Total hip arthroplasty (THA) is a very frequent procedure in Traumatology and Orthopedic Surgery Services, and although its effectiveness is very high, it is not without complications such as aseptic loosening, dislocations, infections and periprosthetic fractures.

Despite the advances in prosthetic techniques and models, dislocation is still the second most common complication in total hip arthroplasties, following aseptic loosening. It appears in 0.3–10% of primary hip arthroplasties and in up to 28% of revision arthroplasties.1

There are various classifications of THA dislocation; according to the time: early (<3 months) and belated (>3 months); according to their number: simple or recurrent; according to their direction: anterior (clinical observation of the affected limb in external rotation and extension) and posterior (lower limb in internal rotation and flexion); according to the mechanism of the lesion: traumatic or spontaneous; according to the etiology, following the Dorr classification,2 which is important as knowledge of the cause of dislocation will help to decide the therapeutic attitude (positional: no radiographic alteration of components without soft tissue imbalance [10%]; malposition of components [33%]; imbalance of soft tissues: musculature, major trochanter, offset, [33%]; combination of II and III).

On the other hand, the risk factors considered associated to a greater probability of prosthetic dislocation have been extensively studied; factors relating to the patient such as age, gender, cognitive or neuromuscular alterations, initial diagnosis, prior surgery; factors related to the surgical procedure, such as approach routes, characteristics of the components, pre- and postoperative radiographic measurements. However, there is still significant controversy surrounding many of them.

Considering the high incidence of dislocation in total hip arthroplasties and the lack of consensus in relation to some of the risk factors that favor it, this clinical–computational research work is designed with the following objectives: clinical: to determine the risk factors associated to prosthetic dislocation and categorize them by order of relevance, and computational: to simulate a prosthetic model with different sizes of components and their maximum ranges of movement before the impingement between components and dislocation takes place, in addition to correlating the computational with the clinical findings to determine the safe ranges of movement in each angulation and anteversion of the cup.

The incidence of THA dislocation in our sample was of 2.07%, with 2.62% in the case of cemented arthroplasties and 1.24% in the case of uncemented arthroplasties.

The dislocation was early (<3 months) in the majority of the cases (87%), with just 1 single case of belated dislocation (>5 years) and 5 cases of dislocations in the intermediate period.

Computational study

We observed that when the inclination (α) of the cup was of 25° regardless of the level of anteversion (β) there was an impingement between components before reaching a flexion of 90°, so it was no longer necessary to carry out the rotations. This happened with any anteversion in the heads of 28mm. However, for the head of 32mm it was only observed in anteversion of 0° and 15°, and with the head of 36mm only in anteversion of 0°.

In addition, a progressively greater flexion took place until impingement as the diameter of the femoral head was increased on one side, and anteversion on the other (Fig. 3).

Figure 3.

Relationship between the ROM in flexion and the diameter of the femoral head and anteversion (β).

(0.11MB).

The analysis revealed 2 opposing positions which favored dislocation. On the one hand, the greater the inclination (α) and anteversion (β) the greater the risk of anterior dislocation in extension and external rotation. On the other hand, the lower the inclination (α) and the anteversion (β) the greater the risk of posterior dislocation in flexion and internal rotation (Fig. 4). The 28mm head was the only one that presented an anterior dislocation with the previously described characteristics, in addition to posterior dislocation, which also took place in the 32mm and 36mm heads.

Figure 4.

ROM free of dislocation according to inclination (α) and anteversion (β).

(0.14MB).

The ROM of impingement and dislocation was proportional both to the degree of inclination (α) and anteversion (β) of the cup and to the major diameter of the femoral head, with dislocation being less frequent in the larger heads, i.e. taking place at more extreme degrees of rotation, practically at the limit of the movement capacity of the arthroplasty.

Regarding the ROM, we observed that this increased together with the diameter of the femoral head when considering the same cup position. The same relationship was found between the ROM and anteversion on the one hand and the ROM and inclination on the other. Considering a single size of femoral head and maintaining a constant inclination and anteversion, respectively, the ROM and the anteversion/inclination increased proportionally (Fig. 5).

Figure 5.

(a) Variation of the ROM in relation to anteversion. (b) Variation of the ROM in relation to inclination.

(0.12MB).

The tensions in the surface of the cup in the area of contact of the neck during the impingement and the dislocation were high regardless of the size of the head. However, in the area of dislocation of the femoral head (egress site) they were lower as the diameter of the head increased (Fig. 6).

Figure 6.

Distribution of tensions in the cup at the time of dislocation in a 28mm head (left) and a 36mm (right) head.

(0.45MB).

The incidence of THA dislocation in the sample was of 2.07%, with 2.62% taking place in cemented arthroplasties and 1.24% in uncemented arthroplasties. The data published in this regard range between rates of 0.5% and 9.2%, as mentioned in previous reviews.1 This places our work in a good range within the literature. Regarding the incidence of dislocation according to cemented or uncemented prosthetic models, our results were very similar to those published in our country on low-friction cemented THA with an incidence of 2.97% (2.62%) and uncemented THA with 2.8% (1.24%).7

Our own findings, along with those reported by these publications regarding a lower rate of dislocation among uncemented arthroplasties are in contrast with the results obtained by Conroy et al.,8 who published a higher rate of dislocation in uncemented versus cemented cups with a relative risk of 1.59, especially if the uncemented cup was used with femoral heads with a diameter of less than 28mm. Although without data to support their hypothesis, these authors postulated that the orientation of cemented cups was more precise because the surgical technique allowed them to be better adapted whilst the cement polymerized, whereas uncemented cups sought their own adjustment within the acetabulum, which may not have coincided with the optimal position sought by the surgeon.

Dislocation was early (<3 months) in the majority of cases (87%), with only 1 case of belated dislocation (>5 years), in the group of uncemented arthroplasties, and 5 cases of dislocations in the intermediate period. The data published in the literature indicate that the majority of the dislocations take place within the first 3 months after the surgery, as was the case in our study. Approximately 50–70% of the dislocations took place between the first 5 weeks and 3 months after the intervention and more than three quarters of all the dislocations within the first year. In 26% of the cases, the first episode of dislocation took place 2 years after the operation, with this period extending more than 5 years in 0.8% of the patients.9

Some authors have proposed progressive wear of the polyethylene of the acetabular nucleus as the cause of the “belated” instability,10 but this is probably not the only reason, and we should add others, at least in a coadjutant role, such as a decrease in soft tissue tension and muscle tone and as well as the modifications in posture, coordination and balance experienced by patients with the passage of time, as mentioned by Fernández-Fairen et al.,11 in their review article of the bibliography published in this respect.

In the group of cemented arthroplasties we observed that dislocation was more frequent among males in a statistically significant manner. The scientific literature adds to the controversy on this issue. Studies such as that by Woo and Morrey12 report that the risk of dislocation among females is 2 times higher than among males. The same finding was reported by Kim et al.,13 with a risk of dislocation among females 2.5 times higher than that of males. On the other hand, Masaoka et al.14 found no differences between both genders.

The factors proposed as causative of a higher rate of dislocation among females are less strength and muscle tone, and a greater elasticity of soft tissues.15 This fact could explain the lack of correlation between the risk of prosthetic dislocation in the female gender in the case of revision arthroplasty. In this case, the involvement of muscle function following revision arthroplasty which is also present in the male gender makes the incidence of dislocation equal between the two genders.16

This study found statistically significant differences with higher mean age (71 years) in the group of dislocated patients versus the non-dislocated (64 years). The literature contains publications, such as those by Morrey17 and Masaoka et al.,14 that did not find a relationship between age and prosthetic dislocation. On the other hand, Ekelund et al.18 published that the risk of dislocation was multiplied by 2 in octogenarians. Likewise, Byström et al.19 published a risk of dislocation 4.5 times higher among those aged over 80 years, whilst Berry et al.20 published a relative risk of dislocation 1.3 times higher in patients aged over 70 years. Advanced age entails increased frailty, loss of muscle tone, inability to comply with anti-dislocation advice and an increased incidence of cognitive problems, all of which entail a higher risk of prosthetic dislocation, which leads us to consider whether age is an independent risk factor or a confusion bias.

Dislocation was more common among cases who had suffered fractures than coxarthrosis, in a statistically significant manner. Similar data have been published in the literature, with a rate of dislocation in THA due to fractures of 14% versus 4% in cases due to arthrosis.21 The 2 circumstances that could explain this are capsular hypertrophy observed in patients with coxarthrosis, which could act as stabilizer element for the hip, and the greater range of movement of the arthroplasty in patients with hip fractures compared to those with coxarthrosis.

Although no statistically significant differences were obtained, dislocation was more frequent in the group of patients who had undergone prior surgery in the same hip. There are some publications in this respect that place the rate of dislocation of the hips with previous surgery at double that of those that had not been intervened previously.22 This is probably due to the lassitude, scarring and other soft tissue lesions caused by the previous surgery.

Dislocation was more frequent when there was neurological impairment, with a significant difference, and also all those patients who consumed alcohol suffered prosthetic dislocation. This figure coincides with that observed by Woolson and Rahimtoola,23 who published an incidence of 12.7% dislocations among patients with a history of dementia, confusion and/or alcoholism versus 3% of patients who did not have a prior history of such alterations.

In our series we did not find statistically significant differences in the relationship between dislocation and the inclination angle of the cup. However, we did find them in the case of anteversion, with a lower value (11.54±6.05°) in dislocated cups than in non-dislocated cups (14.19±8.61°). Similar data were published by Nishii et al.,24 who reported that 181 hips without dislocation had an anteversion ≥20°, whilst 9 dislocated hips had an anteversion <20°.

Regarding the 2 opposing positions that were revealed as favoring dislocation, these were very similar to the findings of the clinical part of the study and the literature. As mentioned previously, on the one hand, the greater the inclination and anteversion, the higher the risk of anterior dislocation in extension and external rotation. These same findings were published by Scifert et al.,25 who considered that an increase of anteversion and inclination improved prosthetic stability in terms of posterior dislocation, although they predisposed toward anterior dislocation and wear. A more recent study by Kluess et al.5 made the same observation following a simulation of total hip arthroplasty through finite elements. As shown by our simulation, the cup should be placed at an inclination of between 40° and 60° and an anteversion of between 15° and 25°.

The findings obtained in this study related a higher soft tissue tension with a higher risk of dislocation, which a priori goes against the widely extended concept that patients with a loss of femoral offset have more unstable hips.26 However, Ameneiro et al.27 published that the offset of dislocated patients was slightly higher than that of non-dislocated patients (42.2mm versus 40.7mm) and the same was true about the length of the femoral neck.

It was worth noting that there was a higher percentage of surgeons with less experience in the group of dislocated patients. This factor has been confirmed by a recent systematic review.28

The statistical analysis revealed significant differences, with all the patients with infection being part of the group who suffered prosthetic dislocation. The joint collection could have produced an increase of the hydrostatic pressure that could have distracted the joint, making it more vulnerable to dislocation.

The ROM of “impingement” and dislocation was proportional to a greater diameter of the femoral head, with dislocation being less frequent among larger heads, i.e. taking place in more extreme degrees of rotation. In relation to the diameter of the head, many publications have supported a stability of larger heads.29 In this respect, it is worth noting the work with finite elements by Scifert et al.25 The importance of a greater diameter of the femoral head in terms of prosthetic stability can also be observed when analyzing the resistance momentum, which increased together with the diameter of the femoral head. A high resistance momentum involves greater stability and greater resistance to dislocation. These findings closely match those published by other authors.5,25

Regarding the distribution of tensions in the surface of the cup during impingement and dislocation, we observed that, regardless of the size of the head, all the tensions were high in the area of neck impingement. However, in the area of dislocation of the femoral head (egress site) they were lower as the diameter of the head increased. These findings suggest that larger heads could have less polyethylene wear, a factor that is associated to instability due to the greater penetration of the femoral head into the acetabular component, favoring impingement of the prosthetic neck and due to the formation of granulomas from polyethylene particles that would condition a loosening and even migration of the acetabular component.30

Advanced age, cognitive deterioration and prior fracture are the main factors favoring prosthetic dislocation. Implantation of the cup with an anteversion under 10–15° is most important factor of the surgical technique in determining the onset of prosthetic dislocation. The methodology with finite elements allows us to study the stability of a total hip arthroplasty, being especially useful to evaluate the resistance momentum. The safety area free of dislocation entails a position of the cup with an inclination between 40° and 60° and an anteversion of between 15° and 25°. Restoring soft tissue tension is crucial in obtaining a stable arthroplasty, as both a lack and an excess of tension will predispose toward dislocation. Larger heads were more stable, as long as adequate proportions regarding the size of the neck and cup were maintained. Although no statistically significant differences were obtained, greater surgeon experience represented a progressively smaller risk of prosthetic dislocation.

Level of evidence II.

The authors have no conflict of interests to declare.