Submitted Successfully!
To reward your contribution, here is a gift for you: A free trial for our video production service.
Thank you for your contribution! You can also upload a video entry or images related to this topic.
Version Summary Created by Modification Content Size Created at Operation
1 -- 1234 2023-08-02 14:12:20 |
2 format correct Meta information modification 1234 2023-08-04 02:46:38 |

Video Upload Options

Do you have a full video?

Confirm

Are you sure to Delete?
Cite
If you have any further questions, please contact Encyclopedia Editorial Office.
Ortona, E.; Pagano, M.T.; Capossela, L.; Malorni, W. Sex Differences in Bone Health and Healing. Encyclopedia. Available online: https://encyclopedia.pub/entry/47562 (accessed on 04 November 2024).
Ortona E, Pagano MT, Capossela L, Malorni W. Sex Differences in Bone Health and Healing. Encyclopedia. Available at: https://encyclopedia.pub/entry/47562. Accessed November 04, 2024.
Ortona, Elena, Maria Teresa Pagano, Lavinia Capossela, Walter Malorni. "Sex Differences in Bone Health and Healing" Encyclopedia, https://encyclopedia.pub/entry/47562 (accessed November 04, 2024).
Ortona, E., Pagano, M.T., Capossela, L., & Malorni, W. (2023, August 02). Sex Differences in Bone Health and Healing. In Encyclopedia. https://encyclopedia.pub/entry/47562
Ortona, Elena, et al. "Sex Differences in Bone Health and Healing." Encyclopedia. Web. 02 August, 2023.
Sex Differences in Bone Health and Healing
Edit

Skeletal tissue displays sex differences in morphology and physiological function, which can have an impact on bone healing [25]. For example, men tend to have stronger and larger bones compared to women, which can make them more resilient to injury and less prone to fractures. Moreover, in females, the risk of developing osteoporosis sharply increases after menopause, while the occurrence of osteoporosis in men progressively rises with age, and this represents a fundamental issue.

bone health sex differences gender differences

1. Introduction

Sex- and gender-specific medicine deals with the detection and study of the disparity between males and females or men and women in biology and medicine. For years this issue was completely neglected by investigators, but, in the last years, epidemiological evidence first and clinical data later clearly demonstrated that the incidence, the prevalence, the course and sometimes the symptoms themselves of many diseases clearly displayed that sex (biological) or gender (sociocultural such as lifestyles including nutritional habits) should be considered in all aspects of diseases (Table 1). Cardiovascular diseases, immune and autoimmune diseases, and oncological or infectious diseases showed impressive sex/gender disparity if the dataset was analyzed after stratification of the results considering this issue. Hence, recent studies demonstrated that from diagnosis to therapeutic intervention, the relevance of gender-specific medicine could provide useful insights into the development of tailored prevention strategies and the appropriateness of the cures. On the basis of these works and the recommendations to pay more attention to sex and gender issues from institutional agencies (the US National Institutes of Health proposed considering sex as a biological variable in 2016), medical specialties other than those reported above began to investigate if gender medicine could be of interest. Among these also, orthopedics has recently been involved in this matter with the aim of clarifying if bone fracture and healing could be a further field of investigation [1][2][3][4][5][6].
Table 1. Some examples of human pathologic conditions showing sex/gender differences in terms of incidence, course and clinical manifestations. A paradigmatic example for each pathology is reported.
In fact, orthopedics and bone research and clinics have provided some interesting clues in recognizing the determinants of sex disparity in various diseases. For example, it has been observed that sex and gender-related differences may influence the outcome of patients undergoing total hip arthroplasty. Female patients seem to require specific care rules either in the preoperative or intraoperative and postoperative phases [7]. Proximal humerus fractures are more common in the elderly female population, together with other fragility fractures such as proximal femur and hip fractures. However, there is evidence that the mortality rate in patients with proximal humerus fractures is higher in the male population [8][9][10].
A further relevant issue came from the studies on cartilage repair. It was observed that males and females differ in cartilage degeneration and repair. Stem cell therapy could contribute to these differences. In particular, the sex of the stem cell donor as well as that of the recipient, seems to play a role [11]. However, the fields of interest appear to be extremely diverse. For instance, the outcomes following anterior cruciate ligament reconstruction clearly display significant sex disparity [12] and, even in pediatric age, differences between females and males in anatomy, hormone and neuromuscular patterns lead to a higher vulnerability of females to knee injury; in particular, for patellofemoral pain syndrome and anterior cruciate ligament rupture [13]. These are just a few examples of completely different applications of gender medicine in clinical practice that underscore how the complex interplay among biological, physiologic, and social issues should be more deeply investigated in the different fields of orthopedics.
Notwithstanding, the ideal management for complex bone fractures also represents a significant unresolved matter in orthopedics and related specialties from a mechanistic point of view. Fracture healing is a multistage process that includes several complex steps starting after tissue injury. In particular, bone healing can be characterized by three partially overlapping phases: the inflammatory phase, the repair phase, and the remodeling phase. Even though understanding of the biological processes and molecular signals that coordinate fracture repair has advanced, the causes of variability observed in fracture repair are poorly understood. From a general point of view, body weight might play a crucial role in bone regeneration processes, influencing the healing process since local tissue tensions are important for callus tissue development. Elevated strains at the fracture area induce mesenchymal cells to form fibrous tissue, whereas low-stress conditions lead to the generation of osseous tissue. At intermediate stresses, mesenchymal cells differentiate into chondrocytes and induce the development of cartilaginous callus [14][15][16].
Epidemiological studies report a very high number of patients with hip fractures worldwide (more than 1.6 million) with significant differences between men and women, e.g., concerning spinal fractures (29.3/1000 for women and 13.6/1000 for men) [17][18]. In fact, the main sites of fracture are the hip and the spine, with the former being very common due to fragility that can be present in elderly people with osteoporosis, which can be one of the main causes of disability. In particular, it was noted that 22% of women and 33% of men die in the first year after hip fracture [19], so this represents a critical issue either for patients or, in view of hospitalization needs, also for the public health services. Furthermore, the quality of life of these patients can be strongly impaired since they could suffer from spinal deformities [20], reduction of pulmonary function [21] changes and impairment of their daily activity, and, more generally, pain [22][23]. Fracture healing is a complex and long-term process, and osteogenesis and healing time can be influenced by several different factors (such as blood supply and/or inflammatory state). Failures in fracture healing are also detected in 5–10% of patients [22][24].

2. Sex Differences in Bone Health and Healing

Skeletal tissue displays sex differences in morphology and physiological function, which can have an impact on bone healing [25]. For example, men tend to have stronger and larger bones compared to women, which can make them more resilient to injury and less prone to fractures. Moreover, in females, the risk of developing osteoporosis sharply increases after menopause, while the occurrence of osteoporosis in men progressively rises with age [26], and this represents a fundamental issue. Hence, from a clinical point of view, these sex differences lead to an epidemiological gap not only in the occurrence and fracture risk but also in the patient management and clinical outcome [27].
Regarding bone fracture healing, some clinical studies reported that males show more rapid fracture healing. In contrast, women may have an increased risk for atrophic non-unions rather than hypertrophic non-unions, as observed in males [28][29]. By contrast, in other clinical studies, no influence of sex on fracture healing in specific fracture types has been observed [14][30][31].
In the elderly, men show higher post-operative complications and mortality after hip fractures, whereas women have a higher risk for developing non-unions after femoral neck fractures. To note, up to a third of patients with hip fractures can be totally disabled because of non-union [32]. In a prospective study of more than one thousand patients with intracapsular fractures of the femoral neck, a significantly higher incidence of non-union has been found in females in comparison to males [33].

References

  1. Mehta, L.S.; Beckie, T.M.; DeVon, H.A.; Grines, C.L.; Krumholz, H.M.; Johnson, M.N.; Lindley, K.J.; Vaccarino, V.; Wang, T.Y.; Watson, K.E.; et al. Acute Myocardial Infarction in Women: A Scientific Statement from the American Heart Association. Circulation 2016, 133, 916–947.
  2. Aggarwal, N.T.; Mielke, M.M. Sex Differences in Alzheimer’s Disease. Neurol. Clin. 2023, 41, 343–358.
  3. Murphy, G.; Isenberg, D. Effect of gender on clinical presentation in systemic lupus erythematosus. Rheumatology 2013, 52, 2108–2115.
  4. Jacobsen, H.; Klein, S.L. Sex Differences in Immunity to Viral Infections. Front. Immunol. 2021, 12, 720952.
  5. Bellenghi, M.; Puglisi, R.; Pontecorvi, G.; De Feo, A.; Carè, A.; Mattia, G. Sex and Gender Disparities in Melanoma. Cancers 2020, 12, 1819.
  6. Jenkins, C. Differences Between Men and Women with Chronic Obstructive Pulmonary Disease. Clin. Chest Med. 2021, 42, 443–456.
  7. Solarino, G.; Bizzoca, D.; Moretti, A.M.; D’Apolito, R.; Moretti, B.; Zagra, L. Sex and Gender-Related Differences in the Outcome of Total Hip Arthroplasty: A Current Concepts Review. Medicina 2022, 58, 1702.
  8. Pesce, V.; Vicenti, G.; Picca, G.; Rifino, F.; Carrozzo, M.; Moretti, B. A review of gender differences in proximal humerus fractures. J. Sex Gend. Specif. Med. 2016, 2, 141–145.
  9. Fluck, D.; Lisk, R.; Yeong, K.; Mahmood, R.; Robin, J.; Fry, C.H.; Han, T.S. Sex differences in clinical outcomes amongst 1105 patients admitted with hip fractures. Intern. Emerg. Med. 2023.
  10. Osipov, B.; Paralkar, M.P.; Emami, A.J.; Cunningham, H.C.; Tjandra, P.M.; Pathak, S.; Langer, H.T.; Baar, K.; Christiansen, B.A. Sex differences in systemic bone and muscle loss following femur fracture in mice. J. Orthop. Res. 2022, 40, 878–890.
  11. Patel, J.; Chen, S.; Katzmeyer, T.; Pei, Y.A.; Pei, M. Sex-dependent variation in cartilage adaptation: From degeneration to regeneration. Biol. Sex Differ. 2023, 14, 17.
  12. Branche, K.; Bradsell, H.L.; Lencioni, A.; Frank, R.M. Sex-Based Differences in Adult ACL Reconstruction Outcomes. Curr. Rev. Musculoskelet. Med. 2022, 15, 645–650.
  13. Edison, B.R.; Pandya, N.; Patel, N.M.; Carter, C.W. Sex and Gender Differences in Pediatric Knee Injuries. Clin. Sports Med. 2022, 41, 769–787.
  14. Morochovič, R.; Takáčová, K.; Tomčovčík, Ľ.; Cibur, P.; Burda, R. Factors influencing femoral neck fracture healing after internal fixation with dynamic locking plate. Arch. Orthop. Trauma Surg. 2019, 139, 629–638.
  15. Claes, L.E.; Heigele, C.A. Magnitudes of local stress and strain along bony surfaces predict the course and type of fracture healing. J. Biomech. 1999, 32, 255–266.
  16. Claes, L.; Wolf, S.; Augat, P. Mechanical modification of callus healing. Chirurg 2000, 71, 989–994.
  17. Tewari, P.; Sweeney, B.F.; Lemos, J.L.; Shapiro, L.; Gardner, M.J.; Morris, A.M.; Baker, L.C.; Harris, A.S.; Kamal, R.N. Evaluation of Systemwide Improvement Programs to Optimize Time to Surgery for Patients With Hip Fractures: A Systematic Review. JAMA Netw. Open. 2022, 5, e2231911.
  18. Robinson, Y.; Heyde, C.E.; Försth, P.; Olerud, C. Kyphoplasty in osteoporotic vertebral compression fractures--guidelines and technical considerations. J. Orthop. Surg. Res. 2011, 6, 43.
  19. Nikitovic, M.; Wodchis, W.P.; Krahn, M.D.; Cadarette, S.M. Direct health-care costs attributed to hip fractures among seniors: A matched cohort study. Osteoporos. Int. 2013, 24, 659–669.
  20. Alpantaki, K.; Dohm, M.; Korovessis, P.; Hadjipavlou, A.G. Surgical options for osteoporotic vertebral compression fractures complicated with spinal deformity and neurologic deficit. Injury 2018, 49, 261–271.
  21. Hoyt, D.; Urits, I.; Orhurhu, V.; Orhurhu, M.S.; Callan, J.; Powell, J.; Manchikanti, L.; Kaye, A.D.; Kaye, R.J.; Viswanath, O. Current Concepts in the Management of Vertebral Compression Fractures. Curr. Pain Headache Rep. 2020, 24, 16.
  22. Einhorn, T.A.; Gerstenfeld, L.C. Fracture healing: Mechanisms and interventions. Nat. Rev. Rheumatol. 2015, 11, 45–54.
  23. Ameis, A.; Randhawa, K.; Yu, H.; Côté, P.; Haldeman, S.; Chou, R.; Hurwitz, E.L.; Nordin, M.; Wong, J.J.; Shearer, H.M.; et al. The Global Spine Care Initiative: A review of reviews and recommendations for the non-invasive management of acute osteoporotic vertebral compression fracture pain in low- and middle-income communities. Eur. Spine J. 2018, 27 (Suppl. S6), 861–869.
  24. Toosi, S.; Behravan, N.; Behravan, J. Nonunion fractures, mesenchymal stem cells and bone tissue engineering. J. Biomed. Mater. Res. A 2018, 106, 2552–2562.
  25. Seeman, E. Clinical review 137: Sexual dimorphism in skeletal size, density, and strength. J. Clin. Endocrinol. Metab. 2001, 86, 4576–4584.
  26. Cummings, S.R.; Black, D.M.; Rubin, S.M. Lifetime risks of hip, Colles’, or vertebral fracture and coronary heart disease among white postmenopausal women. Arch. Intern. Med. 1989, 149, 2445–2448.
  27. Cummings, S.R.; Melton, L.J. Epidemiology and outcomes of osteoporotic fractures. Lancet 2002, 359, 1761–1767.
  28. Rupp, M.; Kern, S.; El Khassawna, T.; Ismat, A.; Malhan, D.; Alt, V.; Heiss, C.; Raschke, M.J. Do Systemic Factors Influence the Fate of Nonunions to Become Atrophic? A Retrospective Analysis of 162 Cases. BioMed Res. Int. 2019, 2019, 6407098.
  29. Li, X.P.; Li, X.Y.; Yang, M.H.; Zhu, S.W.; Wu, X.B.; Zhang, P. Changes of bone turnover markers after elderly hip fracture surgery. J. Bone Miner. Metab. 2021, 39, 237–244.
  30. Johnson, J.P.; Kleiner, J.; Goodman, A.D.; Gil, J.A.; Daniels, A.H.; Hayda, R.A. Treatment of femoral neck fractures in patients 45–64 years of age. Injury 2019, 50, 708–712.
  31. Lofrese, G.; Musio, A.; De Iure, F.; Cultrera, F.; Martucci, A.; Iaccarino, C.; Ibn Essayed, W.; Ghadirpour, R.; Servadei, F.; Cavallo, M.A.; et al. Type II odontoid fracture in elderly patients treated conservatively: Is fracture healing the goal? Eur. Spine J. 2019, 28, 1064–1071.
  32. Poole, K.E.; Compston, J.E. Osteoporosis and its management. BMJ 2006, 333, 1251–1256.
  33. Endo, Y.; Aharonoff, G.B.; Zuckerman, J.D.; Egol, K.A.; Koval, K.J. Gender differences in patients with hip fracture: A greater risk of morbidity and mortality in men. J. Orthop. Trauma 2005, 19, 29–35.
More
Information
Subjects: Orthopedics
Contributors MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register : , , ,
View Times: 511
Revisions: 2 times (View History)
Update Date: 04 Aug 2023
1000/1000
ScholarVision Creations