Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

57, 1, pp. 235-248, Warsaw 2019
DOI: 10.15632/jtam-pl.57.1.235

STRENGHTH ANALYSIS OF HIP JOINT REPLACEMENT

REVISION IMPLANT

Paweł Skowronek
Clinic of Orthopaedics and Traumatology, Regional Hospital and Jan Kochanowski University Kielce, Poland

e-mail: pawel skowronek@interia.pl

Krzysztof Twardoch, Piotr Skawiński
Warsaw University of Technology, Institute of Machine Design Fundamentals, Warszawa, Poland

e-mail: krzysztof.twardoch@pw.edu.pl; psk@simr.pw.edu.pl

Marcel Żołnierz
Silesian University of Technology, Department of Mining Mechanisation and Robotisation, Gliwice, Poland

e-mail: marcel.zolnierz@polsl.pl

The subject of the article is the evaluation of the strength of revision implants made of
titanium or tantalum alloy, used during bone reconstruction of a hip joint while potentially
usingadditional stabilizing screws,necessarydue to significantbone loss.Thearticleprovides
a preliminary strength analysis of implants, indispensable for further evaluation of strength
limitations due to the risk of implant damage depending on the structure and number of
additional screw holes. In the human locomotor system, the hip joint is the joint with the
most load, hence themain problem is to establish an adequate loadmodelwhich ought to be
assumed for the needs of implant strength analysis. It is found necessary to perform a short,
analytical review of the existing hip joint load models from the point of view of choosing
the proper one, considering evaluation of implant strength by means of numerical studies
using FEM.Differences in the implant load distribution depending on the usedmaterial are
shown.

Keywords: implant, implant strength, prosthesis, hip joint, material loss

1. Introduction

The treatment method that WHO considers the one which completely resolved symptoms and
deformations resulting from Degenerative Joint Disease (DJD) is currently the primary Total
Hip Replacement (THR). With higher life expectancy of patients, the number of people suffe-
ring from advanced degenerative lesions of joints is growing (DJD). Having reduced mortality
resulting from heart and cardiovascular diseases within the last two decades, the number of
patients suffering fromDJD and treated with THR has grown. It has become a wider problem,
also in reference to biological and mechanical aspects of prostheses degenerating bone tissue,
which is currently the object of a few technical studies, e.g. evaluating the strength of bone
cement in configurationwith titanium implants and decreased quality of bone tissue (Benouis et
al., 2016). Together with the number of primary joints replacements, the number of secondary-
-revision procedures is also growing, consisting in replacing prostheses with the new ones, e.g.
due to pelvic bone or femur defects.Unfortunately, they are often implanted in acetabulumbone
with bone losses that need procedures using modular reconstruction implants. These implants
must possess appropriate strength and elasticity, enabling own load, must provide a reliable
andmultidirectional primary stabilization in bone tissue and secondary osseointegration of bone



236 P. Skowronek et al.

tissue in the implant. Thus, it is more and more common to use porous revision implants du-
ring joint reconstruction, which allows one to replace bone tissue with metal elements. The
most commonly used are so called “full” ones, which possess only the external porous structure
(most often hydroxyapatite layer) (Dorman et al., 2011) and“trabecularmetal” type of implants
with full spatial porous architecture enabling reconstruction of the bone tissue into the implant
(Dorman et al., 2011). The applied implants are made of titanium and its alloys or of tanta-
lum. The percentage composition of the applied metals is up to the producer. In most cases,
titanium implants are made of titanium alloy with addition of rare metals such as Vanadium
(Ti-6Al-4V-ELI) and Niobium (Ti-6Al-7Nb). In the case of spatial tantalum implants, only a
tantalum foam sintered powder is used. It is thematerial with better bone biocompatibility and
more biologically neutral for the organism, in comparison with rare metals used in titanium
alloys. The implants aremanufactured in different shapes and sizes, which allows one to fully or
partially adjust them to bone losses, leading to reconstruction of anatomy with proper biome-
chanics of the joint. The essence of proper implant functioning is, apart from osteointegration
and mechanical strength, lowest risk of allergic effects or cytotoxicity of metal ions (especially
in the case of implants containing vanadium and niobium, each interference or damage of the
structure during implantation may result in rare metal ions secretion). Standardmanufactured
implants contain primary holes which enable stabilization with a patient’s bone by means of
screws (Bobyn et al., 1999; Dorman et al., 2011; Hacking et al., 2000). The elements are in-
terconnected using polymethylmethacrylate (PMMA) (Bobyn et al., 1999; Hacking et al., 2000;
Meneghini et al., 2010). Each implant is characterized by proper elasticity, resulting from the
appliedmetal i.e. Young’s elasticity modulusE, determining linear strength. It has to be borne
in mind, however, that when mechanically interfering with an implant (related to drilling ad-
ditional fixing holes) during non-standard stabilization, the fatigue strength of an implant Rz
may decrease as well as further damages may occur. It results from the change in strain and
may require remodeling of stiffness and strength. Performed preliminary studies are supposed
to evaluate the strength of tantalum “trabecular metal” type of implants and titanium mixed
with niobium (Ti-6Al-7Nb) implants, which possess standard holed enabling stabilization with
a patient’s bone using screws. The research material presented in the article constitutes a star-
ting point for research of strength evaluation of implants weakened by the holes drilled for the
needs of potential additional stabilization and, at the same time, draws attention to the risk of
mechanical consequences of excessive weakening of an implant and secondary biological risk of
leaving drilling products behinds, especially those of rare metals.

2. State of hip joint load

In order to evaluate the risk of mechanical consequences of excessive weakening of an implant,
it is decided appropriate to define the state of load bymeans of Finite ElementMethod (FEM).
Themain problem is to define the implant load model which must be assumed for the purpose
of such an analysis. From the point of view of mechanics, precisely theory of machines and
mechanisms, a hip joint is a III-class kinematic pair – spherical, enabling reciprocal spherical
movement. In the humanmovement system, the hip joint is one of the biggest kinematic nodes,
possessing three degrees of freedom (s = 3). The occurrence of additional degrees of freedom,
connected with an incomplete close of the node is defined as hip joint instability (Harris, 1992).
Transferring loads of the spine to lower extremities by means of pelvis, involving the hip joint
occurs in conditions of a very complex movement (Fig. 1). It has to be borne inmind, that the
hip joint together with skeletal system of the pelvic rim, connects the upper part of the human
body with lower extremities by means of a complex system of muscles, tendons and ligaments.
Interactions between the femur head and acetabulum as well as stresses of the muscle system



Strenghth analysis of hip joint replacement revision implant 237

taking part in movement, determines the state of load of the entire skeletal system of the hip
joint. The load of the hip joint is directly dependent on body weight and activities performed
by a human duringwalking – it constitutes a complex system of forces andmoments. In the hip
joint,movementmay occur around threemain axes. Usually, a particularmovement caused by a
contraction of theappropriatemuscle is prevalent anddetermines the essential functionof thehip
joint towhich a system of external and internal forces is applied. The external forces are: weight
related to body mass, support actions, and forces resulting from interactions of other objects
with the human body. The internal forces are mainly forces resulting from muscle interactions.
Evaluation of directions and values of these forces is very difficult due to a large number of
muscles and place of their application (muscle attachments) (Madej, 2008). Furthermore, values
and directions of loads occurring in the hip joint vary in different phases of gait (Bergman et
al., 1993, Bergman et al., 2001; Będziński and Ścigała, 2004; Dąbrowska-Tkaczyk, 1999; Dragan,
1992; Madej and Ryniewicz, 2007; Popovic et al., 2004, Włodarski, 2005).

Fig. 1. Transfer of loads from the spine to lower extremities (Będziński, 1997)

During gait, the center of gravity of the body S also changes, and moves in the direction
opposite to the loaded extremity (Fig. 2). Additionally, the loads in the hip joint depend on
phases of foot contact with the ground.Movements in other planes occur: bow-hyperextension,
ante-version and retroversion, as well as rotational movements.

The rule is to simulate static conditions in the load phase of one extremity, standing on
both feet and in the phase of heel contact with the ground. Additionally, in vivo research is
performed on the values of forces occurring in the hip joint in different phases of gait, especially
in the phases, in which the highest load occurs: while standing on one foot, going up the stairs,
getting up a chair. The values of forces occurring in the hip joint in patients with implanted a
telemetricMoore-type implant were studied byRydell. The researchwas continued byBergman
and Rohlmann, who defined vectors of forces influencing endoprosthesis head in a patient with
full hip alloplasty (Dragan, 2004).

In experiments on biomechanics of hip joint, mechanical properties, especially stiffness and
strength against impact stresses of constructed implants, are studied and physiological models
of force and load distribution in the hip joint before and after endoprosthesis implantation are
devised. Thus, the most often conducted research applies computer techniques using numerical
simulationbasedonphysicalmodels,withholographic interferometrymethodorwithapplication
of resistance strain gauges (Dragan, 2004; Madej, 2008).



238 P. Skowronek et al.

Fig. 2. The course of forces expressed as percentage of the body weight in the hip joint load in the gait
cycle (according to Bergman) (Będziński, 1997)

3. Identification of the hip joint load model

The research on hip joint mechanics in numerous research centers has lod to creation of multi-
ple models of the hip joint load, e.g. Pauwels’, Maquet’s, Bombeli’s, Huiskes’, Bergman’s and
Będziński’s models (Bergman et al., 1993, 1995; Bernakiewicz and Będziński, 1999; Będziński,
1997; Bombeli, 1983; Maquet, 1985; Pauwels, 1976). Researchers, in their majority, agree that
whilemodelling the hip joint load, the following have to be taken into consideration (Będziński,
1997):

• gluteus muscles, for lateral-medial loads,
• biceps femoris muscle, significant in front-to-back interactions,
• iliotibial band of abductors (tractusiliotibialis),
• band of abductors, more significant in femur load than band of adductors,
• a group of rotator muscles, during simulation of the extremity movement in the sagittal
plane, which causes – due to their function and location – turningmoment of femur.

In the light of all the above, the identification of hip joint load model is an exceptionally
difficult and crucial task, considering theoretical studies aimed at strength evaluation from the
perspective of e.g. deformation or risk of implant damage.
One of themost common hip joint loadmodels is Pauwels’ model, which presents two cases

of the hip joint load: two-feet load and standing on one lower extremity (Fig. 3a). The resultant
vector of the force R is directed at the rotation point, which is the anatomical center of the
femur head. In Pauwels’ model, it is assumed that during unilateral extremity load, the total
value of the force loading hip joint results from the interaction between the body weight and
forces of periarticular muscles (Madej, 2008).



Strenghth analysis of hip joint replacement revision implant 239

Fig. 3. (a) Hip joint loadmodel (according to Pauwels) during movement, the phase of one leg load:
S5 – body center of gravity, impact of torso, hand-arms, head, without the other lower extremity,
K – resultant force of body weight impact,M – abductor muscle impact,R – resultant reaction of
impact on the femur head (Bernakiewicz, 1994). (b)Model of two-armed lever modelling loads of the

femur head while standing on one leg (Będziński, 1997)

Relations of loads in the hip joint are brought to a two-armed lever, in which the point of
support is in themiddleof thehip joint (Fig. 3b). Suchanattitude towards the issue constitutes a
significant simplification of a complex state of load in the hip joint, dependent on various factors
(Będziński, 1997; Pauwels, 1976). Analysis of loads based on a two-armed lever is approximately
valid only in the case of the state of balance, when the body center of gravity is in the coronal
plane. Performing any kind of movement will cause a change in the location of the body center
of gravity, which results in the change in the state of load – directions and values of forces
coming from groups of muscles which become activated in order to maintain balance of the
body (Będziński, 1997).

The role of iliotibial band is presented differently by Maquet’s model (Fig. 4a), which is a
modification of Pauwels’ model. InMaquet’s model, tension of the external band of thigh fascia
lata is caused by the abductormuscle. The band is simulated as a tie running along the femoral
shaft from the knee joint to pelvic bone. The tie is based on the great trochanter of the femur
and can slide on it. The impact of the iliotibial band modeled in this way gives an additional
horizontal force, which stabilizes the hip joint. Due to a different, in comparison with other
models, consideration of the impact of muscles, Maquet’s model is more accurate in terms of
the upper anatomy of the lower extremity (Będziński, 1997; Madej, 2008).

Both hip joint load models (Maquet’s and Pauwels’) present a system of forces impacting
the pelvis (together with the upper part of the lower extremity) only in the coronal plane.

Themodel of the hip joint load, additionally considering the role of rotatormusclesRu which
cause turning of the femur in relation to the pelvis (Fig. 4b), based onMaquet’smodel, is shown
by Będziński (Będziński and Ścigała, 2004; Będziński, 1997). In this model, the iliotibial band
can alsomove along the external surface of the great trochanter of femur. The loading system is
constituted by the resultant forces of the hip joint: impact of the weight of torso on the femur
head R, abductors Ma and the iliotibial band M, T (sliding on the great trochanter of femur)
and rotational forcesRu. Theauthor states (Będziński andŚcigała, 2004;Będziński, 1997;Madej
and Ryniewicz, 2007; Madej, 2008; Ryniewicz and Madej, 2001, 2002) that the devised model



240 P. Skowronek et al.

Fig. 4. (a)Maquet’s hip joint loadmodel (Będziński, 1997). (b) Będziński’s model (devised at Zakład
Doświadczalnej Analizy Konstrukcji Inżynierskich i Biomechanicznych) (Będziński and Ścigała, 2004;

Będziński, 1997)

results from experimental studies conducted on physical models. The model groups the basic
forces acting within functioning of the hip joint.
The aim of the analysis of the state of strain and deformation in an endoprosthesis of the

hip joint, having an analytically revisedmodel of the loads of this joint, is to assume the spatial
hip joint load model according to Będziński.

4. Hip joint load

While defining loads for the needs of the studies, the model devised at Division of Experi-
mental Analysis of Engineering and Biomechanical Structures ofWrocławUniversity of Science
and Technology by prof. R. Będziński has been assumed, as well as literature data taken from
M. Bernakiewicz’s PhDDissertation (Bernakiewicz, 1999), and a unique software for analyzing
gait HIP98, which enables to define values of forces and moments for each case of movement.
The value of load for the studies is assumed based on Table 1 (Madej, 2008), in which values
of the resultant force F acting upon the femur head in the case of performing movement are
compiled. The values obtained from HIP98 software for different velocities of gait of particular
patients and various phases – have been assumed after (Madej, 2008), based on literature (Berg-
man etal, 2001; Bernakiewicz, 1999; Bernakiewicz andBędziński, 1999). The aim of obtaining a
comparative reference in terms of reliability of literature data, own studies have been performed
atClinic ofOrthopedics andRehabilitation of the 2ndFaculty ofMedicine ofMedicalUniversity
of Warsaw, which include cases of patients (taking into account sex) occurring most often sta-
tistically, considering weight and load. The studies were performed for the following conditions:
an 80cm step forward without weight transfer and with total temporary transfer of weight to
one foot and leap (maximum temporal result) of 100cm from the platform for different weights
(Table 2).
While performing a comparative analysis, it was concluded that in none of the cases the

value of 1000N of patient’s body weight was exceeded. Arbitrarily, in strength analysis, it was
decided to assume a certain surplus of load impacting the hip implant, the value of the vector of
the resultant force F =300N. The load was assumed with a slight reserve of value in the light



Strenghth analysis of hip joint replacement revision implant 241

Table 1.Values of reaction forces on the femur head for particular patients (Madej, 2008)
❤
❤
❤
❤
❤
❤
❤
❤
❤
❤
❤
❤
❤
❤
❤
❤❤

Phase of gait
Patient Phase of heel contact Phase of standing

with the ground on one foot
Resultant force % 100 BW Fx Fy Fz F Fx Fy Fz F

H.S.
body weight
860N

Slow gait
49 17 216 222 47 19 188 195

3.81km/h
Normal gait

49 22 231 237 42 16 175 181
4.41km/h
Fast gait

55 23 268 274 46 12 181 187
5.11km/h

P.F.
body weight
980N

Slow gait
29 43 215 221 35 34 234 239

3.08km/h
Normal gait

29 35 197 202 30 23 206 209
3.71km/h
Fast gait

29 30 187 192 33 26 207 211
4.46km/h

K.W.
body weight
980N

Slow gait
61 17 202 212 68 3 205 216

3.81km/h
Normal gait

67 20 230 240 59 −1 179 189
4.05km/h
Fast gait

73 19 251 262 58 4 167 177
4.64km/h

Average
for all
patients

Slow gait
47 27 214 221 51 25 217 224

3.60km/h
Normal gait

47 23 210 216 54 8 200 207
4.09km/h
Fast gait

52 26 237 244 47 1 180 186
4.74km/h

of not sufficient knowledge of the actual state of the hip joint load, according to the authors,
with regard to not yet fully identified parameters of this load.

5. Geometry and conditions of the hip joint load

Theassumedgeometry of the cup implant systemsubject to strengthanalysis in conditions of the
static load is shown in Fig. 5. The analyzed implants are a standard version, having preliminary
holeswhich enable stabilizationwith a patient’s boneusing screws. For the assumedgeometry of
themodel, tetra-meshing is applied, i.e. uneven division of the solidmodel continuum into finite
elements of Tet1o type (quadratictetrahedron) is applied. Three identical cylindrical elements
symbolize screws, which are screwed during a surgical procedure.
Strength analysis has been performed for the “trabecular metal” type of implants and tita-

nium implantswith the addition of niobium (Ti-6Al-7Nb), which possess primary holes enabling
stabilization with a patient’s bones using screws.
Mechanical properties for materials:

• “trabecular metal” – are assumed based on the article (Medlin et al., 2004)

Young’s modulus Poisson’s Yield strength Tangent modulus
[MPa] ratio [MPa] [MPa]

3100 0.35 48.2 (±5.9) 310



242 P. Skowronek et al.

Table 2.Values of forces without and with transfer of weight on one foot and during leap

Sex
Weight Step forward Step forward Leap
[N] without [N] with [n] [N]

M 780 220 760 790
M 870 270 880 910
K 560 190 550 570
K 630 200 620 640
K 720 220 720 730
M 880 240 880 890
M 670 220 680 700
K 770 210 770 770
M 710 220 720 740
M 680 210 690 690
K 720 210 710 710
M 740 220 740 750
K 810 210 810 780
K 510 180 500 520
K 550 190 550 550
M 760 220 750 760
K 780 200 780 780
K 810 200 800 810
M 800 220 800 820
K 620 200 620 620
M 640 220 640 650
M 680 220 680 680
M 590 210 590 600
K 670 210 660 670
M 750 220 750 760
M 910 250 900 930
M 870 230 830 840
K 710 220 700 720
K 770 210 760 770
K – female, M –male

• titanium alloy with addition of niobium (Ti-6Al-7Nb) – assumed based on article (Li et
al., 2014)

Young’s modulus Poisson’s Yield strength Tangent modulus
[MPa] ratio [MPa] [MPa]

110000 0.36 min 800 (880-950) 5000

The analyzed case is the one of the implant load being in contact with the pelvic bone, as
shown in Fig. 6. The pelvic bone is modeled conventionally, as a slice of a spherical cylinder, to
which an augment cup implant is attached bymeans of 500N tension screws (Fig. 6a), the pelvic
bone is fixed (Fixed Support), as illustrated in Fig. 6b (blue spherical surface). The direction
of impact of the acetabulum force F on the augment is illustrated by Fig. 7a. The load system
of the implant by vectors of screw tension forces F = 500N (axial forces resulting from fixing
the cup augment to the pelvis) and the vector of the resultant force F =300N is illustrated by
Fig. 7b.



Strenghth analysis of hip joint replacement revision implant 243

Fig. 5. Meshing process continuum of the cup implant model

Fig. 6. Fixing the implant (cup augment) to the pelvic bone: (a) tension of screws (500N), (b) fixed
support of the pelvic bone (blue spherical surface)

Fig. 7. System of implant (cup augment) load: (a) vector of the resultant forceF =300N impacting the
augment, (b) vectors of screw tension forces F =500N (axial forces resulting from fixing the augment

to the pelvis) and the vector of the resultant force

Distribution (maps) of strain reduced according to HMH Hypothesis (Huber-Mises-Hencky
hypothesis of specific energy of shear modulus) obtained by means of FEM analysis for the
case of the “trabecularmetal” type of implants and titanium implants with addition of niobium
(Ti-6Al-7Nb) are shown in Figs. 8 and 9. Distributions (maps) of total deformations of the cup
augment for these two cases of implant materials are shown in Figs. 10 and 11, respectively.



244 P. Skowronek et al.

Fig. 8. Map of reduced strain according to HMH – “trabecular metal” tantalum implant loaded with a
300N force

Fig. 9. Map of reduced strain according to HMH – titanium Ti-6Al-7Nb implant loaded with a 300N
force



Strenghth analysis of hip joint replacement revision implant 245

Fig. 10.Map of total deformations – “trabecular metal” tantalum implant loaded with a 300N force

Fig. 11. Map of total deformations – titaniumTi-6Al-7Nb implant loaded with a 300N force

In neither of the analyzed cases the values of reduced strains HMH reach the assumed
ductility borderReTantalum =48.2MPa andReTitanium =800MPa. For the assumedmaximum
forceF =300N loading of implants, the highest values of reduced strainHMH reach about 46%
Retm = 22.3MPa for the “trabecular metal” tantalum implant and 6.5% ReTi = 52MPa for
titaniumTi-6Al-7Nb implant, respectively. Themaximumvalues of the reduced strain according
toHMHoccuraround thefixingholes andare connectedwith the concentration of strains around
them.

Local concentrations of strains aroundholes result fromscrew tension forces, and are connec-
ted with the assumed boundary conditions. In the actual system, where the analyzed implant
will cooperate fixed to the pelvic bone (especially after it bonds with the bone), the risk of
implant damage as a result of strain concentration will not occur. It has to be stressed, ho-
wever, that the maximum total deformations occur in the lower rim of the cup implant and
may result from the pressure of the augment on the pelvic bone due to uneven pressure during
acetabulum impact. The values of maximum deformations amount to about 0.607mm for the
“trabecular metal” tantalum implant, and to 0.383mm for the titanium implant respectively.
It can be noticed, however, that the total deformations around the holes for the implant made
of the “trabecular metal” material are about 50% smaller, and do not exceed approximately
0.3mm. For the implantmade of Ti-6Al-7Nb, a slight displacement of the simulated pressure of
the augment to the pelvic bone occurred (along the lower rim of the cup implant towards the
sharp edge), thus relatively higher values of total deformations around thehole occur, amounting
to approximately 80% of the maximum, but do not exceed 0.3mm.

Theanalyzed issue is considered as a static analysis.Apart fromthevalue of the load forceF,
a fatigue character of the operation of the analyzed system, subject to permanent movement
load, ought to be noticed.



246 P. Skowronek et al.

6. Conclusions

The conducted preliminary simulation studies enable strength evaluation of “trabecular metal”
tantalum implants and titanium implants with addition of niobium (Ti-6Al-7Nb). The results
of performed numerical analyses indicate that implants with standard holes (i.e. without me-
chanical interference connected with non-standard stabilization with a patient’s bone) fulfill the
strength requirements in conditions of themaximum strain in the assumed implant load system.
It has to be kept in mind, however, that during non-standard stabilization connected with

drilling additional fixing holes, the implant fatigue strength Rz may decrease, which may lead
to further damage. So far, it has not been studied howmechanical interference with the implant
structure and their modification by drilling more holes influences the mechanical properties
of such a system, i.e. change in implant ductility in terms of implant strength after drilling
additional holes. The reports on the strength of the structure after drilling the holes, as well
as after prolonged functioning of such implants, are scarce (Bobyn et al., 1999; Levine et al.,
2006; Meneghini et al., 2010; Meneghini et al., 2010). Attention needs to be drawn to a series of
significant issues connected with the risk of:

• decreasing strength and elasticity of an implant modified with holes,
• damage to prosthesis articulation caused by pieces of metal which remain after drilling
and/or prior loosening of the implant,
• migration of particles in the circulatory system, nephrotoxicity while using alloys with ad-
dition of Al, Ni andV, influence ofmetal ions and implant corrosion around the prosthesis
and weakening of implant osseointegration.

Further studies ought to identify:

• The influence of additional holes inmedical implantsmade of Ti andTa alloys on strength
properties of such implants.Duringbone reconstruction of the hip joint, it is often required
to perform additional holes for the needs of stabilization techniques connected with a
significant bone loss.
• The influence of dependence of the remaining in the surgical field mass of metal ions on
prosthesis tribology.
• The influence of themass of tantalum and titanium particles and raremetal ions (such as
Ni and V) on body toxicity.
• The risk of influence of metal ions and implant corrosion on periarticular tissues, together
with the increase in themass of tantalumand titanium, aluminum, niobiumandvanadium
particles.

Furthermore, studies should to be aimed at:

• Development of implant material with high mechanical properties, least possibly suscep-
tible to weakening due to interference with the implant structure.
• Development of a technique ofmaximum removal ofmetal particles from the surgical field.

The above-mentioned issues define the authors’ goals in terms of further numerical studies
of implants made of the “trabecular metal” and Ti-6Al-7Nb material.

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Manuscript received June 15, 2018; accepted for print September 24, 2018