to applied load. | Q52351021 | ||
| Effects of fit and bonding characteristics of femoral stems on adaptive bone remodeling. | Q52367168 | ||
| Comparison of hip force calculations and measurements in the same patient. | Q52382113 | ||
| Toward an identification of mechanical parameters initiating periosteal remodeling: a combined experimental and analytic approach. | Q52507056 | ||
| Influence of physical activity on the regulation of bone density. | Q52579339 | ||
| A unifying principle relating stress to trabecular bone morphology. | Q52652287 | ||
| Effect of dose-rate and dose fractionation on radiation-induced hemolysis of human erythrocytes | Q62268670 | ||
| Adaptive bone-remodeling analysis | Q68011001 | ||
| Limitations of the continuum assumption in cancellous bone | Q68414928 | ||
| Bone remodeling of diaphyseal surfaces by torsional loads: theoretical predictions | Q68538091 | ||
| Mechanical influences in bone remodeling. Experimental research on Wolff's law | Q70360107 | ||
| On the mathematical analysis of stress in the human femur | Q70360115 | ||
| Early migration of acetabular components revised with cement. A roentgen stereophotogrammetric study | Q70598842 | ||
| Static vs dynamic loads as an influence on bone remodelling | Q70736644 | ||
| Different loads can produce similar bone density distributions | Q71647119 | ||
| Human osteoblast-like cells respond to mechanical strain with increased bone matrix protein production independent of hormonal regulation | Q71670729 | ||
| Migration of the Charnley stem in rheumatoid arthritis and osteoarthritis. A roentgen stereophotogrammetric study | Q72411493 | ||
| Computer simulations of stress-related bone remodeling around noncemented acetabular components | Q72756830 | ||
| Adaptive bone remodeling around bonded noncemented total hip arthroplasty: a comparison between animal experiments and computer simulation | Q72855744 | ||
| Strain gradients correlate with sites of periosteal bone formation | Q73382487 | ||
| Testing the daily stress stimulus theory of bone adaptation with natural and experimentally controlled strain histories | Q73549275 | ||
| Influence of stem geometry on mechanics of cemented femoral hip components with a proximal bond | Q74010906 | ||
| Partitioning a daily mechanical stimulus into discrete loading bouts improves the osteogenic response to loading | Q74141076 | ||
| Tissue stresses and strain in trabeculae of a canine proximal femur can be quantified from computer reconstructions | Q74533367 | ||
| Strain rate as a controlling influence on adaptive modeling in response to dynamic loading of the ulna in growing male rats | Q77379130 | ||
| P304 | page(s) | 13-22 | |
| P577 | publication date | 2003-01-01 | |
| P1433 | published in | The Iowa Orthopaedic Journal | Q26841877 |
| P1476 | title | How do tissues respond and adapt to stresses around a prosthesis? A primer on finite element stress analysis for orthopaedic surgeons | |
| P478 | volume | 23 |
| Q40280567 | 50 years ago in CORR: Biomechanics of hip prostheses. Duncan C. McKeever, MD CORR 1961;19:187-199. | cites work | P2860 |
Search more.