References
- Bryant R. Post-traumatic stress disorder vs traumatic brain injury. Dialogues in Clinical Neuroscience 2011;13:251–262
- Chamelian L, Reis M, Feinstein A. Six-month recovery from mild to moderate Traumatic Brain Injury: the role of APOE-epsilon4 allele. Brain 2004;127:2621–2628
- Kane MJ, Angoa-Perez M, Briggs DI, Viano DC, Kreipke CW, Kuhn DM. A mouse model of human repetitive mild traumatic brain injury. Journal of Neuroscience Methods 2011;203:41–49
- Center of Disease Control and Prevention. Injury prevention & control: traumatic brain injury. Available online at: http://www.cdc.gov/TraumaticBrainInjury/index.html, accessed 2012
- Affairs DoV. Understanding traumatic brain injury: definition and background. Available online at: http://www.polytrauma.va.gov/understanding-tbi/definition-and-background.asp, accessed 2011
- Brenner LA. Neuropsychological and neuroimaging findings in traumatic brain injury and post-traumatic stress disorder. Dialogues in Clinical Neuroscience 2011;13:311–323
- Ryan PB, Lee-Wilk T, Kok BC, Wilk JE. Interdisciplinary rehabilitation of mild TBI and PTSD: a case report. Brain Injury 2011;25:1019–1025
- Moon RJ, Sutton T, Wilson PM, Kirkham FJ, Davies JH. Pituitary function at long-term follow-up of childhood traumatic brain injury. Journal of Neurotrauma 2010;27:1827–1835
- Tanriverdi F, De Bellis A, Ulutabanca H, Bizzarro A, Sinisi AA, Bellastella G, Paglionico VA, Mora LD, Selcuklu A, Unluhizarci K, et al. Five years prospective investigation of anterior pituitary function after traumatic brain injury: is hypopituitarism long-term after head trauma associated with autoimmunity? Journal of Neurotrauma 2013;30:1426--1433
- Park KD, Kim DY, Lee JK, Nam HS, Park YG. Anterior pituitary dysfunction in moderate-to-severe chronic traumatic brain injury patients and the influence on functional outcome. Brain Injury 2010;24:1330–1335
- Rose SR, Auble BA. Endocrine changes after pediatric traumatic brain injury. Pituitary 2012;15:267–275
- Zaben M, El Ghoul W, Belli A. Post-traumatic head injury pituitary dysfunction. Disability & Rehabilitation 2013;35:522–525
- Rosario ER, Aqeel R, Brown MA, Sanchez G, Moore C, Patterson D. Hypothalamic-pituitary dysfunction following traumatic brain injury affects functional improvement during acute inpatient rehabilitation. Journal of Head Trauma Rehabilitation 2013;28:390--396
- Acerini CL, Tasker RC. Traumatic brain injury induced hypothalamic-pituitary dysfunction: a paediatric perspective. Pituitary 2007;10:373–380
- Norwood KW, Deboer MD, Gurka MJ, Kuperminc MN, Rogol AD, Blackman JA, Wamstad JB, Buck ML, Patrick PD. Traumatic brain injury in children and adolescents: surveillance for pituitary dysfunction. Clinical Pediatrics (Philadelphia) 2010;49:1044–1049
- Mohan S, Baylink DJ. Impaired skeletal growth in mice with haploin sufficiency of IGF-I: genetic evidence that differences in IGF-I expression could contribute to peak bone mineral density differences. Journal of Endocrinology 2005;185:415–420
- Mohan S, Richman C, Guo R, Amaar Y, Donahue LR, Wergedal J, Baylink DJ. Insulin-like growth factor regulates peak bone mineral density in mice by both growth hormone-dependent and -independent mechanisms. Endocrinology 2003;144:929–936
- Trentz OA, Handschin AE, Bestmann L, Hoerstrup SP, Trentz OL, Platz A. Influence of brain injury on early posttraumatic bone metabolism. Critical Care Medicine 2005;33:399–406
- Sato Y. Abnormal bone and calcium metabolism in patients after stroke. Archives of Physical Medicine & Rehabilitation 2000;81:117–121
- Sato Y, Kuno H, Kaji M, Etoh K, Oizumi K. Influence of immobilization upon calcium metabolism in the week following hemiplegic stroke. Journal of Neurological Sciences 2000;175:135–139
- Lee JI, Kim JH, Kim HW, Choi ES, Lim SH, Ko YJ, Han YM. Changes in bone metabolism in a rat model of traumatic brain injury. Brain Injury 2005;19:1207–1211
- Ajao DO, Pop V, Kamper JE, Adami A, Rudobeck E, Huang L, Vlkolinsky R, Hartman RE, Ashwal S, Obenaus A, et al. Traumatic brain injury in young rats leads to progressive behavioral deficits coincident with altered tissue properties in adulthood. Journal of Neurotrauma 2012;29:2060–2074
- Yu H, Watt H, Kesavan C, Johnson PJ, Wergedal JE, Mohan S. Lasting consequences of traumatic events on behavioral and skeletal parameters in a mouse model for post-traumatic stress disorder (PTSD). PLoS One 2012;7:e42684
- Yu H, Watt H, Kesavan C, Mohan S. The negative impact of single prolonged stress on bone development in mice. Stress 2013;16:564–570
- Cizza G, Ravn P, Chrousos GP, Gold PW. Depression: a major, unrecognized risk factor for osteoporosis? Trends in Endocrinology & Metabolism 2001;12:198–203
- Yirmiya R, Goshen I, Bajayo A, Kreisel T, Feldman S, Tam J, Trembovler V, Csernus V, Shohami E, Bab I. Depression induces bone loss through stimulation of the sympathetic nervous system. Proceedings of the National Academy of Sciences USA 2006;103:16876–16881
- Albert-Weissenberger C, Siren AL. Experimental traumatic brain injury. Experimental & Translational Stroke Medicine 2010;2:16
- Marmarou A, Foda MA, van den Brink W, Campbell J, Kita H, Demetriadou K. A new model of diffuse brain injury in rats. Part I: pathophysiology and biomechanics. Journal of Neurosurgery 1994;80:291–300
- Masinde GL, Li X, Gu W, Wergedal J, Mohan S, Baylink DJ. Quantitative trait loci for bone density in mice: the genes determining total skeletal density and femur density show little overlap in F2 mice. Calcified Tissue International 2002;71:421–428
- Yu H, Wergedal JE, Zhao Y, Mohan S. Targeted disruption of TGFBI in mice reveals its role in regulating bone mass and bone size through periosteal bone formation. Calcified Tissue International 2012;91:81–87
- Kesavan C, Mohan S. Bone mass gained in response to external loading is preserved for several weeks following cessation of loading in 10 week C57BL/6J mice. Journal of Musculoskeletal & Neuronal Interactions 2010;10:274–280
- Wergedal JE, Sheng MH, Ackert-Bicknell CL, Beamer WG, Baylink DJ. Mouse genetic model for bone strength and size phenotypes: NZB/B1NJ and RF/J inbred strains. Bone 2002;31:670–674
- Mohan S, Baylink DJ. Development of a simple valid method for the complete removal of insulin-like growth factor (IGF)-binding proteins from IGFs in human serum and other biological fluids: comparison with acid-ethanol treatment and C18 Sep-Pak separation. Journal of Clinical Endocrinology & Metabolism 1995;80:637–647
- Govoni KE, Linares GR, Chen ST, Pourteymoor S, Mohan S. T-box 3 negatively regulates osteoblast differentiation by inhibiting expression of osterix and runx2. Journal of Cellular Biochemistry 2009;106:482–490
- Linares GR, Xing W, Burghardt H, Baumgartner B, Chen ST, Ricart W, Fernandez-Real JM, Zorzano A, Mohan S. Role of diabetes- and obesity-related protein in the regulation of osteoblast differentiation. American Journal of Physiology – Endocrinology & Metabolism 2011;301:E40–48
- Day TF, Yang Y. Wnt and hedgehog signaling pathways in bone development. Journal of Bone & Joint Surgery American Volume 2008;90:19–24
- Einaudi S, Matarazzo P, Peretta P, Grossetti R, Giordano F, Altare F, Bondone C, Andreo M, Ivani G, Genitori L, et al. Hypothalamo-hypophysial dysfunction after traumatic brain injury in children and adolescents: a preliminary retrospective and prospective study. Journal of Pediatric Endocrinology & Metabolism 2006;19:691–703
- Kaulfers AM, Backeljauw PF, Reifschneider K, Blum S, Michaud L, Weiss M, Rose SR. Endocrine dysfunction following traumatic brain injury in children. Journal of Pediatrics 2010;157:894–899
- Mysiw WJ, Tan J, Jackson RD. Heterotopic ossification. The utility of osteocalcin in diagnosis and management. American Journal of Physical Medicine & Rehabilitation 1993;72:184–187
- Toffoli AM, Gautschi OP, Frey SP, Filgueira L, Zellweger R. From brain to bone: evidence for the release of osteogenic humoral factors after traumatic brain injury. Brain Injury 2008;22:511–518
- Kesikburun S, Omac OK, Yasar E, Hazneci B, Alaca R. Severe heterotopic ossification in the non-affected limbs of a hemiplegic patient with traumatic brain injury. Brain Injury 2011;25:127–129
- van Kampen PJ, Martina JD, Vos PE, Hoedemaekers CW, Hendricks HT. Potential risk factors for developing heterotopic ossification in patients with severe traumatic brain injury. Journal of Head Trauma Rehabilitation 2011;26:384–391
- Bruno-Petrina A. Posttraumatic heterotopic ossification. Available online at: http://emedicine.medscape.com/article/326242-overview, accessed 2011
- Leblanc E, Trensz F, Haroun S, Drouin G, Bergeron E, Penton CM, Montanaro F, Roux S, Faucheux N, Grenier G. BMP-9-induced muscle heterotopic ossification requires changes to the skeletal muscle microenvironment. Journal of Bone & Mineral Research 2011;26:1166–1177
- Boes M, Kain M, Kakar S, Nicholls F, Cullinane D, Gerstenfeld L, Einhorn TA, Tornetta P 3rd. Osteogenic effects of traumatic brain injury on experimental fracture-healing. Journal of Bone & Joint Surgery America 2006;88:738–743
- Gautschi OP, Cadosch D, Frey SP, Skirving AP, Filgueira L, Zellweger R. Serum-mediated osteogenic effect in traumatic brain-injured patients. ANZ Journal of Surgery 2009;79:449–455
- Klein BY, Shohami E, Reikhinshtein Y, Ben-Bassat H, Liebergall M. Serum-mediated osteogenic effects of head injury on cultured rat marrow stromal cells. Calcified Tissue International 1999;65:217–222
- Song Y, Bi L, Zhang Z, Huang Z, Hou W, Lu X, Sun P, Han Y. Increased levels of calcitonin gene-related peptide in serum accelerate fracture healing following traumatic brain injury. Molecular Medicine Reports 2011;5:432–438
- Morley J, Marsh S, Drakoulakis E, Pape HC, Giannoudis PV. Does traumatic brain injury result in accelerated fracture healing? Injury 2005;36:363–368