| scholarly article | Q13442814 |
| P356 | DOI | 10.1143/JPSJ.12.1158 |
| P5875 | ResearchGate publication ID | 274365321 |
| P2093 | author name string | Eiichi Fukada | |
| Iwao Yasuda | |||
| P433 | issue | 10 | |
| P304 | page(s) | 1158-1162 | |
| P577 | publication date | 1957-10-15 | |
| P1433 | published in | Journal of the Physical Society of Japan | Q2038117 |
| P1476 | title | On the Piezoelectric Effect of Bone | |
| P478 | volume | 12 |
| Q71085212 | A holographic study of bone displacement induced by an applied voltage |
| Q41630076 | A linear piezoelectric model for characterizing stress generated potentials in bone |
| Q51599545 | A multiscale theoretical investigation of electric measurements in living bone : piezoelectricity and electrokinetics. |
| Q36985805 | A new direction for osteoporosis research: A review and proposal |
| Q69061784 | A pulsed electrical stimulation technique for inducing bone growth |
| Q44879658 | A quantitative method for the application of compressive forces to bone in tissue culture |
| Q73044033 | A study of piezoelectric and mechanical anisotropies of the human cornea |
| Q51565837 | A theoretical study of bone remodelling under PEMF at cellular level. |
| Q39916363 | A theory of piezoelectric activity and ion-movements in the relation of flagellar structures and their movements to the phototaxis of Euglena |
| Q53625269 | Absence of systemic toxicity in mouse model towards BaTiO3 nanoparticulate based eluate treatment. |
| Q46290050 | Anisotropy effects of EPR signals and mechanisms of mass transfer in tooth enamel and bones |
| Q58762784 | BioFerroelectricity: Diphenylalanine Peptide Nanotubes Computational Modeling and Ferroelectric Properties at the Nanoscale |
| Q70222200 | Biochemical pathways involved in the translation of physical stimulus into biological message |
| Q42832202 | Biocompatibility of ferroelectric lithium niobate and the influence of polarization charge on osteoblast proliferation and function |
| Q57307486 | Bioelectricity and microcurrent therapy for tissue healing – a narrative review |
| Q42038798 | Bioelectromechanical imaging by scanning probe microscopy: Galvani's experiment at the nanoscale. |
| Q37828488 | Bioinspired peptide nanotubes: deposition technology, basic physics and nanotechnology applications |
| Q39983896 | Biologic significance of piezoelectricity |
| Q37496374 | Biological aspects and clinical importance of ultrasound therapy in bone healing. |
| Q53096845 | Biological ferroelectricity uncovered in aortic walls by piezoresponse force microscopy. |
| Q41035750 | Biological significance of piezoelectricity in relation to acupuncture, Hatha Yoga, osteopathic medicine and action of air ions |
| Q71783233 | Biophysical aspects of normal and regenerating bone cortex |
| Q36106989 | Blood Stage Plasmodium falciparum Exhibits Biological Responses to Direct Current Electric Fields |
| Q69002939 | Bone Growth in Organ Culture Modified by an Electric Field |
| Q40239426 | Bone Metabolism Associated With Tooth Eruption and Orthodontic Tooth Movement |
| Q33741867 | Bone and bone healing |
| Q37794095 | Bone bioelectricity: What have we learned in the past 160 years? |
| Q48924873 | Bone density changes in osteoporosis-prone women exposed to pulsed electromagnetic fields (PEMFs). |
| Q30467681 | Bone dielectric property variation as a function of mineralization at microwave frequencies |
| Q43515777 | Bone remodeling and piezoelectricity — I |
| Q52949946 | Bone remodeling and piezoelectricity — II |
| Q39930908 | Bone resorption and prosthodontics |
| Q34276207 | Bone's mechanostat: A 2003 update |
| Q57864125 | Calculating anisotropic piezoelectric properties from texture data using the MTEX open source package |
| Q70195831 | Capacitative pulsed electric stimulation of bone cells. Induction of cyclic-AMP changes and DNA synthesis |
| Q37462478 | Cellular effects of extremely low frequency (ELF) electromagnetic fields. |
| Q54227296 | Changing concepts in skeletal physiology: Wolff's Law, the Mechanostat, and the "Utah Paradigm". |
| Q38761000 | Choice of osteoblast model critical for studying the effects of electromagnetic stimulation on osteogenesis in vitro |
| Q40709844 | Clinical aspects of the stimulation of bone healing using electrical phenomena |
| Q74278696 | Clinical report on long-term bone density after short-term EMF application |
| Q39236351 | Combined effects of direct current stimulation and immobilized BMP-2 for enhancement of osteogenesis. |
| Q45304246 | Comparative study of the efficacy of the topical application of hydrocortisone, therapeutic ultrasound and phonophoresis on the tissue repair process in rat tendons |
| Q54273986 | Comparison of asymmetrical and symmetrical pulse waveforms in electromagnetic stimulation |
| Q47589520 | Control of piezoelectricity in amino acids by supramolecular packing. |
| Q28741379 | Degenerate wave and capacitive coupling increase human MSC invasion and proliferation while reducing cytotoxicity in an in vitro wound healing model |
| Q39824502 | Development and Characterization of Organic Electronic Scaffolds for Bone Tissue Engineering |
| Q58459229 | Dynamic piezoelectric stimulation enhances osteogenic differentiation of human adipose stem cells |
| Q71787983 | Effect of constant and modulated electrical charges applied to the culture material on PGI2 and TXA2 secretion by endothelial cells |
| Q50898243 | Effect of direct current on cultured growth cartilage cells in vitro |
| Q59086379 | Effects of Electric Currents on Bone In Vivo |
| Q53008584 | Effects of electric fields on human mesenchymal stem cell behaviour and morphology using a novel multichannel device. |
| Q39935127 | Effects of extremely low-frequency-pulsed electromagnetic field on different-derived osteoblast-like cells |
| Q50279302 | Effects of low frequency electromagnetic fields on the chondrogenic differentiation of human mesenchymal stem cells |
| Q34148970 | Effects of low-energy NMR on posttraumatic osteoarthritis: observations in a rabbit model. |
| Q40719182 | Effects of pulsed electromagnetic field (PEMF) stimulation on bone tissue like formation are dependent on the maturation stages of the osteoblasts |
| Q40077744 | Effects of weak, low-frequency pulsed electromagnetic fields (BEMER type) on gene expression of human mesenchymal stem cells and chondrocytes: an in vitro study |
| Q47442577 | Electrets in soft materials: nonlinearity, size effects, and giant electromechanical coupling |
| Q70945372 | Electric potentials recorded from mandibular alveolar bone as a result of forces applied to the tooth |
| Q70510416 | Electrical Behavior of Cartilage during Loading |
| Q59050273 | Electrical Properties of Wet Collagen |
| Q58077082 | Electrical Stimulation of Osteogenesis:Studies of the Cathode Effect on Rabbit Femur |
| Q53803761 | Electrical and Piezo-electrical Properties of Dental Hard Tissues |
| Q39438390 | Electrical bone-growth stimulation in an experimental model of delayed union |
| Q35549010 | Electrical implications of corrosion for osseointegration of titanium implants |
| Q39249715 | Electrical stimulation modulates osteoblast proliferation and bone protein production through heparin-bioactivated conductive scaffolds. |
| Q41519746 | Electrical stimulation of osteogenesis in pathological osseous defects |
| Q46556770 | Electrically Polarized Biomaterials |
| Q33841324 | Electromagnetic fields and magnets. Investigational treatment for musculoskeletal disorders |
| Q60096233 | Electron Paramagnetic Resonance in Non-irradiated Bone |
| Q50456142 | Enhancement of adhesion and promotion of osteogenic differentiation of human adipose stem cells by poled electroactive poly(vinylidene fluoride). |
| Q46840941 | Evaluation of electric field distribution in electromagnetic stimulation of human femoral head. |
| Q59033676 | Evaluation of the effects of different surface configurations on stability of miniscrews |
| Q59013369 | Experimental Model for Studying the Effect of Electric Current on Bone in vivo |
| Q44674422 | Experimental production of osseous reactions on metal implants. Influencing of the priosteal bone formation through mechanical tensions |
| Q39844892 | Extremely Low Frequency Electromagnetic Field in Mesenchymal Stem Cells Gene Regulation: Chondrogenic Markers Evaluation. |
| Q30361937 | Fabrication and in vitro biological properties of piezoelectric bioceramics for bone regeneration |
| Q38647411 | Fabrication of Biocompatible Potassium Sodium Niobate Piezoelectric Ceramic as an Electroactive Implant |
| Q26771985 | Fabrication, Properties and Applications of Dense Hydroxyapatite: A Review |
| Q30421164 | Ferroelectric switching of elastin. |
| Q68591611 | Frequency specific modulation of bone adaptation by induced electric fields |
| Q33895674 | Gap junctions and biophysical regulation of bone cell differentiation |
| Q39879867 | Generation of Hall Voltage in Bone |
| Q50989284 | Glucose suppresses biological ferroelectricity in aortic elastin. |
| Q39190983 | HOW DO BONE CELLS SENSE MECHANICAL LOADING? |
| Q54729055 | Hemodynamic deformation of alveolar socket walls. |
| Q72140651 | Human histologic tissue response after long-term orthodontic tooth movement |
| Q35685991 | Immobilization osteoporosis in paraplegia |
| Q42330312 | In vitro effect of direct current electrical stimulation on rat mesenchymal stem cells. |
| Q74469336 | Influence of extremely low frequency magnetic fields on chromosomes and the mitotic cycle in Vicia faba L., the broad bean |
| Q68178592 | Influence of shock waves on fracture healing |
| Q52894823 | Influences of osteoarthritis and osteoporosis on the electrical properties of human bones as in vivo electrets produced due to Wolff's law. |
| Q77841897 | Interleukin-1beta and beta-glucuronidase in gingival crevicular fluid from molars during rapid palatal expansion |
| Q33356592 | Intraoperative measurement of bone electrical potential: a piece in the puzzle of understanding fracture healing |
| Q92643728 | Investigation of The Cellular Response to Bone Fractures: Evidence for Flexoelectricity |
| Q48013972 | Local and holistic electromagnetic therapies |
| Q62855128 | Local bias-induced phase transitions |
| Q59144629 | MG-63 Cell Proliferation with Static or Dynamic Compressive Stimulation on an Auxetic PLGA Scaffold |
| Q38788723 | Mechanistic contribution of electroconductive hydroxyapatite-titanium disilicide composite on the alignment and proliferation of cells |
| Q45370628 | Mechanotransduction in cortical bone and the role of piezoelectricity: a numerical approach |
| Q54212179 | Midroelectrode studies of stress-generated potentials in four-point bending of bone |
| Q28540994 | Moderate-intensity rotating magnetic fields do not affect bone quality and bone remodeling in hindlimb suspended rats |
| Q37333093 | Molecular ferroelectrics: where electronics meet biology |
| Q42806025 | Morphologic responses of osteoblast-like cells in monolayer culture to ELF electromagnetic fields |
| Q38071997 | Nanoscale flexoelectricity. |
| Q40711062 | Nitric oxide mediates the effects of pulsed electromagnetic field stimulation on the osteoblast proliferation and differentiation |
| Q30873266 | Non-pharmacological treatments in the stimulation of osteogenesis |
| Q41757310 | Nonunion of a Hawkin's group II talar neck fracture without avascular necrosis |
| Q72374908 | On the origin of electrical effects produced by stress in the hard tissues of living organisms |
| Q31004451 | Optimization of electrical stimulation parameters for enhanced cell proliferation on biomaterial surfaces |
| Q67271944 | Orchestration of tooth movement |
| Q40598955 | Orthodontic movement using pulsating force-induced piezoelectricity |
| Q35156473 | Osteocyte shape and mechanical loading |
| Q30483106 | Outer hair cell piezoelectricity: Frequency response enhancement and resonance behavior |
| Q38659295 | Overcoming physical constraints in bone engineering: 'the importance of being vascularized'. |
| Q40613094 | Overview of effects of electrical stimulation on osteogenesis and alveolar bone |
| Q59128926 | PEDOT:PSS-Containing Nanohydroxyapatite/Chitosan Conductive Bionanocomposite Scaffold: Fabrication and Evaluation |
| Q72787792 | Painful Heel Syndrome: Rationale of Diagnosis and Treatment |
| Q56568082 | Part III. Clinical Studies: MECHANICAL AND ELECTRICAL CALLUS |
| Q50767834 | Periodontal conditions after facial root tipping and palatal root torque of incisors |
| Q59056410 | Permanent Longitudinal Electric Polarization and Pyroelectric Behaviour of Collagenous Structures and Nervous Tissue in Man and other Vertebrates |
| Q37800618 | Photosensitive materials and potential of photocurrent mediated tissue regeneration |
| Q33582369 | Physical approach for prevention and treatment of osteoporosis |
| Q59062152 | Piezoelectric Activity in Invertebrate Exoskeletons |
| Q59080810 | Piezoelectric Effect and Growth Control in Bone |
| Q59074672 | Piezoelectric Effect in Bone |
| Q59006894 | Piezoelectric Effect in Poly-γ-methyl-L-glutamate |
| Q59086000 | Piezoelectric Properties of Dry and Wet Bone |
| Q51542804 | Piezoelectric allostery of protein. |
| Q28658206 | Piezoelectric energy harvesting solutions |
| Q59299552 | Piezoelectric poly(vinylidene fluoride) microstructure and poling state in active tissue engineering |
| Q40154452 | Piezoelectric properties of biological polymers |
| Q45194032 | Piezoelectric properties of bone as functions of moisture content |
| Q74190775 | Piezoelectric response of scleral collagen |
| Q59080155 | Piezoelectricity as a Fundamental Property of Biological Tissues |
| Q59085633 | Piezoelectricity in hydrated frozen bone and tendon |
| Q53019983 | Piezoelectricity in polymers and biological materials |
| Q41779841 | Piezoelectricity in tendon and bone |
| Q30383189 | Poromicromechanics reveals that physiological bone strains induce osteocyte-stimulating lacunar pressure. |
| Q40908925 | Prospects on clinical applications of electrical stimulation for nerve regeneration |
| Q59096746 | Pyroelectric Effect in Bone and Tendon |
| Q36925325 | Reconstructive Effects of Percutaneous Electrical Stimulation Combined with GGT Composite on Large Bone Defect in Rats |
| Q45154647 | Relation between bone mass and muscle weight |
| Q68393516 | Scaphoid screws |
| Q30829444 | Self-assembly of diphenylalanine peptide with controlled polarization for power generation. |
| Q47225636 | Sequential application of mineralized electroconductive scaffold and electrical stimulation for efficient osteogenesis. |
| Q71596632 | Simulation of condylar growth in the cat with pulsating electromagnetic currents |
| Q36995630 | Spinal facet joint biomechanics and mechanotransduction in normal, injury and degenerative conditions |
| Q69837793 | Spontaneous regeneration of the mandible in a child. A sequel to partial avulsion as a result of a war injury |
| Q77761825 | Statistical characterization of piezoelectric coefficient d23 in cow bone |
| Q44736682 | Strain-related potentials in living bone |
| Q70912697 | Stress generated electric potentials in the mandible and teeth |
| Q51446926 | Strong correlation between early stage atherosclerosis and electromechanical coupling of aorta. |
| Q42819729 | Subcutaneous tissue reaction and cytotoxicity of polyvinylidene fluoride and polyvinylidene fluoride-trifluoroethylene blends associated with natural polymers. |
| Q38388992 | Supramolecular ferroelectrics |
| Q37869360 | Supramolecular self-assembly of biopolymers with carbon nanotubes for biomimetic and bio-inspired sensing and actuation |
| Q36065700 | Systemic treatment with pulsed electromagnetic fields do not affect bone microarchitecture in osteoporotic rats |
| Q70531314 | Tensile forces in skeletal structures |
| Q40022570 | The Electrical Phenomena in Bone: A Review. A Possible Direction for the Treatment of Osseous Defects |
| Q34229693 | The Origin of Bioelectric Effects in Mineralized Tissues |
| Q54429395 | The Use of Electricity in Ligament and Tendon Repair. |
| Q39789344 | The biomechanical effects of simulated osseous surgery |
| Q47775859 | The effect of electric current on rat tail tendon collagen in solution |
| Q52995447 | The effect of electric current on the healing time of crural fractures. |
| Q77626221 | The effect of therapeutic ultrasound on repair of the achilles tendon (tendo calcaneus) of the rat |
| Q67365309 | The effect of ultraviolet radiation on the electrical conductivity of human bone |
| Q40870752 | The future of orthodontic materials: the long-term view |
| Q39342189 | The increase in vivo by electric currents of the 99mTc-methylene diphosphonate uptake and cyclic AMP content of the bone of the cat mandible |
| Q67258465 | The radiologist, the orthopedist, the lawyer, and the fracture |
| Q53039850 | The role of the collaborative functions of the composite structure of organic and inorganic constituents and their influence on the electrical properties of human bone. |
| Q41863732 | The thermodynamic driving force for bone growth and remodelling: a hypothesis |
| Q58971738 | Thermal Expansion Coefficients and the Primary and Secondary Pyroelectric Coefficients of Animal Bone |
| Q36786951 | Tooth Movement |
| Q59003833 | Transformation of Fibrous Tissue to Bone In Vivo |
| Q47403999 | Treatment of distal radius fractures with a wrist-bridging external fixation: the value of alternating electric current stimulation |
| Q30880775 | Treatment of osteoporosis by long-term magnetic field with extremely low frequency in rats |
| Q70050409 | Treatment of un-united fractures of the shaft of the humerus with bent nail |
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| Q35134847 | Ultrasound stimulation of maxillofacial bone healing |
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| Q69061768 | Uptake of tritiated thymidine during electrical stimulation of induced cortical bone defects |
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