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Not all posttraumatic stress disorder symptoms are equal: fear, dysphoria, and risk of developing hypertension in trauma-exposed women

Published online by Cambridge University Press:  04 January 2019

Jennifer A. Sumner Open the ORCID record for Jennifer A. Sumner [Opens in a new window] ,
Laura D. Kubzansky ,
Andrea L. Roberts ,
Qixuan Chen ,
Eric B. Rimm  and
Karestan C. Koenen
Jennifer A. Sumner*
Affiliation:
Center for Behavioral Cardiovascular Health, Columbia University Medical Center, New York, NY, USA
Laura D. Kubzansky
Affiliation:
Department of Social and Behavioral Sciences, Harvard T.H. Chan School of Public Health, Boston, MA, USA
Andrea L. Roberts
Affiliation:
Department of Environmental Health, Harvard T.H. Chan School of Public Health, Boston, MA, USA
Qixuan Chen
Affiliation:
Department of Biostatistics, Columbia University Mailman School of Public Health, New York, NY, USA
Eric B. Rimm
Affiliation:
Channing Division of Network Medicine, Brigham and Women's Hospital, Harvard Medical School, Boston, MA, USA Department of Nutrition, Harvard T.H. Chan School of Public Health, Boston, MA, USA Department of Epidemiology, Harvard T.H. Chan School of Public Health, Boston, MA, USA
Karestan C. Koenen
Affiliation:
Department of Epidemiology, Harvard T.H. Chan School of Public Health, Boston, MA, USA Psychiatric and Neurodevelopmental Genetics Unit and Department of Psychiatry, Massachusetts General Hospital, Boston, MA, USA
*
Author for correspondence: Jennifer A. Sumner, E-mail: [email protected]
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Abstract

Background

Posttraumatic stress disorder (PTSD) is associated with higher risk of incident hypertension, but it is unclear whether specific aspects of PTSD are particularly cardiotoxic. PTSD is a heterogeneous disorder, comprising dimensions of fear and dysphoria. Because elevated fear after trauma may promote autonomic nervous system dysregulation, we hypothesized fear would predict hypertension onset, and associations with hypertension would be stronger with fear than dysphoria.

Methods

We examined fear and dysphoria symptom dimensions in relation to incident hypertension over 24 years in 2709 trauma-exposed women in the Nurses’ Health Study II. Posttraumatic fear and dysphoria symptom scores were derived from a PTSD diagnostic interview. We used proportional hazards models to estimate hazard ratios (HRs) and 95% confidence intervals (CIs) for each symptom dimension (quintiles) with new-onset hypertension events (N = 925), using separate models. We also considered lower-order symptom dimensions of fear and dysphoria.

Results

Higher levels of fear (P-trend = 0.02), but not dysphoria (P-trend = 0.22), symptoms were significantly associated with increased hypertension risk after adjusting for socio-demographics and family history of hypertension. Women in the highest v. lowest fear quintile had a 26% higher rate of developing hypertension [HR = 1.26 (95% CI 1.02–1.57)]; the increased incidence associated with greater fear was similar when further adjusted for biomedical and health behavior covariates (P-trend = 0.04) and dysphoria symptoms (P-trend = 0.04). Lower-order symptom dimension analyses provided preliminary evidence that the re-experiencing and avoidance components of fear were particularly associated with hypertension.

Conclusions

Fear symptoms associated with PTSD may be a critical driver of elevated cardiovascular risk in trauma-exposed individuals.

Keywords

Dysphoriafearhigh blood pressurehypertensionposttraumatic stress disordertraumawomen
Type
Original Articles
Information
Psychological Medicine , Volume 50 , Issue 1 , January 2020 , pp. 38 - 47
Copyright
Copyright © Cambridge University Press 2019 

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References

Adebamowo, CA, Cho, E, Sampson, L, Katan, MB, Spiegelman, D, Willett, WC and Holmes, MD (2005) Dietary flavonols and flavonol-rich foods intake and the risk of breast cancer. International Journal of Cancer 114, 628633.Google Scholar
American Psychiatric Association (2000) Diagnostic and Statistical Manual of Mental Disorders. Washington, DC: American Psychiatric Association.Google Scholar
Armour, C, Carragher, N and Elhai, JD (2013) Assessing the fit of the dysphoric arousal model across two nationally representative epidemiological surveys: the Australian NSMHWB and the United States NESARC. Journal of Anxiety Disorders 27, 109115.Google Scholar
Armour, C, Műllerová, J and Elhai, JD (2016) A systematic literature review of PTSD's latent structure in the diagnostic and statistical manual of mental disorders: DSM-IV to DSM-5. Clinical Psychology Review 44, 6074.Google Scholar
Benjamin, EJ, Virani, SS, Callaway, CW, Chamberlain, AM, Chang, AR, Cheng, S, Chiuve, SE, Cushman, M, Delling, FN, Deo, R, de Ferranti, SD, Ferguson, JF, Fornage, M, Gillespie, C, Isasi, CR, Jiménez, MC, Jordan, LC, Judd, SE, Lackland, D, Lichtman, JH, Lisabeth, L, Liu, S, Longenecker, CT, Lutsey, PL, Mackey, JS, Matchar, DB, Matsushita, K, Mussolino, ME, Nasir, K, O'Flaherty, M, Palaniappan, LP, Pandey, A, Pandey, DK, Reeves, MJ, Ritchey, MD, Rodriguez, CJ, Roth, GA, Rosamond, WD, Sampson, UKA, Satou, GM, Shah, SH, Spartano, NL, Tirschwell, DL, Tsao, CW, Voeks, JH, Willey, JZ, Wilkins, JT, Wu, JH, Alger, HM, Wong, SS and Muntner, P & American Heart Association Council on Epidemiology and Prevention Statistics Committee and Stroke Statistics Subcommittee (2018) Heart disease and stroke statistics – 2018 update: a report from the American Heart Association. Circulation 137, e67e492.Google Scholar
Benjet, C, Bromet, E, Karam, E, Kessler, R, McLaughlin, K, Ruscio, A, Shahly, V, Stein, D, Petukhova, M, Hill, E, Alonso, J, Atwoli, L, Bunting, B, Bruffaerts, R, Caldas-de-Almeida, JM, de Girolamo, G, Florescu, S, Gureje, O, Huang, Y, Lepine, J-P, Kawakami, N, Kovess-Masfety, V, Medina-Mora, M, Navarro-Mateu, F, Piazza, M, Posada-Villa, J, Scott, K, Shalev, A, Slade, T, ten Have, M, Torres, Y, Viana, MC, Zarkov, Z and Koenen, K (2016) The epidemiology of traumatic event exposure worldwide: results from the World Mental Health Survey Consortium. Psychological Medicine 46, 327343.Google Scholar
Boscarino, JA (2008) A prospective study of PTSD and early-age heart disease mortality among Vietnam veterans: implications for surveillance and prevention. Psychosomatic Medicine 70, 668676.Google Scholar
Briscione, MA, Jovanovic, T and Norrholm, SD (2014) Conditioned fear associated phenotypes as robust, translational indices of trauma-, stressor-, and anxiety-related behaviors. Frontiers in Psychiatry 5, 88.Google Scholar
Bryant, RA, Creamer, M, O'Donnell, M, Forbes, D, McFarlane, AC, Silove, D and Hadzi-Pavlovic, D (2017) Acute and chronic posttraumatic stress symptoms in the emergence of posttraumatic stress disorder: a network analysis. JAMA Psychiatry 74, 135142.Google Scholar
Burg, MM and Soufer, R (2016) Post-traumatic stress disorder and cardiovascular disease. Current Cardiology Reports 18, 94.Google Scholar
Chasan-Taber, L, Willett, WC, Manson, JE, Spiegelman, D, Hunter, DJ, Curhan, G, Colditz, GA and Stampfer, MJ (1996) Prospective study of oral contraceptives and hypertension among women in the United States. Circulation 94, 483489.Google Scholar
Cohen, BE, Marmar, C, Ren, L, Bertenthal, D and Seal, KH (2009) Association of cardiovascular risk factors with mental health diagnoses in Iraq and Afghanistan war veterans using VA health care. JAMA 302, 489492.Google Scholar
Cuthbert, BN and Insel, TR (2013) Toward the future of psychiatric diagnosis: the seven pillars of RDoC. BMC Medicine 11, 126.Google Scholar
Devore, EE, Kang, JH, Stampfer, MJ and Grodstein, F (2012) The association of antioxidants and cognition in the Nurses’ Health Study. American Journal of Epidemiology 177, 3341.Google Scholar
El-Gabalawy, R, Blaney, C, Tsai, J, Sumner, JA and Pietrzak, RH (2018) Physical health conditions associated with full and subthreshold PTSD in US military veterans: results from the National Health and Resilience in Veterans Study. Journal of Affective Disorders 227, 849853.Google Scholar
Elhai, JD, Biehn, TL, Armour, C, Klopper, JJ, Frueh, BC and Palmieri, PA (2011) Evidence for a unique PTSD construct represented by PTSD's D1–D3 symptoms. Journal of Anxiety Disorders 25, 340345.Google Scholar
Foa, EB and Kozak, MJ (1986) Emotional processing of fear: exposure to corrective information. Psychological Bulletin 99, 2035.Google Scholar
Forman, JP, Curhan, GC and Taylor, EN (2008) Plasma 25-hydroxyvitamin D levels and risk of incident hypertension among young women. Hypertension 52, 828832.Google Scholar
Galatzer-Levy, IR and Bryant, RA (2013) 636120 ways to have posttraumatic stress disorder. Perspectives on Psychological Science 8, 651662.Google Scholar
Glaesmer, H, Brähler, E, Gündel, H and Riedel-Heller, SG (2011) The association of traumatic experiences and posttraumatic stress disorder with physical morbidity in old age: a German population-based study. Psychosomatic Medicine 73, 401406.Google Scholar
Gradus, JL, Farkas, DK, Svensson, E, Ehrenstein, V, Lash, TL, Milstein, A, Adler, N and Sørensen, HT (2015) Associations between stress disorders and cardiovascular disease events in the Danish population. BMJ Open 5, e009334.Google Scholar
Granado, NS, Smith, TC, Swanson, GM, Harris, RB, Shahar, E, Smith, B, Boyko, EJ, Wells, TS and Ryan, MA (2009) Newly reported hypertension after military combat deployment in a large population-based study. Hypertension 54, 966973.Google Scholar
Howard, JT, Sosnov, JA, Janak, JC, Gundlapalli, AV, Pettey, WB, Walker, LE and Stewart, IJ (2018) Associations of initial injury severity and posttraumatic stress disorder diagnoses with long-term hypertension risk after combat injury. Hypertension 71, 824832.Google Scholar
Kessler, RC and Üstün, TB (2004) The world mental health (WMH) survey initiative version of the world health organization (WHO) composite international diagnostic interview (CIDI). International Journal of Methods in Psychiatric Research 13, 93121.Google Scholar
Kessler, RC, Berglund, P, Demler, O, Jin, R, Merikangas, KR and Walters, EE (2005) Lifetime prevalence and age-of-onset distributions of DSM-IV disorders in the national comorbidity survey replication. Archives of General Psychiatry 62, 593602.Google Scholar
Koenen, KC, De Vivo, I, Rich-Edwards, J, Smoller, JW, Wright, RJ and Purcell, SM (2009) Protocol for investigating genetic determinants of posttraumatic stress disorder in women from the Nurses’ Health Study II. BMC Psychiatry 9, 29.Google Scholar
Koenen, KC, Sumner, JA, Gilsanz, P, Glymour, MM, Ratanatharathorn, A, Rimm, EB, Roberts, AL, Winning, A and Kubzansky, LD (2017) Post-traumatic stress disorder and cardiometabolic disease: improving causal inference to inform practice. Psychological Medicine 47, 209225.Google Scholar
Lambiase, MJ, Kubzansky, LD and Thurston, RC (2014) Prospective study of anxiety and incident stroke. Stroke 45, 438443.Google Scholar
Lazarov, A, Ben-Zion, Z, Shamai, D, Pine, DS and Bar-Haim, Y (2018) Free viewing of sad and happy faces in depression: a potential target for attention bias modification. Journal of Affective Disorders 238, 94100.Google Scholar
Lima, BB, Hammadah, M, Wilmot, K, Pearce, BD, Shah, A, Levantsevych, O, Kaseer, B, Obideen, M, Gafeer, MM, Kim, JH, Sullivan, S, Lewis, TT, Weng, L, Elon, L, Li, L, Bremner, JD, Raggi, P, Quyyumi, A and Vaccarino, V (2018) Posttraumatic stress disorder is associated with enhanced interleukin-6 response to mental stress in subjects with a recent myocardial infarction. Brain, Behavior, and Immunity 75, 2633.Google Scholar
Mancia, G and Grassi, G (2014) The autonomic nervous system and hypertension. Circulation Research 114, 18041814.Google Scholar
Mannelli, M, Pupilli, C, Lanzillotti, R, Ianni, L and Serio, M (1990) Catecholamines and blood pressure regulation. Hormone Research in Paediatrics 34, 156160.Google Scholar
Miller, MW and Sadeh, N (2014) Traumatic stress, oxidative stress and post-traumatic stress disorder: neurodegeneration and the accelerated-aging hypothesis. Molecular Psychiatry 19, 11561162.Google Scholar
Morgan, CA III, Hazlett, G, Wang, S, Richardson, EG Jr., Schnurr, P and Southwick, SM (2001) Symptoms of dissociation in humans experiencing acute, uncontrollable stress: a prospective investigation. American Journal of Psychiatry 158, 12391247.Google Scholar
Mota, N, Sumner, JA, Lowe, SR, Neumeister, A, Uddin, M, Aiello, AE, Wildman, DE, Galea, S, Koenen, KC and Pietrzak, RH (2015) The rs1049353 polymorphism in the CNR1 gene interacts with childhood abuse to predict posttraumatic threat symptoms. The Journal of Clinical Psychiatry 76, e1622.Google Scholar
Norrholm, SD, Jovanovic, T, Olin, IW, Sands, LA, Bradley, B and Ressler, KJ (2011) Fear extinction in traumatized civilians with posttraumatic stress disorder: relation to symptom severity. Biological Psychiatry 69, 556563.Google Scholar
Norrholm, SD, Glover, EM, Stevens, JS, Fani, N, Galatzer-Levy, IR, Bradley, B, Ressler, KJ and Jovanovic, T (2015) Fear load: the psychophysiological over-expression of fear as an intermediate phenotype associated with trauma reactions. International Journal of Psychophysiology 98, 270275.Google Scholar
O'Donovan, A, Ahmadian, AJ, Neylan, TC, Pacult, MA, Edmondson, D and Cohen, BE (2017) Current posttraumatic stress disorder and exaggerated threat sensitivity associated with elevated inflammation in the Mind Your Heart Study. Brain, Behavior, and Immunity 60, 198205.Google Scholar
Pietrzak, RH, Goldstein, RB, Southwick, SM and Grant, BF (2011) Medical comorbidity of full and partial posttraumatic stress disorder in United States adults: results from wave 2 of the national epidemiologic survey on alcohol and related conditions. Psychosomatic Medicine 73, 697707.Google Scholar
Pitman, RK, Rasmusson, AM, Koenen, KC, Shin, LM, Orr, SP, Gilbertson, MW, Milad, MR and Liberzon, I (2012) Biological studies of post-traumatic stress disorder. Nature Reviews Neuroscience 13, 769787.Google Scholar
Player, MS and Peterson, LE (2011) Anxiety disorders, hypertension, and cardiovascular risk: a review. The International Journal of Psychiatry in Medicine 41, 365377.Google Scholar
Rich-Edwards, JW, Mason, S, Rexrode, K, Spiegelman, D, Hibert, E, Kawachi, I, Jun, HJ and Wright, RJ (2012) Physical and sexual abuse in childhood as predictors of early onset cardiovascular events in women. Circulation 126, 920927.Google Scholar
Riley, E, Wright, RJ, Jun, H, Hibert, E and Rich-Edwards, J (2010) Hypertension in adult survivors of child abuse: observations from the Nurses’ Health Study II. Journal of Epidemiology and Community Health 64, 413418.Google Scholar
Stein, DJ, Aguilar-Gaxiola, S, Alonso, J, Bruffaerts, R, de Jonge, P, Liu, Z, Caldas-de-Almeida, JM, O'Neill, S, Viana, MC and Al-Hamzawi, AO (2014) Associations between mental disorders and subsequent onset of hypertension. General Hospital Psychiatry 36, 142149.Google Scholar
Sumner, JA, Kubzansky, LD, Elkind, MS, Roberts, AL, Agnew-Blais, J, Chen, Q, Cerdá, M, Rexrode, KM, Rich-Edwards, JW, Spiegelman, D, Suglia, SF, Rimm, EB and Koenen, KC (2015) Trauma exposure and posttraumatic stress disorder symptoms predict onset of cardiovascular events in women. Circulation 132, 251259.Google Scholar
Sumner, JA, Kubzansky, LD, Roberts, AL, Gilsanz, P, Chen, Q, Winning, A, Forman, JP, Rimm, EB and Koenen, KC (2016) Post-traumatic stress disorder symptoms and risk of hypertension over 22 years in a large cohort of younger and middle-aged women. Psychological Medicine 46, 31053116.Google Scholar
Tawakol, A, Ishai, A, Takx, RA, Figueroa, AL, Ali, A, Kaiser, Y, Truong, QA, Solomon, CJ, Calcagno, C, Mani, V, Tang, CY, Mulder, WJ, Murrough, JW, Hoffmann, U, Nahrendorf, M, Shin, LM, Fayad, ZA and Pitman, RK (2017) Relation between resting amygdalar activity and cardiovascular events: a longitudinal and cohort study. Lancet 389, 834845.Google Scholar
Tsai, J, Harpaz-Rotem, I, Armour, C, Southwick, S, Krystal, J and Pietrzak, R (2015) Dimensional structure of DSM-5 posttraumatic stress disorder symptoms: results from the national health and resilience in veterans study. The Journal of Clinical Psychiatry 76, 546553.Google Scholar
Vaccarino, V, Goldberg, J, Rooks, C, Shah, AJ, Veledar, E, Faber, TL, Votaw, JR, Forsberg, CW and Bremner, JD (2013) Post-traumatic stress disorder and incidence of coronary heart disease: a twin study. Journal of the American College of Cardiology 62, 970978.Google Scholar
Weathers, FW, Litz, BT, Huska, JA and Keane, TM (1994) PTSD Checklist – Civilian Version. Boston: National Center for PTSD, Behavioral Science Division.Google Scholar
Wentworth, BA, Stein, MB, Redwine, LS, Xue, Y, Taub, PR, Clopton, P, Nayak, KR and Maisel, AS (2013) Post-traumatic stress disorder: a fast track to premature cardiovascular disease? Cardiology in Review 21, 1622.Google Scholar
Wurm, LH and Fisicaro, SA (2014) What residualizing predictors in regression analyses does (and what it does not do). Journal of Memory and Language 72, 3748.Google Scholar
Zoellner, LA, Pruitt, LD, Farach, FJ and Jun, JJ (2014) Understanding heterogeneity in PTSD: fear, dysphoria, and distress. Depression and Anxiety 31, 97106.Google Scholar
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