Contribution of Bone Scintigraphy in the Diagnosis of a Calcaneus Fatigue Fracture in a Case at the Nuclear Medicine Department of Idrissa Pouye General Hospital (HOGIP) in Dakar

Introduction: Fatigue fractures are secondary to excessive, unusual, repeated mechanical stress, occurring on healthy bone. Bone scintigraphy (BS) with 99mTc-HMDP is an excellent means of diagnosis. We report a case of stress fracture of the calcaneus with scintigraphic diagnosis, in a marathon runner. Patient and Methods: He is a 40-year-old athlete in overtraining with right calcaneal pain on running, intense at first, moderate in the middle and then persistent after exercise. The interrogation found no trauma to the right foot and the x-ray of the foot was without abnormality. The so 3 phases were performed following an injection of 564 MBq of 99mTc-HMDP, with a SPECT gamma camera. Results: Bone scintigraphy found in the early phase, hyper-perfusion and hyper-fixation of the right calcaneal region compared to its left counterpart and in the bone phase persistence of focal hyperfixation opposite the right calcaneus. This scintigraphic aspect of the right calcaneus in an overtrained marathon runner, in a painful context and in front of a normal X-ray, made us evoke a fracture of fatigue. A complementary CT scan performed two days after the BS was without abnormality. Conclusion: Fatigue fractures are micro-fractures generally not noticed on radiography and CT. BS due to its high sensitivity is an excellent or the best tool for the early diagnosis of stress fractures. How to cite this paper: Bathily, E.-H.A.L., Ndong, B., Diop, O., Djigo, M.S., Gueye, K., Kokou, A., Thiaw, G., Mbaye, G., Diouf, L.A.D., Soumboundou, M., Djiboune, A.R., Sy, P.M., Ndoye, O., Diarra, M. and Mbodj, M. (2020) Contribution of Bone Scintigraphy in the Diagnosis of a Calcaneus Fatigue Fracture in a Case at the Nuclear Medicine Department of Idrissa Pouye General Hospital (HOGIP) in Dakar. Open Journal of Medical Imaging, 10, 62-71. https://doi.org/10.4236/ojmi.2020.101006 Received: January 8, 2020 Accepted: March 28, 2020 Published: March 31, 2020 Copyright © 2020 by author(s) and Scientific Research Publishing Inc. This work is licensed under the Creative Commons Attribution International License (CC BY 4.0). http://creativecommons.org/licenses/by/4.0/


Introduction
Fatigue fractures or stress fractures are secondary to non-violent, repetitive stresses of moderate amplitude, occurring on previously healthy bone [1]- [7]. They occur in the absence of metabolic disorders and any specific trauma [3] [7] [8] [9].
They were first reported in 1855 by Breithaupt and mainly among military personnel [10]. Devas [11] in 1958 was one of the first authors to study stress fractures in athletes and running is the main cause [10] [12] [13] [14]. The vast majority of fatigue fractures occur at the lower extremities [15] [16] [17]; the calcaneus being the second location after the tibia [3] [4] [18].
These fractures are favored by a period of unusual physical activity, such as overtraining or a change in training [4] [12] [18]. Although radiography is the primary diagnostic modality for detection of skeletal trauma, there are many occasions when radiographs may initially fail to diagnose an injury. Also, there are several types of injuries which are not diagnosable by routine radiographic methods but can be detected easily by nuclear medicine techniques [5] [10] [16] [19]. However, magnetic resonance imaging (MRI) is also likely to provide an early diagnosis of traumatic bone injuries related to sports [5] [7]. There are four primary categories of injury where nuclear medicine techniques may be of use.
These include 1) stress fracture and periosteal injury; 2) covert fractures; 3) joint abnormalities and injuries to connective tissues, especially where they attach to bone; and 4) acute skeletal muscle injury and rhabdomyolysis. One of the most important features of the use of nuclear medicine techniques in the evaluation of sports and traumatic injury is the ability, in most cases, to be able to differentiate among these various categories [5] [20]. Bone scintigraphy (BS) at 99mTc-HMDP, is a good way to highlight the fatigue fracture.
We report a case of stress fracture of the calcaneus for scintigraphic diagnosis, in an athlete.

Patient and Methods
He is a Senegalese, 40-year-old marathon runner, presenting for two months approximately, right calcaneal pain occurring during the race, intense at the beginning, moderate in the middle and then persistent after the effort. This pain got worse a month ago after participating in a marathon. The interrogation found overtraining linked to the preparation of the marathon, and an absence of trauma to the right foot.
The X-ray of the foot carried out twice is without abnormality. He was then referred to the nuclear medicine department of Idrissa Pouye General Hospital

Results
Bone scintigraphy found: -In the early phase (Vascular or phase 1 and tissue or phase 2): hyper-perfusion ( Figure 2) and hyper-fixation ( Figure 1) of the right calcaneal region compared to its left counterpart more visible on the posterior acquisition. Indeed, the comparative study of perfusion curves shows a curve of the right foot always above that of the left foot ( Figure 2). In addition, the right/left or Examinated (E)/Reference (R) perfusion reports find values ranging from 1.30 to 3.01, reflecting the hyper-perfusion on the right ( Figure 3).
-In the late or bone phase (phase 3) we noted on the whole body scintigraphy ( Figure 4) as well as on the static images ( Figure 5), a persistence of focal hyperfixation projecting opposite the right calcaneus. It was visible on the anterior side but more prominently on the posterior side.
-This scintigraphic aspect of the right calcaneus in an overtrained marathon runner, in a painful context and in front of a normal radiography, had made us evoke a fracture of fatigue.
Like the X-ray, the complementary CT scan of the feet performed two days after the BS was normal ( Figure 6).

Discussion
The field and the context of occurrence of the fatigue fracture in our case are widely found in the literature. He is indeed a marathon athlete in overtraining.
Michael T. Reeder et al. [10], Brent W. S. [21] stated that running is the cause in the vast majority of stress fractures. It is the same as Prather et al. [22]. Matin P. [5] reported that these lesions are frequently observed in runners and other athletes whose training regimen produces unusually heavy stresses on bone cells.
Indeed stress fractures occur when the stresses applied to the bone cause changes in the bone greater than the body's ability to neutralize them. The resulting lesion is probably due to much greater bone resorption than bone replacement [5] [21]. Paycha [7] argued that the classic trigger is a recent and ill-suited change in training conditions. They are also commonly found in army recruits and other untrained people who participate in new types of training. In addition, people with biomechanical abnormalities such as walking or running may be prone to this type of injury [5].
The bone structure, although subject to efforts within the limits of its capacities, undergoes elastic deformation and regains its histological configuration at the end of the stress. However, when these stresses exceed its normal resistance, the elastic deformation is replaced by plastic deformation; in other words, there is no return to the previous situation, bone reabsorption thus prevailing if the conditions remain, and microfractures occur. In this stage of the evolution of the stress fracture, physiological alteration occurs without apparent anatomical implication [27]. The pursuit of "sports" requirements, after the initial installation of the microfracture, results in an open fracture, this time associated with anatomical modifications of the bone structure. Thus, we can say that the establishment of the fatigue fracture begins with a physiological modification; when the cause of this alteration remains, the situation ends in an anatomical modification [27]. In fact, following intense, unusual, repeated mechanical stresses, an accentuation of osteoclastic resorption takes place with an increase in bone turnover, which is only followed belatedly by an increase in osteoblastic formation. This temporary embrittlement exposes to fracture decompensation in the event of continued overuse [7] [11] [21] [28].
We know that X-rays are of little use in detecting acute stress fractures; therefore, the diagnosis of these abnormalities has become mainly dependent on nuclear medicine techniques. The clinical picture of our patient is also widely reported in the literature. Paycha [7] and Mouaden A. [9] reported that the reason for the consultation was a sudden onset pain without trauma, typically mechanical, worsening with exertion and calmed by rest. The diagnosis of fatigue fracture is evoked in athletes in the face of progressively disabling mechanical pain, contrasting with the poor physical examination.
The scintigraphic aspect of hyperfixation at the early and late phase of the right calcaneus in a overtrained marathon runner, in a painful context and in front of a normal radiography, made us evoke a fatigue fracture. This scintigraphic aspect is classic and very widely described [3] [29]. In fact, the 4 pillars of the diagnosis are: the history of the athlete, isolated exertion pain, normal radiographs and positive bone scan [7]. The radiographic signs are most often delayed (2 weeks to 3 months), discreet, sometimes even absent (tarsus, metatarsals). The same late nature of the anomalies visible on the computed tomography (CT) should be emphasized [7] [31]. This ideal sensitivity value is only valid for fatigue fractures occurring on healthy non-osteoporotic bone, when a minimum period of 12 hours separates the onset of pain from bone scintigraphy.
The specificity of the dynamic and morphological criteria for the fatigue frac-ture is greater than 80%. Among the bone lesions that may resemble the fatigue fracture, the most frequently encountered are osteonecrosis for the metatarsals and the talus, algodystrophy parcel or osteonecrosis for the tibial plateau, osteoid osteoma for the calcaneus and metatarsals. This list is obviously not exhaustive [7] [31].
To achieve an early diagnosis, bone scintigraphy is widely used in this indication, especially in developed countries. Some sports medicine teams even use scintigraphy as the first intention, radiography downshifting into second position and often in a delayed manner. However, magnetic resonance imaging (MRI) is also likely to provide an early diagnosis of traumatic bone injuries related to sports [32] [33]. The merits of this technique are to identify extra-osseous traumatic injuries and to provide an anatomical image of the lesions. The disadvantages are the limited nature of the exploration, the non-specificity of spinal edema when the fracture line is invisible, a slightly lower sensitivity to scintigraphy when the MRI is not guided by the latter.
The location of fatigue fractures depends on the type of physical activity.  [7]. The treatment consists of rest with reduction of the load when pressing on the foot in question.
Conservative therapy for stress fractures involves the use of ice, non-steroidal anti-inflammatory drugs, and rest of the affected bone for several weeks or until pain-free. Additionally, pre-exercise warm-up and stretching, and a gradual return to the offending exercise intensity are indicated. Substitution of a non-weight-bearing exercise, such as swimming (or upper extremity bicycle for lower extremity fractures), may speed recovery without loss of cardiovascular conditioning. Metatarsal and navicular fractures may require short leg casting for six to eight weeks unless comminuted or displaced. In elite athletes, it is more common to perform intramedullary nailing if a joint is not involved [21].
For the prevention, a gradual increase in the intensity of exercise, not to exceed an increase of 10 percent per week, generally is recommended for prevention of all stress fractures. Adequate stretching with warm-up before exercise is advised. The use of lightweight footwear in good condition and smooth, level running surfaces are specifically recommended to prevent lower extremity stress fractures as well as correcting predisposing biomechanical conditions by using custom orthotics or arch supports. A Cochrane Review involving four trials suggested that the use of shock-absorbing insoles may prevent stress fractures and stress reactions of the lower extremities. Another study found that decreased exercise intensity after an initial intense period may be effective in preventing stress fractures but may not be significant when corrected for cluster randomization [21].

Conclusion
Fatigue fractures are micro-fractures generally not noticed on radiography and CT. So due to its high sensitivity is an excellent tool for the early diagnosis of stress fractures. However, a SPECT scintigraphy coupled with tracking CT is essential to increase the specificity of the examination. Although MRI is currently accepted for evaluation of stress injuries of the bone, some limitations and pitfalls remain. Three-phase bone scintigraphy is the gold standard to provide prompt and sensitive diagnosis of stress fractures. Additional SPECT/CT imaging will enhance the diagnostic accuracy of planar bone scintigraphy.