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Neurocritical Care
Published in: Neurocritical Care 2/2020

01-10-2020 | Central Nervous System Trauma | Take a closer look at trials

Personalized Connectome Mapping to Guide Targeted Therapy and Promote Recovery of Consciousness in the Intensive Care Unit

Authors: Brian L. Edlow, Megan E. Barra, David W. Zhou, Andrea S. Foulkes, Samuel B. Snider, Zachary D. Threlkeld, Sourish Chakravarty, John E. Kirsch, Suk-tak Chan, Steven L. Meisler, Thomas P. Bleck, Joseph J. Fins, Joseph T. Giacino, Leigh R. Hochberg, Ken Solt, Emery N. Brown, Yelena G. Bodien

Published in: Neurocritical Care | Issue 2/2020

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Abstract

There are currently no therapies proven to promote early recovery of consciousness in patients with severe brain injuries in the intensive care unit (ICU). For patients whose families face time-sensitive, life-or-death decisions, treatments that promote recovery of consciousness are needed to reduce the likelihood of premature withdrawal of life-sustaining therapy, facilitate autonomous self-expression, and increase access to rehabilitative care. Here, we present the Connectome-based Clinical Trial Platform (CCTP), a new paradigm for developing and testing targeted therapies that promote early recovery of consciousness in the ICU. We report the protocol for STIMPACT (Stimulant Therapy Targeted to Individualized Connectivity Maps to Promote ReACTivation of Consciousness), a CCTP-based trial in which intravenous methylphenidate will be used for targeted stimulation of dopaminergic circuits within the subcortical ascending arousal network (ClinicalTrials.gov NCT03814356). The scientific premise of the CCTP and the STIMPACT trial is that personalized brain network mapping in the ICU can identify patients whose connectomes are amenable to neuromodulation. Phase 1 of the STIMPACT trial is an open-label, safety and dose-finding study in 22 patients with disorders of consciousness caused by acute severe traumatic brain injury. Patients in Phase 1 will receive escalating daily doses (0.5–2.0 mg/kg) of intravenous methylphenidate over a 4-day period and will undergo resting-state functional magnetic resonance imaging and electroencephalography to evaluate the drug’s pharmacodynamic properties. The primary outcome measure for Phase 1 relates to safety: the number of drug-related adverse events at each dose. Secondary outcome measures pertain to pharmacokinetics and pharmacodynamics: (1) time to maximal serum concentration; (2) serum half-life; (3) effect of the highest tolerated dose on resting-state functional MRI biomarkers of connectivity; and (4) effect of each dose on EEG biomarkers of cerebral cortical function. Predetermined safety and pharmacodynamic criteria must be fulfilled in Phase 1 to proceed to Phase 2A. Pharmacokinetic data from Phase 1 will also inform the study design of Phase 2A, where we will test the hypothesis that personalized connectome maps predict therapeutic responses to intravenous methylphenidate. Likewise, findings from Phase 2A will inform the design of Phase 2B, where we plan to enroll patients based on their personalized connectome maps. By selecting patients for clinical trials based on a principled, mechanistic assessment of their neuroanatomic potential for a therapeutic response, the CCTP paradigm and the STIMPACT trial have the potential to transform the therapeutic landscape in the ICU and improve outcomes for patients with severe brain injuries.
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Literature
1.
Giacino JT, Fins JJ, Laureys S, et al. Disorders of consciousness after acquired brain injury: the state of the science. Nat Rev Neurol. 2014;10:99–114.PubMedCrossRef
2.
Giacino JT, Kalmar K. The vegetative and minimally conscious states: a comparison of clinical features and functional outcome. J Head Trauma Rehabil. 1997;12:36–51.CrossRef
3.
Claassen J, Doyle K, Matory A, et al. Detection of brain activation in unresponsive patients with acute brain injury. N Engl J Med. 2019;380:2497–505.PubMedCrossRef
4.
Faugeras F, Rohaut B, Valente M, et al. Survival and consciousness recovery are better in the minimally conscious state than in the vegetative state. Brain Inj. 2018;32:72–7.PubMedCrossRef
5.
Fins JJ. Rights come to mind: brain injury, ethics, and the struggle for consciousness. New York: Cambridge University Press; 2015.CrossRef
6.
Turgeon AF, Lauzier F, Simard JF, et al. Mortality associated with withdrawal of life-sustaining therapy for patients with severe traumatic brain injury: a Canadian multicentre cohort study. CMAJ. 2011;183:1581–8.PubMedPubMedCentralCrossRef
7.
Izzy S, Compton R, Carandang R, et al. Self-fulfilling prophecies through withdrawal of care: do they exist in traumatic brain injury, too? Neurocrit Care. 2013;19:347–63.PubMedCrossRef
8.
Peberdy MA, Kaye W, Ornato JP, et al. Cardiopulmonary resuscitation of adults in the hospital: a report of 14720 cardiac arrests from the National Registry of Cardiopulmonary Resuscitation. Resuscitation. 2003;58:297–308.PubMedCrossRef
9.
Snider SB, Bodien YG, Bianciardi M, et al. Disruption of the ascending arousal network in acute traumatic disorders of consciousness. Neurology. 2019;93:e1281–7.PubMedCrossRefPubMedCentral
10.
Edlow BL, Haynes RL, Takahashi E, et al. Disconnection of the ascending arousal system in traumatic coma. J Neuropathol Exp Neurol. 2013;72:505–23.PubMedCrossRef
11.
Rosenblum WI. Immediate, irreversible, posttraumatic coma: a review indicating that bilateral brainstem injury rather than widespread hemispheric damage is essential for its production. J Neuropathol Exp Neurol. 2015;74:198–202.PubMedCrossRef
12.
Threlkeld ZD, Bodien YG, Rosenthal ES, et al. Functional networks reemerge during recovery of consciousness after acute severe traumatic brain injury. Cortex. 2018;106:299–308.PubMedPubMedCentralCrossRef
13.
Demertzi A, Antonopoulos G, Heine L, et al. Intrinsic functional connectivity differentiates minimally conscious from unresponsive patients. Brain. 2015;138:2619–31.PubMedCrossRef
14.
Newcombe VF, Williams GB, Scoffings D, et al. Aetiological differences in neuroanatomy of the vegetative state: insights from diffusion tensor imaging and functional implications. J Neurol Neurosurg Psychiatry. 2010;81:552–61.PubMedCrossRef
15.
Maas AIR, Menon DK, Adelson PD, et al. Traumatic brain injury: integrated approaches to improve prevention, clinical care, and research. Lancet Neurol. 2017;16:987–1048.PubMedCrossRef
16.
Diaz-Arrastia R, Kochanek PM, Bergold P, et al. Pharmacotherapy of traumatic brain injury: state of the science and the road forward: report of the Department of Defense Neurotrauma Pharmacology Workgroup. J Neurotrauma. 2014;31:135–58.PubMedPubMedCentralCrossRef
17.
Kochanek PM, Dixon CE, Mondello S, et al. Multi-center pre-clinical consortia to enhance translation of therapies and biomarkers for traumatic brain injury: operation brain trauma therapy and beyond. Front Neurol. 2018;9:640.PubMedPubMedCentralCrossRef
18.
19.
Tononi G, Boly M, Massimini M, et al. Integrated information theory: from consciousness to its physical substrate. Nat Rev Neurosci. 2016;17:450–61.PubMedCrossRef
20.
Dehaene S, Changeux JP, Naccache L, et al. Conscious, preconscious, and subliminal processing: a testable taxonomy. Trends Cogn Sci. 2006;10:204–11.PubMedCrossRef
21.
Sharp DJ, Scott G, Leech R. Network dysfunction after traumatic brain injury. Nat Rev Neurol. 2014;10:156–66.PubMedCrossRef
22.
Izzy S, Mazwi NL, Martinez S, et al. Revisiting grade 3 diffuse axonal injury: not all brainstem microbleeds are prognostically equal. Neurocrit Care. 2017;27:199–207.PubMedPubMedCentralCrossRef
23.
Jang SH, Kim SH, Lim HW, et al. Injury of the lower ascending reticular activating system in patients with hypoxic-ischemic brain injury: diffusion tensor imaging study. Neuroradiology. 2014;56:965–70.PubMedCrossRef
24.
Demertzi A, Tagliazucchi E, Dehaene S, et al. Human consciousness is supported by dynamic complex patterns of brain signal coordination. Sci Adv. 2019;5:eaat7603.PubMedPubMedCentralCrossRef
25.
26.
Edlow BL, Takahashi E, Wu O, et al. Neuroanatomic connectivity of the human ascending arousal system critical to consciousness and its disorders. J Neuropathol Exp Neurol. 2012;71:531–46.PubMedCrossRef
27.
Koch C, Massimini M, Boly M, et al. Neural correlates of consciousness: progress and problems. Nat Rev Neurosci. 2016;17:307–21.PubMedCrossRef
28.
Estraneo A, Moretta P, Loreto V, et al. Late recovery after traumatic, anoxic, or hemorrhagic long-lasting vegetative state. Neurology. 2010;75:239–45.PubMedCrossRef
29.
30.
Hammond FM, Giacino JT, Nakase Richardson R, et al. Disorders of consciousness due to traumatic brain injury: functional status ten years post-injury. J Neurotrauma. 2019;36:1136–46.PubMedCrossRef
31.
Ommaya AK, Gennarelli TA. Cerebral concussion and traumatic unconsciousness. Correlation of experimental and clinical observations of blunt head injuries. Brain. 1974;97:633–54.PubMedCrossRef
32.
Adams JH, Doyle D, Ford I, et al. Diffuse axonal injury in head injury: definition, diagnosis and grading. Histopathology. 1989;15:49–59.PubMedCrossRef
33.
Gentry LR, Godersky JC, Thompson BH. Traumatic brain stem injury: MR imaging. Radiology. 1989;171:177–87.PubMedCrossRef
34.
Edlow BL, Threlkeld ZD, Fehnel KP, et al. Recovery of functional independence after traumatic transtentorial herniation with duret hemorrhages. Front Neurol. 2019;10:1077.PubMedPubMedCentralCrossRef
35.
Donnemiller E, Brenneis C, Wissel J, et al. Impaired dopaminergic neurotransmission in patients with traumatic brain injury: a SPECT study using 123I-beta-CIT and 123I-IBZM. Eur J Nucl Med. 2000;27:1410–4.PubMedCrossRef
36.
Jenkins PO, De Simoni S, Bourke NJ, et al. Stratifying drug treatment of cognitive impairments after traumatic brain injury using neuroimaging. Brain. 2019;142:2367–79.PubMedCrossRef
37.
Fridman EA, Osborne JR, Mozley PD, et al. Presynaptic dopamine deficit in minimally conscious state patients following traumatic brain injury. Brain. 2019;142:1887–93.PubMedPubMedCentralCrossRef
38.
Solt K, Cotten JF, Cimenser A, et al. Methylphenidate actively induces emergence from general anesthesia. Anesthesiology. 2011;115:791–803.PubMedCrossRef
39.
Swanson JM, Volkow ND. Serum and brain concentrations of methylphenidate: implications for use and abuse. Neurosci Biobehav Rev. 2003;27:615–21.PubMedCrossRef
40.
Taylor NE, Chemali JJ, Brown EN, et al. Activation of D1 dopamine receptors induces emergence from isoflurane general anesthesia. Anesthesiology. 2013;118:30–9.PubMedCrossRef
41.
Taylor NE, Van Dort CJ, Kenny JD, et al. Optogenetic activation of dopamine neurons in the ventral tegmental area induces reanimation from general anesthesia. Proc Natl Acad Sci USA. 2016;113:12826–31.PubMedCrossRefPubMedCentral
42.
Solt K, Van Dort CJ, Chemali JJ, et al. Electrical stimulation of the ventral tegmental area induces reanimation from general anesthesia. Anesthesiology. 2014;121:311–9.PubMedCrossRef
43.
44.
Thibaut A, Schiff N, Giacino J, et al. Therapeutic interventions in patients with prolonged disorders of consciousness. Lancet Neurol. 2019;18:600–14.PubMedCrossRef
45.
Giacino JT, Whyte J, Bagiella E, et al. Placebo-controlled trial of amantadine for severe traumatic brain injury. N Engl J Med. 2012;366:819–26.PubMedCrossRef
46.
47.
Whyte J, Hart T, Vaccaro M, et al. Effects of methylphenidate on attention deficits after traumatic brain injury: a multidimensional, randomized, controlled trial. Am J Phys Med Rehabil. 2004;83:401–20.PubMedCrossRef
48.
McNab JA, Edlow BL, Witzel T, et al. The human connectome project and beyond: initial applications of 300 mT/m gradients. Neuroimage. 2013;80:234–45.PubMedCrossRef
49.
Morales M, Margolis EB. Ventral tegmental area: cellular heterogeneity, connectivity and behaviour. Nat Rev Neurosci. 2017;18:73–85.PubMedCrossRef
50.
Norton L, Hutchison RM, Young GB, et al. Disruptions of functional connectivity in the default mode network of comatose patients. Neurology. 2012;78:175–81.PubMedCrossRef
51.
52.
Kondziella D, Fisher PM, Larsen VA, et al. Functional MRI for assessment of the default mode network in acute brain injury. Neurocrit Care. 2017;27:401–6.PubMedCrossRef
53.
Vanhaudenhuyse A, Noirhomme Q, Tshibanda LJ, et al. Default network connectivity reflects the level of consciousness in non-communicative brain-damaged patients. Brain. 2010;133:161–71.PubMedCrossRef
54.
55.
Gale AS. The effect of methylphenidate (ritalin) on thiopental recovery. Anesthesiology. 1958;19:521–31.PubMedCrossRef
56.
Janowsky DS, Leichner P, Clopton P, et al. Comparison of oral and intravenous methylphenidate. Psychopharmacology. 1978;59:75–8.PubMedCrossRef
57.
Joyce PR, Nicholls MG, Donald RA. Methylphenidate increases heart rate, blood pressure and plasma epinephrine in normal subjects. Life Sci. 1984;34:1707–11.PubMedCrossRef
58.
Wang GJ, Volkow ND, Hitzemann RJ, et al. Behavioral and cardiovascular effects of intravenous methylphenidate in normal subjects and cocaine abusers. Eur Addict Res. 1997;3:49–54.CrossRef
59.
60.
Volkow ND, Wang GJ, Fowler JS, et al. Cardiovascular effects of methylphenidate in humans are associated with increases of dopamine in brain and of epinephrine in plasma. Psychopharmacology. 2003;166:264–70.PubMedCrossRef
61.
Carter CH, Maley MC. Parenteral use of methylphenidate (ritalin). Dis Nerv Syst. 1957;18:146–8.PubMed
62.
Clark CR, Geffen GM, Geffen LB. Role of monoamine pathways in attention and effort: effects of clonidine and methylphenidate in normal adult humans. Psychopharmacology. 1986;90:35–9.PubMed
63.
Chan YP, Swanson JM, Soldin SS, et al. Methylphenidate hydrochloride given with or before breakfast: II. Effects on plasma concentration of methylphenidate and ritalinic acid. Pediatrics. 1983;72:56–9.PubMed
64.
Joyce PR, Donald RA, Nicholls MG, et al. Endocrine and behavioral responses to methylphenidate in normal subjects. Biol Psychiatry. 1986;21:1015–23.PubMedCrossRef
65.
Volkow ND, Wang GJ, Fowler JS, et al. Methylphenidate and cocaine have a similar in vivo potency to block dopamine transporters in the human brain. Life Sci. 1999;65:PL7–12.PubMedCrossRef
66.
Li CS, Morgan PT, Matuskey D, et al. Biological markers of the effects of intravenous methylphenidate on improving inhibitory control in cocaine-dependent patients. Proc Natl Acad Sci U S A. 2010;107:14455–9.PubMedPubMedCentralCrossRef
67.
Christensen RO. A new agent for shortening recovery time in oral surgery. Oral Surg Oral Med Oral Pathol. 1958;11:999–1002.PubMedCrossRef
68.
Percheson PB, Carroll JJ, Screech G. Ritalin (methylphenidate): clinical experiences. Can Anaesth Soc J. 1959;6:277–82.PubMedCrossRef
69.
Gale AS. The comparative and additive effects of methylphenidate and bemegride. Anesthesiology. 1961;22:210–4.PubMedCrossRef
70.
Volkow ND, Wang GJ, Gatley SJ, et al. Temporal relationships between the pharmacokinetics of methylphenidate in the human brain and its behavioral and cardiovascular effects. Psychopharmacology. 1996;123:26–33.PubMedCrossRef
71.
Smith B, Adriani J. Studies on newer analeptics and the comparison of their action with pentylenetetrazole, nikethamide and picrotoxin. Anesthesiology. 1958;19:115.CrossRef
72.
Ticktin H, Epstein J, Shea JG, et al. Effect of methylphenidate hydrochloride in antagonizing barbiturate-induced depression. Neurology. 1958;8:267–71.PubMedCrossRef
73.
Volkow ND, Wang GJ, Fowler JS, et al. Dopamine transporter occupancies in the human brain induced by therapeutic doses of oral methylphenidate. Am J Psychiatry. 1998;155:1325–31.PubMedCrossRef
74.
Setsompop K, Gagoski BA, Polimeni JR, et al. Blipped-controlled aliasing in parallel imaging for simultaneous multislice echo planar imaging with reduced g-factor penalty. Magn Reson Med. 2012;67:1210–24.PubMedCrossRef
75.
Glover GH, Li TQ, Ress D. Image-based method for retrospective correction of physiological motion effects in fMRI: RETROICOR. Magn Reson Med. 2000;44:162–7.PubMedCrossRef
76.
Lindquist MA, Waugh C, Wager TD. Modeling state-related fMRI activity using change-point theory. Neuroimage. 2007;35:1125–41.PubMedCrossRef
77.
78.
Hutchison RM, Womelsdorf T, Allen EA, et al. Dynamic functional connectivity: promise, issues, and interpretations. Neuroimage. 2013;80:360–78.PubMedCrossRef
79.
Killick R, Eckley I. Changepoint: an R package for changepoint analysis. J Stat Softw. 2014;58:1–19.CrossRef
80.
Piarulli A, Bergamasco M, Thibaut A, et al. EEG ultradian rhythmicity differences in disorders of consciousness during wakefulness. J Neurol. 2016;263:1746–60.PubMedCrossRef
81.
Engemann DA, Raimondo F, King JR, et al. Robust EEG-based cross-site and cross-protocol classification of states of consciousness. Brain. 2018;141:3179–92.PubMedCrossRef
82.
Cimenser A, Purdon PL, Pierce ET, et al. Tracking brain states under general anesthesia by using global coherence analysis. Proc Natl Acad Sci USA. 2011;108:8832–7.PubMedCrossRefPubMedCentral
83.
Giacino JT, Kalmar K, Whyte J. The JFK Coma Recovery Scale-Revised: measurement characteristics and diagnostic utility. Arch Phys Med Rehabil. 2004;85:2020–9.PubMedCrossRef
84.
Metadata
Title
Personalized Connectome Mapping to Guide Targeted Therapy and Promote Recovery of Consciousness in the Intensive Care Unit
Authors
Brian L. Edlow
Megan E. Barra
David W. Zhou
Andrea S. Foulkes
Samuel B. Snider
Zachary D. Threlkeld
Sourish Chakravarty
John E. Kirsch
Suk-tak Chan
Steven L. Meisler
Thomas P. Bleck
Joseph J. Fins
Joseph T. Giacino
Leigh R. Hochberg
Ken Solt
Emery N. Brown
Yelena G. Bodien
Publication date
01-10-2020
Publisher
Springer US
Published in
Neurocritical Care / Issue 2/2020
Print ISSN: 1541-6933
Electronic ISSN: 1556-0961
DOI
https://doi.org/10.1007/s12028-020-01062-7

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